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Lightwave Logic, Inc. – ‘424B3’ on 2/5/20

On:  Wednesday, 2/5/20, at 11:55am ET   ·   Accession #:  1553350-20-122   ·   File #:  333-236115

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  As Of               Filer                 Filing    For·On·As Docs:Size             Issuer                      Filing Agent

 2/05/20  Lightwave Logic, Inc.             424B3                  1:5.6M                                   Edgar Filing LLC/FA

Document/Exhibit                   Description                      Pages   Size 

 1: 424B3       Prospectus                                          HTML    901K 

Filed Pursuant to Rule 424(b)(3)

Registration No. 333-236115

8,477,864 Shares of Common Stock

This prospectus relates to the resale of up to 8,477,864 shares of the common stock, par value $0.001 per share (“Common Stock”) of Lightwave Logic, Inc. (“Company”, “us” or “we”) which may be offered by Lincoln Park Capital Fund, LLC (“Lincoln Park”) from time to time, and which have been or may be issued pursuant to a purchase agreement between the Company and Lincoln Park, dated as of January 21, 2019 (the “Purchase Agreement”) (including 650,660 shares of the Common Stock which have been or may be issued as commitment shares under the Purchase Agreement). See “The Lincoln Park Transaction” for a description of the Purchase Agreement, and “Selling Securityholder” for additional information regarding Lincoln Park.

We previously filed a registration statement on Form S–1 (File No. 333- 229433) filed with the Securities and Exchange Commission on January 30, 2019 and declared effective on February 13, 2019 (the “Prior Registration Statement”). The Prior Registration Statement registered 9,500,000 shares of Common Stock including 8,337,500 purchase shares and 1,162,500 commitment shares that have been or may be issued pursuant to the Purchase Agreement, of which 1,827,204 purchase shares and 650,660 purchase shares remain registered and have not been resold thereunder as of January 22, 2020. Such remaining shares of Common Stock are being carried over from the Prior Registration Statement pursuant to Rule 429 under the Securities Act of 1933, as amended (the “Securities Act”). In addition, 6,000,000 newly registered purchase shares, which were not registered under the Prior Registration Statement are being registered hereunder

The registration of the shares hereunder does not mean that Lincoln Park will actually offer or sell the full number of the shares being registered pursuant to this prospectus. We will not receive any proceeds from the sales of shares of our Common Stock by Lincoln Park; however we may receive proceeds upon the sale of up to 7,687,500 purchase shares under the Purchase Agreement, which have not yet been sold to Lincoln Park.

Lincoln Park is an underwriter within the meaning of Section 2(a)(11) of the Securities Act. Lincoln Park may offer the securities registered hereunder directly or through agents or to or through underwriters or dealers. The securities may be offered and sold through public or private transactions at market prices prevailing at the time of sale, at a fixed price or fixed prices, at negotiated prices, at various prices determined at the time of sale or at prices related to prevailing market prices. See "Plan of Distribution" for more information about how Lincoln Park may sell the shares of Common Stock being registered pursuant to this prospectus.

Our Common Stock is currently quoted on the OTC Markets (OTCQB) under the symbol "LWLG". On January 22, 2020, the Company had 87,921,049 shares issued and outstanding, and the last reported sale price of our Common Stock was $0.7476 per share.

We will pay the expenses incurred in registering the shares, including legal and accounting fees. See “Plan of Distribution”.

Investing in our securities involves a high degree of risk. See “Risk Factors” beginning on page 5 of this prospectus for a discussion of information that should be considered in connection with an investment in our securities.

Neither the Securities and Exchange Commission nor any state securities regulators have approved or disapproved of these securities or determined if this prospectus is truthful or complete. Any representation to the contrary is a criminal offense.

The date of this prospectus is February 4, 2020.

TABLE OF CONTENTS

You should rely only on the information contained in this prospectus. We have not, and the selling securityholder has not, authorized any person to provide you with different information. If anyone provides you with different or inconsistent information, you should not rely on it. This prospectus is not an offer to sell, nor is the selling securityholder seeking an offer to buy, securities in any state where the offer or solicitation is not permitted. The information contained in this prospectus is complete and accurate as of the date on the front cover of this prospectus, but information may have changed since that date. We are responsible for updating this prospectus to ensure that all material information is included and will update this prospectus to the extent required by law.

This prospectus includes statistical and other industry and market data that we obtained from industry publications and research, surveys and studies conducted by third parties. Industry publications and third-party research, surveys and studies generally indicate that their information has been obtained from sources believed to be reliable, although they do not guarantee the accuracy or completeness of such information. While we believe that these industry publications and third-party research, surveys and studies are reliable, we have not independently verified such data and we do not make any representation as to the accuracy of the information.

PROSPECTUS SUMMARY

Our Company

We were incorporated under the laws of the State of Nevada on June 24, 1997 and in 2004 we acquired PSI-TEC Corp., and in 2006 we merged with PSI-TEC Corp. PSI-TEC Corp. was incorporated under the laws of the State of Delaware on September 12, 1995. In 2008 we changed our name to Lightwave Logic, Inc. Unless the context otherwise requires, all references to “Lightwave” the “Company,” “we,” “our” or “us” and other similar terms means Lightwave Logic, Inc., a Nevada corporation.

Our principal executive office is located at 369 Inverness Parkway, Suite 350, Englewood, CO 80112, and our telephone number is (720) 340-4949. Our website address is www.lightwavelogic.com. No information found on our website is part of this prospectus.

Overview

We are a development stage company moving toward commercialization of next generation electro-optic photonic devices made on its P²IC^TM technology platform which uses in-house proprietary high-activity and high-stability organic polymers. Electro-optical devices convert data from electric signals into optical signals for multiple applications.

Our differentiation at the device level is in higher speed, lower power consumption, simplicity of manufacturing and reliability. We have demonstrated higher speed and lower power consumption in packaged devices, and during 2019, we developed new materials that promise to further lower power consumption. We are currently focused on testing and demonstrating the simplicity of manufacturability and reliability of our devices.

We are initially targeting applications in data communications and telecommunications markets and are exploring other applications for our polymer technology platform.

Materials Development

Our Company designs and synthesizes organic chromophores for use in its own proprietary electro-optic polymer systems and photonic device designs. A polymer system is not solely a material, but also encompasses various technical enhancements necessary for its implementation. These include host polymers, poling methodologies, and molecular spacer systems that are customized to achieve specific optical properties. Our organic electro-optic polymer systems compounds are mixed into solution form that allows for thin film application. Our proprietary electro-optic polymers are designed at the molecular level for potentially superior performance, stability and cost-efficiency. We believe they have the potential to replace more expensive, higher power consuming, slower-performance materials and devices used in fiber-optic communication networks.

Our patented and patent pending molecular architectures are based on a well-understood chemical and quantum mechanical occurrence known as aromaticity. Aromaticity provides a high degree of molecular stability that enables our core molecular structures to maintain stability under a broad range of operating conditions.

We expect our patented and patent-pending optical materials along with trade secrets and licensed materials, to be the core of and the enabling technology for future generations of optical devices, modules, sub-systems and systems that we will develop or potentially out-license to electro-optic device manufacturers. Our Company contemplates future applications that may address the needs of semiconductor companies, optical network companies, Web 2.0 media companies, high performance computing companies, telecommunications companies, aerospace companies, and government agencies.

1

Device Design and Development

Electro-optic Modulators

Our Company designs its own proprietary electro-optical modulation devices. Electro-optical modulators convert data from electric signals into optical signals that can then be transmitted over high-speed fiber-optic cables. Our modulators are electro-optic, meaning they work because the optical properties of the polymers are affected by electric fields applied by means of electrodes. Modulators are key components that are used in fiber optic telecommunications, data communications, and data centers networks etc., to convey the high data flows that have been driven by applications such as pictures, video streaming, movies etc., that are being transmitted through the internet. Electro-optical modulators are expected to continue to be an essential element as the appetite and hunger for data increases every year.

Polymer Photonic Integrated Circuits (P²IC^TM)

Our Company also designs its own proprietary polymer photonic integrated circuits (otherwise termed a polymer PIC). A polymer PIC is a photonic device that integrates several photonic functions on a single chip. We believe that our technology can enable the ultra-miniaturization needed to increase the number of photonic functions residing on a semiconductor chip to create a progression like what was seen in the computer integrated circuits, commonly referred to as Moore’s Law. One type of integration is to combine several instances of the same photonic functions such as a plurality of modulators to create a 4 channel polymer PIC. In this case, the number of photonic components would increase by a factor of 4. Another type is to combine different types of devices including from different technology bases such as the combination of a semiconductor laser with a polymer modulator. Our P²IC™ platform encompasses both these types of architecture.

Current photonic technology today is struggling to reach faster device speeds. Our modulator devices, enabled by our electro-optic polymer material systems, work at extremely high frequencies (wide bandwidths) and possess inherent advantages over current crystalline electro-optic material contained in most modulator devices such as lithium niobate (LiNbO3), indium phosphide (InP), silicon (Si), and gallium arsenide GaAs). Our advanced electro-optic polymer platform is creating a new class of modulators and associated PIC platforms that can address higher data rates in a lower cost, lower power consuming manner, with much simpler modulation techniques.

Our electro-optic polymers can be integrated with other materials platforms because they can be applied as a thin film coating in a fabrication clean room such as may be found in semiconductor foundries. Our polymers are unique in that they are stable enough to seamlessly integrate into existing CMOS, Indium Phosphide (InP), Gallium Arsenide (GaAs), and other semiconductor manufacturing lines.

2

The Offering

———————

(1)

The number of shares of our Common Stock set forth above is based on 87,921,049 shares of Common Stock outstanding as of January 22, 2020, and excludes options and warrants to purchase an aggregate of 16,672,517 shares of our Common Stock at exercise prices ranging from $0.57 - $1.69 per share with a weighted average exercise price of $0.85 per share.

3

The Lincoln Park Transaction

On January 21, 2019, we entered into the Purchase Agreement with Lincoln Park, pursuant to which Lincoln Park agreed to purchase from us up to $25,000,000 of our Common Stock (subject to certain limitations) from time to time over a 36-month period. In connection with the Purchase Agreement, we also entered into a registration rights agreement with Lincoln Park whereby we agreed to file registration statements with the SEC covering the shares of Common Stock that may be issued to Lincoln Park under the Purchase Agreement, and while a registration statement covering such shares of Common Stock issuable under the Purchase Agreement is effective, we may, from time to time and at our sole discretion, direct Lincoln Park to purchase up to 125,000 shares of our Common Stock on any such business day, which may be increased to up to 200,000 shares depending on certain conditions as set forth in the Purchase Agreement (and subject to adjustment for any reorganization, recapitalization, non-cash dividend, stock split, reverse stock split or other similar transaction as provided in the Purchase Agreement); provided that in no event shall Lincoln Park purchase more than $500,000 worth of our Common Stock on any single business day (each, a “Regular Purchase”). Under certain circumstances, we may also, in our sole discretion, direct Lincoln Park on each purchase date to make “accelerated purchases” on the following business day up to the lesser of (i) two (2) times the number of shares purchased pursuant to a Regular Purchase or (ii) 30% of the trading volume on the accelerated purchase date at a purchase price equal to the lesser of (i) the closing sale price on the accelerated purchase date and (ii) 95% of the accelerated purchase date’s volume weighted average price. Except as described in this prospectus, there are no trading volume requirements or restrictions under the Purchase Agreement, and we control the timing and amount of any sales of our Common Stock to Lincoln Park. However, in no event may the Company sell any amount of shares that would result in Lincoln Park beneficially owning more than 4.99% of the Company’s Common Stock. The purchase price of the up to 200,000 shares that may be sold to Lincoln Park under the Purchase Agreement on any business day will be based on the market price of our Common Stock immediately preceding the time of sale as computed under the Purchase Agreement without any fixed discount.

The purchase price per share will be equitably adjusted for any reorganization, recapitalization, non-cash dividend, forward or reverse stock split, or other similar transaction occurring during the business days used to compute such price. We may at any time in our sole discretion terminate the Purchase Agreement without fee, penalty or cost upon one business day’s prior notice.

The Purchase Agreement contains customary representations, warranties, covenants, closing conditions and indemnification and termination provisions by, among and for the benefit of the parties. Lincoln Park has covenanted not to cause or engage in any manner whatsoever, any direct or indirect short selling or hedging of our Common Stock. Lincoln Park may not assign or transfer its rights and obligations under the Purchase Agreement, and the Purchase Agreement may be terminated by the Company at any time at its discretion without any cost to us.

In consideration for entering into the Purchase Agreement, we issued to Lincoln Park 350,000 shares of Common Stock as a commitment fee and is obliged to issue up to an additional 812,500 commitment shares, pro rata for no consideration, when and if Lincoln Park purchases (at the Company’s discretion) the $25,000,000 aggregate commitment.  For example, if we elect, at our sole discretion, to require Lincoln Park to purchase $50,000 of our stock then we would issue 1,625 additional commitment shares, which is the product of $50,000 (the amount we have elected to sell) divided by $25,000,000 (remaining total amount we can sell Lincoln Park pursuant to the Purchase Agreement) multiplied by 812,500 (the total number of additional commitment shares). The additional commitment shares will only be issued pursuant to this formula if and when we elect at our discretion to sell stock to Lincoln Park.

4

RISK FACTORS

Before you make a decision to invest in our securities, you should consider carefully the risks described below, together with other information in this prospectus. If any of the following events actually occur, our business, operating results, prospects or financial condition could be materially and adversely affected. This could cause the trading price of our Common Stock to decline and you may lose all or part of your investment. The risks described below are not the only ones that we face. Additional risks not presently known to us or that we currently deem immaterial may also significantly impair our business operations and could result in a complete loss of your investment.

Risks Related to our Business

We have incurred substantial operating losses since our inception and will continue to incur substantial operating losses for the foreseeable future.

Since our inception, we have been engaged primarily in the research and development of our electro-optic polymer materials technologies and potential products. As a result of these activities, we incurred significant losses and experienced negative cash flow since our inception. We incurred a net loss of $5,772,958 for the year ended December 31, 2018 and $4,509,172 for the nine months ended September 30, 2019. We anticipate that we will continue to incur operating losses through at least 2020.

We may not be able to generate significant revenue either through customer contracts for our potential products or technologies or through development contracts from the U.S. government or government subcontractors. We expect to continue to make significant operating and capital expenditures for research and development and to improve and expand production, sales, marketing and administrative systems and processes. As a result, we will need to generate significant revenue to achieve profitability. We cannot assure you that we will ever achieve profitability.

We are subject to the risks frequently experienced by early stage companies.

The likelihood of our success must be considered in light of the risks frequently encountered by early stage companies, especially those formed to develop and market new technologies. These risks include our potential inability to:

If we fail to effectively manage our growth, and effectively transition from our focus on research and development activities to commercially successful products, our business could suffer.

Failure to manage growth of operations could harm our business. To date, a large number of our activities and resources have been directed at the research and development of our technologies and development of potential related products. The transition from a focus on research and development to being a vendor of products requires effective planning and management. Additionally, growth arising from the expected synergies from future acquisitions will require effective planning and management. Future expansion will be expensive and will likely strain management and other resources.

In order to effectively manage growth, we must:

We cannot assure you that we will be able to accomplish these tasks effectively or otherwise effectively manage our growth.

5

We will require additional capital to continue to fund our operations and if we do not obtain additional capital, we may be required to substantially limit our operations.

Our business does not presently generate the cash needed to finance our current and anticipated operations. Based on our current operating plan and budgeted cash requirements, we believe that with the Purchase Agreement for $25 million we entered into with Lincoln Park, we have sufficient funds to finance our operations through February of 2022, and we believe that we have sufficient funds to finance our operations through April 2020 with only cash currently on hand; however, we will need to obtain additional future financing after that time to finance our operations until such time that we can conduct profitable revenue-generating activities. We expect that we will need to seek additional funding through public or private financings, including equity financings, and through other arrangements, including collaborative arrangements. Poor financial results, unanticipated expenses or unanticipated opportunities could require additional financing sooner than we expect. Other than with respect to the Purchase Agreement for $25 million we entered into with Lincoln Park, we have no plans or arrangements with respect to the possible acquisition of additional financing, and such financing may be unavailable when we need it or may not be available on acceptable terms.

Our forecast of the period of time through which our financial resources will be adequate to support our operations is a forward-looking statement and involves risks and uncertainties, and actual results could vary as a result of a number of factors, including the factors discussed elsewhere in this Registration Statement. We have based this estimate on assumptions that may prove to be wrong, and we could use our available capital resources sooner than we currently expect.

Additional financing may not be available to us, due to, among other things, our Company not having a sufficient credit history, income stream, profit level, asset base eligible to be collateralized, or market for its securities. If we raise additional funds by issuing equity or convertible debt securities, the percentage ownership of our existing shareholders may be reduced, and these securities may have rights superior to those of our Common Stock. If adequate funds are not available to satisfy our long-term capital requirements, or if planned revenues are not generated, we may be required to substantially limit our operations.

We are entering new markets, and if we fail to accurately predict growth in these new markets, we may suffer substantial losses.

We are devoting significant resources to engineer next-generation organic nonlinear optical materials and devices for future applications to be utilized by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies as well as our proprietary photonic devices, such as our Polymer Photonic Integrated Circuits P²IC^TM. We expect to continue to develop products for these markets and to seek to identify new markets. These markets change rapidly, and we cannot assure you that they will grow or that we will be able to accurately forecast market demand, or lack thereof, in time to respond appropriately. Our investment of resources to develop products for these markets may either be insufficient to meet actual demand or result in expenses that are excessive in light of actual sales volumes. Failure to predict growth and demand accurately in new markets may cause us to suffer substantial losses. In addition, as we enter new markets, there is a significant risk that:

Our plan to develop relationships with strategic partners may not be successful.

Part of our business strategy is to maintain and develop strategic relationships with private firms, and to a lesser extent, government agencies and academic institutions, to conduct research and development of products and technologies. For these efforts to be successful, we must identify partners whose competencies complement ours. We must also successfully enter into agreements with them on terms attractive to us, and integrate and coordinate their resources and capabilities with our own. We may be unsuccessful in entering into agreements with acceptable partners or negotiating favorable terms in these agreements. Also, we may be unsuccessful in integrating the resources or capabilities of these partners. In addition, our strategic partners may prove difficult to work with or less skilled than we originally expected. If we are unsuccessful in our collaborative efforts, our ability to develop and market products could be severely limited.

6

The failure to establish and maintain collaborative relationships may have a materially adverse affect on our business.

We plan to sell many of our products directly to commercial customers or through potential industry partners. For example, we expect to sell our proprietary electro-optic polymer systems to electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies. Our ability to generate revenues depends significantly on the extent to which potential customers and other potential industry partners develop, promote and sell systems that incorporate our products, which, of course, we cannot control. Any failure by potential customers and other potential industry partners to successfully develop and market systems that incorporate our products could adversely affect our sales. The extent to which potential customers and other industry partners develop, promote and sell systems incorporating our products is based on a number of factors that are largely beyond our ability to control.

We may participate in joint ventures that expose us to operational and financial risk.

We may participate in one or more joint ventures for the purpose of assisting us in carrying out our business expansion, especially with respect to new product and/or market development. We may experience with our joint venture partner(s) issues relating to disparate communication, culture, strategy, and resources. Further, our joint venture partner(s) may have economic or business interests or goals that are inconsistent with ours, exercise their rights in a way that prohibits us from acting in a manner which we would like, or they may be unable or unwilling to fulfill their obligations under the joint venture or other agreements. We cannot assure you that the actions or decisions of our joint venture partners will not affect our operations in a way that hinders our corporate objectives or reduces any anticipated cost savings or revenue enhancement resulting from these ventures.

If we fail to develop and introduce new or enhanced products on a timely basis, our ability to attract and retain customers could be impaired and our competitive position could be harmed.

We plan to operate in a dynamic environment characterized by rapidly changing technologies and industry standards and technological obsolescence. To compete successfully, we must design, develop, market and sell products that provide increasingly higher levels of performance and reliability and meet the cost expectations of our customers. The introduction of new products by our competitors, the market acceptance of products based on new or alternative technologies, or the emergence of new industry standards could render our anticipated products obsolete. Our failure to anticipate or timely develop products or technologies in response to technological shifts could adversely affect our operations. In particular, we may experience difficulties with product design, manufacturing, marketing or certification that could delay or prevent our development, introduction or marketing of products. If we fail to introduce products that meet the needs of our customers or penetrate new markets in a timely fashion our Company will be adversely affected.

Our future growth will suffer if we do not achieve sufficient market acceptance of our organic nonlinear optical material products or our proprietary photonic devices.

We are developing our proprietary electro-optic polymer systems to be utilized by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies, as well as our proprietary photonic devices, such as our Polymer Photonic Integrated Circuits P²IC^TM. All of our potential products are still in the development stage, and we do not know when a market for these products will develop, if at all. Our success depends, in part, upon our ability to gain market acceptance of our products. To be accepted, our products must meet the technical and performance requirements of our potential customers. OEMs, suppliers or government agencies may not accept polymer-based products. In addition, even if we achieve some degree of market acceptance for our potential products in one industry, we may not achieve market acceptance in other industries for which we are developing products.

Achieving market acceptance for our products will require marketing efforts and the expenditure of financial and other resources to create product awareness and demand by customers. We may be unable to offer products that compete effectively due to our limited resources and operating history. Also, certain large corporations may be predisposed against doing business with a company of our limited size and operating history. Failure to achieve broad acceptance of our products by customers and to compete effectively would harm our operating results.

7

Our potential customers require our products to undergo a lengthy and expensive qualification process, which does not assure product sales.

Prior to purchasing our products, our potential customers will require that our products undergo extensive qualification processes. These qualification processes may continue for several months or more. However, qualification of a product by a customer does not assure any sales of the product to that customer. Even after successful qualification and sales of a product to a customer, a subsequent revision to the product, changes in our customer’s manufacturing process or our selection of a new supplier may require a new qualification process, which may result in additional delays. Also, once one of our products is qualified, it could take several additional months or more before a customer commences volume production of components or devices that incorporate our products. Despite these uncertainties, we are devoting substantial resources, including design, engineering, sales, marketing and management efforts, to qualifying our products with customers in anticipation of sales. If we are unsuccessful or delayed in qualifying any of our products with a customer, sales of our products to a customer may be precluded or delayed, which may impede our growth and cause our business to suffer.

Obtaining a sales contract with a potential customer does not guarantee that a potential customer will not decide to cancel or change its product plans, which could cause us to generate no revenue from a product and adversely affect our results of operations.

Even after we secure a sales contract with a potential customer, we may experience delays in generating revenue from our products as a result of a lengthy development cycle that may be required. Potential customers will likely take a considerable amount of time to evaluate our products; it could take 12 to 24 months from early engagement by our sales team to actual product sales. The delays inherent in these lengthy sales cycles increase the risk that a customer will decide to cancel, curtail, reduce or delay its product plans, causing us to lose anticipated sales. In addition, any delay or cancellation of a customer’s plans could materially and adversely affect our financial results, as we may have incurred significant expense and generated no revenue. Finally, our customers’ failure to successfully market and sell their products could reduce demand for our products and materially and adversely affect our business, financial condition and results of operations. If we were unable to generate revenue after incurring substantial expenses to develop any of our products, our business would suffer.

Many of our products will have long sales cycles, which may cause us to expend resources without an acceptable financial return and which makes it difficult to plan our expenses and forecast our revenue.

Many of our products will have long sales cycles that involve numerous steps, including initial customer contacts, specification writing, engineering design, prototype fabrication, pilot testing, regulatory approvals (if needed), sales and marketing and commercial manufacture. During this time, we may expend substantial financial resources and management time and effort without any assurance that product sales will result. The anticipated long sales cycle for some of our products makes it difficult to predict the quarter in which sales may occur. Delays in sales may cause us to expend resources without an acceptable financial return and make it difficult to plan expenses and forecast revenues.

Successful commercialization of our current and future products will require us to maintain a high level of technical expertise.

Technology in our target markets is undergoing rapid change. To succeed in our target markets, we will have to establish and maintain a leadership position in the technology supporting those markets. Accordingly, our success will depend on our ability to:

We cannot assure you that we will be able to achieve any of these objectives.

8

One of our significant target markets is the telecommunications market, which historically has not accepted polymer modulators.

One of our significant target markets is the telecommunications market, which demands high reliability optical components. Historically, polymer modulators have not been accepted into this market even though polymer modulators have achieved Telcordia™ based specifications. It is clear that the telecommunications market is demanding higher and higher data rates for its optical components, and may again decide that polymer based modulators are not suitable even if higher data rates, high reliability, and low power consumption are demonstrated

Another of our significant target markets is the data communications (datacenter and/or high performance computing) market, which may be subject to heavy competition from other PIC based technologies such as silicon photonics and Indium Phosphide.

Another of our significant target markets is the data communications (datacenter and/or high performance computing) market, which may be subject to heavy competition from other PIC based technologies such as silicon photonics and Indium Phosphide. As the demands for high performance, low cost ($/Gbps) is implemented into next generation architectures, polymer modulators and polymer based PIC products may be subject to significant competition. Furthermore, there is a potential that technologies such as silicon photonics and Indium Phosphide might reach the might reach the metric of $1/Gbps at 400Gbps before ours. Customers may then be less willing to purchase new technology such as ours or invest in new technology development such as ours for next generation systems.

Our inability to successfully acquire and integrate other businesses, assets, products or technologies could harm our business and cause us to fail at achieving our anticipated growth.

We may grow our business through strategic acquisitions and investments, such as our acquistion of BrPhotonics’ polymer business, and we are actively evaluating acquisitions and strategic investments in businesses, products or technologies that we believe could complement or expand our product offering, create and/or expand a client base, enhance our technical capabilities or otherwise offer growth or cost-saving opportunities. From time to time, we may enter into letters of intent with companies with which we are negotiating potential acquisitions or investments or as to which we are conducting due diligence. Although we are currently not a party to any binding definitive agreement with respect to potential investments in, or acquisitions of, complementary businesses, products or technologies, we may enter into these types of arrangements in the future, which could materially decrease the amount of our available cash or require us to seek additional equity or debt financing. We have limited experience in successfully acquiring and integrating businesses, products and technologies. We may not be successful in negotiating the terms of any potential acquisition, conducting thorough due diligence, financing the acquisition or effectively integrating the acquired business, product or technology into our existing business and operations. Our due diligence may fail to identify all of the problems, liabilities or other shortcomings or challenges of an acquired business, product or technology, including issues related to intellectual property, product quality or product architecture, regulatory compliance practices, revenue recognition or other accounting practices, or employee or customer issues.

Additionally, in connection with any acquisitions we complete, we may not achieve the synergies or other benefits we expected to achieve, and we may incur write-downs, impairment charges or unforeseen liabilities that could negatively affect our operating results or financial position or could otherwise harm our business. If we finance acquisitions using existing cash, the reduction of our available cash could cause us to face liquidity issues or cause other unanticipated problems in the future. If we finance acquisitions by issuing convertible debt or equity securities, the ownership interest of our existing stockholders may be diluted, which could adversely affect the market price of our stock. Further, contemplating or completing an acquisition and integrating an acquired business, product or technology could divert management and employee time and resources from other matters, which could harm our business, financial condition and operating results.

The exercise of options and warrants and other issuances of shares of Common Stock or securities convertible into Common Stock will dilute your interest.

As of January 22, 2020, we have outstanding options and warrants to purchase an aggregate of 16,672,517 shares of our Common Stock at exercise prices ranging from $0.57 - $1.69 per share with a weighted average exercise price of $0.85 per share. The exercise of options and warrants at prices below the market price of our Common Stock could adversely affect the price of shares of our Common Stock. Additional dilution may result from the issuance of shares of our capital stock in connection with any collaboration (although none are contemplated at this time) or in connection with other financing efforts, including pursuant to the Purchase Agreement with Lincoln Park.

9

Any issuance of our Common Stock that is not made solely to then-existing stockholders proportionate to their interests, such as in the case of a stock dividend or stock split, will result in dilution to each stockholder by reducing his, her or its percentage ownership of the total outstanding shares. Moreover, if we issue options or warrants to purchase our Common Stock in the future and those options or warrants are exercised or we issue restricted stock, stockholders may experience further dilution. Holders of shares of our Common Stock have no preemptive rights that entitle them to purchase their pro rata share of any offering of shares of any class or series.

We may incur debt in the future that might be secured with our intellectual property as collateral, which could subject our Company to the risk of loss of all of our intellectual property.

If we incur debt in the future, we may be required to secure the debt with our intellectual property, including all of our patents and patents pending. In the event we default on the debt, we could incur the loss of all of our intellectual property, which would materially and adversely affect our Company and cause you to lose your entire investment in our Company.

Our quarter-to-quarter performance may vary substantially, and this variance, as well as general market conditions, may cause our stock price to fluctuate greatly and even potentially expose us to litigation.

We have generated no significant sales to date and we cannot accurately estimate future quarterly revenue and operating expenses based on historical performance. Our quarterly operating results may vary significantly based on many factors, including:

Our current and future expense estimates are based, in large part, on estimates of future revenue, which is difficult to predict. We expect to continue to make significant operating and capital expenditures in the area of research and development and to invest in and expand production, sales, marketing and administrative systems and processes. We may be unable to, or may elect not to, adjust spending quickly enough to offset any unexpected revenue shortfall. If our increased expenses were not accompanied by increased revenue in the same quarter, our quarterly operating results would be harmed.

Our failure to compete successfully could harm our business.

The markets that we are targeting for our proprietary electro-optic polymer systems and photonic devices are intensely competitive. Most of our present and potential competitors have or may have substantially greater research and product development capabilities, financial, scientific, marketing, manufacturing and human resources, name recognition and experience than we have. As a result, these competitors may:

The failure to compete successfully against these existing or future competitors could harm our business.

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We may be unable to obtain effective intellectual property protection for our potential products and technology.

Our intellectual property, or any intellectual property that we have or may acquire, license or develop in the future, may not provide meaningful competitive advantages. Our patents and patent applications, including those we license, may be challenged by competitors, and the rights granted under such patents or patent applications may not provide meaningful proprietary protection. For example, numerous patents held by third parties relate to polymer materials and electro-optic devices. These patents could be used as a basis to challenge the validity or limit the scope of our patents or patent applications. A successful challenge to the validity or limitation of the scope of our patents or patent applications could limit our ability to commercialize our polymer materials technology and, consequently, reduce our revenues.

Moreover, competitors may infringe our patents or those that we license, or successfully avoid these patents through design innovation. To combat infringement or unauthorized use, we may need to resort to litigation, which can be expensive and time-consuming and may not succeed in protecting our proprietary rights. In addition, in an infringement proceeding a court may decide that our patents or other intellectual property rights are not valid or are unenforceable, or may refuse to stop the other party from using the intellectual property at issue on the ground that it is non-infringing. Policing unauthorized use of our intellectual property is difficult and expensive, and we may not be able to, or have the resources to, prevent misappropriation of our proprietary rights, particularly in countries where the laws may not protect these rights as fully as the laws of the United States.

We also rely on the law of trade secrets to protect unpatented technology and know-how. We try to protect this technology and know-how by limiting access to those employees, contractors and strategic partners with a need to know this information and by entering into confidentiality agreements with these parties. Any of these parties could breach the agreements and disclose our trade secrets or confidential information to our competitors, or these competitors might learn of the information in other ways. Disclosure of any trade secret not protected by a patent could materially harm our business.

We may be subject to patent infringement claims, which could result in substantial costs and liability and prevent us from commercializing our potential products.

Third parties may claim that our potential products or related technologies infringe their patents. Any patent infringement claims brought against us may cause us to incur significant expenses, divert the attention of our management and key personnel from other business concerns and, if successfully asserted against us, require us to pay substantial damages. In addition, as a result of a patent infringement suit, we may be forced to stop or delay developing, manufacturing or selling potential products that are claimed to infringe a patent covering a third party's intellectual property unless that party grants us rights to use its intellectual property. We may be unable to obtain these rights on terms acceptable to us, if at all. Even if we are able to obtain rights to a third party's patented intellectual property, these rights may be non-exclusive, and therefore our competitors may obtain access to the same intellectual property. Ultimately, we may be unable to commercialize our potential products or may have to cease some of our business operations as a result of patent infringement claims, which could severely harm our business.

If our potential products infringe the intellectual property rights of others, we may be required to indemnify customers for any damages they suffer. Third parties may assert infringement claims against our current or potential customers. These claims may require us to initiate or defend protracted and costly litigation on behalf of customers, regardless of the merits of these claims. If any of these claims succeed, we may be forced to pay damages on behalf of these customers or may be required to obtain licenses for the products they use. If we cannot obtain all necessary licenses on commercially reasonable terms, we may be unable to continue selling such products.

Our technology may be subject to government rights.

We may have obligations to government agencies in connection with the technology that we have developed, including the right to require that a compulsory license be granted to one or more third parties selected by certain government agencies. It may be difficult to monitor whether these third parties will limit their use of our technology to these licensed uses, and we could incur substantial expenses to enforce our rights to our licensed technology in the event of misuse.

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The loss of certain of our key personnel, or any inability to attract and retain additional personnel, could impair our ability to attain our business objectives.

Our future success depends to a significant extent on the continued service of our key management personnel, particularly Dr. Michael Lebby, our Chief Executive Officer and James S. Marcelli our President, Chief Operating Officer, Secretary and Principal Financial Officer. Accordingly, the loss of the services of either of these persons would adversely affect our business and our ability to timely commercialize our products, and impede the attainment of our business objectives.

Our future success will also depend on our ability to attract, retain and motivate highly skilled personnel to assist us with product development and commercialization. Competition for highly educated qualified personnel in the polymer industry is intense. If we fail to hire and retain a sufficient number of qualified management, engineering, sales and technical personnel, we will not be able to attain our business objectives.

If we fail to develop and maintain the quality of our manufacturing processes, our operating results would be harmed.

The manufacture of our potential products is a multi-stage process that requires the use of high-quality materials and advanced manufacturing technologies. Also, polymer-related device development and manufacturing must occur in a highly controlled, clean environment to minimize particles and other yield and quality-limiting contaminants. In spite of stringent quality controls, weaknesses in process control or minute impurities in materials may cause a substantial percentage of a product in a lot to be defective. If we are not able to develop and continue to improve on our manufacturing processes or to maintain stringent quality controls, or if contamination problems arise, our operating results would be harmed.

The complexity of our anticipated products may lead to errors, defects and bugs, which could result in the necessity to redesign products and could negatively, impact our reputation with customers.

Products as complex as those we intend to market might contain errors, defects and bugs when first introduced or as new versions are released. Delivery of products with production defects or reliability, quality or compatibility problems could significantly delay or hinder market acceptance of our products or result in a costly recall and could damage our reputation and adversely affect our ability to sell our products. If our products experience defects, we may need to undertake a redesign of the product, a process that may result in significant additional expenses.

We may also be required to make significant expenditures of capital and resources to resolve such problems. There is no assurance that problems will not be found in new products after commencement of commercial production, despite testing by our suppliers, our customers and us.

If we decide to make commercial quantities of products at our facilities, we will be required to make significant capital expenditures to increase capacity.

We lack the internal ability to manufacture products at a level beyond the stage of early commercial introduction. To the extent we do not have an outside vendor to manufacture our products, we will have to increase our internal production capacity and we will be required to expand our existing facilities or to lease new facilities or to acquire entities with additional production capacities. These activities would require us to make significant capital investments and may require us to seek additional equity or debt financing. We cannot assure you that such financing would be available to us when needed on acceptable terms, or at all. Further, we cannot assure you that any increased demand for our potential products would continue for a sufficient period of time to recoup our capital investments associated with increasing our internal production capacity.

In addition, we do not have experience manufacturing our potential products in large quantities. In the event of significant demand for our potential products, large-scale production might prove more difficult or costly than we anticipate and lead to quality control issues and production delays.

We may not be able to manufacture products at competitive prices.

To date, we have produced limited quantities of products for research, development, demonstration and prototype purposes. The cost per unit for these products currently exceeds the price at which we could expect to profitably sell them. If we cannot substantially lower our cost of production as we move into sales of products in commercial quantities, our financial results will be harmed.

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We conduct significantly all of our research and development activities at our Englewood, CO facility, and circumstances beyond our control may result in considerable interruptions.

We conduct significantly all of our research and development activities at our Englewood, CO facility. And although we have an agreement with CU Boulder to use their facilities in case of any contingency, a disaster such as a fire, flood or severe storm at or near one of our facilities could prevent us from further developing our technologies or manufacturing our potential products, which would harm our business.

We are subject to regulatory compliance related to our operations.

We are subject to various U.S. governmental regulations related to occupational safety and health, labor and business practices. Failure to comply with current or future regulations could result in the imposition of substantial fines, suspension of production, alterations of our production processes, cessation of operations, or other actions, which could harm our business.

We may be unable to export our potential products or technology to other countries, convey information about our technology to citizens of other countries or sell certain products commercially, if the products or technology are subject to United States export or other regulations.

We are developing certain polymer-based products that we believe the United States government and other governments may be interested in using for military and information gathering or antiterrorism activities. United States government export regulations may restrict us from selling or exporting these potential products into other countries, exporting our technology to those countries, conveying information about our technology to citizens of other countries or selling these potential products to commercial customers. We may be unable to obtain export licenses for products or technology, if they become necessary. We currently cannot assess whether national security concerns would affect our potential products and, if so, what procedures and policies we would have to adopt to comply with applicable existing or future regulations.

We may incur liability arising from the use of hazardous materials.

Our business and our facilities are subject to a number of federal, state and local laws and regulations relating to the generation, handling, treatment, storage and disposal of certain toxic or hazardous materials and waste products that we use or generate in our operations. Many of these environmental laws and regulations subject current or previous owners or occupiers of land to liability for the costs of investigation, removal or remediation of hazardous materials. In addition, these laws and regulations typically impose liability regardless of whether the owner or occupier knew of, or was responsible for, the presence of any hazardous materials and regardless of whether the actions that led to the presence were taken in compliance with the law. In our business, we use hazardous materials that are stored on site. We use various chemicals in our manufacturing process that may be toxic and covered by various environmental controls. An unaffiliated waste hauler transports the waste created by use of these materials off-site. Many environmental laws and regulations require generators of waste to take remedial actions at an off-site disposal location even if the disposal was conducted lawfully. The requirements of these laws and regulations are complex, change frequently and could become more stringent in the future. Failure to comply with current or future environmental laws and regulations could result in the imposition of substantial fines, suspension of production, alteration of our production processes, cessation of operations or other actions, which could severely harm our business.

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Our data and information systems and network infrastructure may be subject to hacking or other cyber security threats. If our security measures are breached and an unauthorized party obtains access to our proprietary business information, our information systems may be perceived as being unsecure, which could harm our business and reputation, and our proprietary business information could be misappropriated which could have an adverse effect on our business and results of operations.

Our Company stores and transmits its proprietary information on its computer systems. Despite our security measures, our information systems and network infrastructure may be vulnerable to cyber-attacks or could be breached due to an employee error or other disruption that could result in unauthorized disclosure of sensitive information that has the potential to significantly interfere with our business operations. Breaches of our security measures could expose us to a risk of loss or misuse of this information, litigation and potential liability. Since techniques used to obtain unauthorized access or to sabotage information systems change frequently and generally are not recognized until launched against a target, we may be unable to anticipate these techniques or to implement adequate preventive measures in advance of such an attack on our systems. In addition, we use a vendor that uses cyber or “Cloud” storage of information as part of their service or product offerings, and despite our attempts to validate the security of such services, our proprietary information may be misappropriated by third parties. In the event of an actual or perceived breach of our security, or the security of one of our vendors, the market perception of the effectiveness of our security measures could be harmed and we could suffer damage to our reputation or our business. Additionally, misappropriation of our proprietary business information could prove competitively harmful to our business.

If we are unable to maintain effective internal controls, our business, financial position and results of operations could be adversely affected.

If we are unable to maintain effective internal controls, our business, financial position and results of operations could be adversely affected. We are subject to the reporting and other obligations under the Securities Exchange Act of 1934 (“Exchange Act”), including the requirements of Section 404 of the Sarbanes-Oxley Act of 2002, which require annual management assessments of the effectiveness of our internal control over financial reporting. Our management is responsible for establishing and maintaining adequate internal control over financial reporting, as such term is defined in Exchange Act Rules 13a-15(f) and 15d-15(f). Our internal control over financial reporting is a process designed to provide reasonable assurance regarding the reliability of financial reporting and the preparation of financial statements for external purposes in accordance with accounting principles generally accepted in the United States. Any failure to achieve and maintain effective internal controls could have an adverse effect on our business, financial position and results of operations. In addition, our independent registered public accounting firm is required to attest to the effectiveness of our internal control over financial reporting annually. If our independent registered public accounting firm is unable to attest to the effectiveness of our internal control over financial reporting, investor confidence in our reported results will be harmed and the price of our securities may fall. These reporting and other obligations place significant demands on our management and administrative and operational resources, including accounting resources.

Risks Related to Our Common Stock

Sales of shares to Lincoln Park under the Purchase Agreements may affect the price of our Common Stock and make it more difficult to raise additional equity capital.

All 8,477,864  shares registered hereunder which may be sold to Lincoln Park pursuant to the Purchase Agreements are expected to be freely tradable. As of the January 22, 2020, 7,161,840  shares of Common Stock have been issued to Lincoln Park under the Purchase Agreement, and $20,020,375 in shares of Common Stock remain issuable from time to time under the Purchase Agreement as purchase shares (in addition to 650,660 commitment shares). It is anticipated that such shares registered hereunder will be sold, if at all, before February of 2022, upon the expiration of the Purchase Agreement. The sale by Lincoln Park of a significant amount of shares registered hereunder at any given time could cause the market price of our Common Stock to decline and to be highly volatile. We may ultimately sell (or issue as commitment shares) all, some or none of the shares of Common Stock issuable under the Purchase Agreement and registered in this offering to Lincoln Park in our sole discretion. If we sell (or issue as commitment shares) such shares to Lincoln Park, Lincoln Park may sell all, some or none of such shares. Therefore, sales to Lincoln Park by us under the Purchase Agreement may result in substantial dilution to the interests of other holders of our Common Stock. In addition, if we sell a substantial number of shares to Lincoln Park under the Purchase Agreement, or if investors expect that we will do so, the actual sales of shares or the mere existence of our arrangements with Lincoln Park may make it more difficult for us to sell equity or equity-related securities in the future at a time and at a price that we might otherwise wish to effect such sales. However, we have the right to control the timing and amount of any sales of our shares to Lincoln Park and the Purchase Agreement may be terminated by us at any time at our discretion without any cost to us.

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There is a limited market for our Common Stock, which may make it more difficult for you to sell your stock.

Our Company’s Common Stock is quoted on the OTCMarkets (OTCQB) under the symbol "LWLG." The trading market for our Common Stock is limited, accordingly, there can be no assurance as to the liquidity of any markets that may develop for our Common Stock, your ability to sell our Common Stock, or the prices at which you may be able to sell our Common Stock.

Shares eligible for future sale may adversely affect the market.

From time to time, certain of the Company’s shareholders may be eligible to sell all or some of their shares of Common Stock by means of ordinary brokerage transactions in the open market pursuant to Rule 144, promulgated under the Securities Act of 1933, as amended (the “Securities Act”), subject to certain limitations. In general, a non-affiliate stockholder who has satisfied a six-month holding period may, under certain circumstances, sell its shares, without limitation. Any substantial sale of the Company’s Common Stock pursuant to Rule 144 or pursuant to any resale prospectus may have a material adverse effect on the market price of our Common Stock.

Our board of directors has the authority, without stockholder approval, to issue preferred stock with terms that may not be beneficial to existing Common Stockholders and with the ability to affect adversely stockholder voting power and perpetuate their control over us.

Our amended articles of incorporation allow us to issue shares of preferred stock without any vote or further action by our stockholders. Our board of directors has the authority to fix and determine the relative rights and preferences of preferred stock. Our board of directors also has the authority to issue preferred stock without further stockholder approval, including large blocks of preferred stock. As a result, our board of directors could authorize the issuance of a series of preferred stock that would grant to holders thereof the preferred right to our assets upon liquidation, the right to receive dividend payments before dividends are distributed to the holders of Common Stock or other preferred stockholders and the right to the redemption of the shares, together with a premium, prior to the redemption of our Common Stock or existing preferred stock, if any.

Preferred stock could be used to dilute a potential hostile acquirer. Accordingly, any future issuance of preferred stock or any rights to purchase preferred stock may have the effect of making it more difficult for a third party to acquire control of us. This may delay, defer or prevent a change of control or an unsolicited acquisition proposal. The issuance of preferred stock also could decrease the amount of earnings attributable to, and assets available for distribution to, the holders of our Common Stock and could adversely affect the rights and powers, including voting rights, of the holders of our Common Stock and preferred stock.

Our articles of incorporation and bylaws, and certain provisions of Nevada corporate law, as well as certain of our contracts, contain provisions that could delay or prevent a change in control even if the change in control would be beneficial to our stockholders.

Nevada law, as well as our amended articles of incorporation and bylaws, contain anti-takeover provisions that could delay or prevent a change in control of our Company, even if the change in control would be beneficial to our stockholders. These provisions could lower the price that future investors might be willing to pay for shares of our Common Stock. These anti-takeover provisions:

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Nevada Revised Statutes, the terms of our employee stock option agreements and other contractual provisions may also discourage, delay or prevent a change in control of our Company. Nevada Revised Statutes sections 78.378 to 78.3793 provide state regulation over the acquisition of a controlling interest in certain Nevada corporations unless the articles of incorporation or bylaws of the corporation provide that the provisions of these sections do not apply. Our articles of incorporation and bylaws do not state that these provisions do not apply. The statute creates a number of restrictions on the ability of a person or entity to acquire control of a Nevada company by setting down certain rules of conduct and voting restrictions in any acquisition attempt, among other things. The statute contains certain limitations and it may not apply to our Company. Our 2016 Equity Incentive Plan includes change-in-control provisions that allow us to grant options that may become vested immediately upon a change in control. Our board of directors also has the power to adopt a stockholder rights plan that could delay or prevent a change in control of our Company even if the change in control is generally beneficial to our stockholders. These plans, sometimes called “poison pills,” are oftentimes criticized by institutional investors or their advisors and could affect our rating by such investors or advisors. If our board of directors adopts such a plan, it might have the effect of reducing the price that new investors are willing to pay for shares of our Common Stock.

Together, these charter, statutory and contractual provisions could make the removal of our management and directors more difficult and may discourage transactions that otherwise could involve payment of a premium over prevailing market prices for our Common Stock. Furthermore, the existence of the foregoing provisions, as well as the significant Common Stock beneficially owned by our founders, executive officers, and members of our board of directors, could limit the price that investors might be willing to pay in the future for shares of our Common Stock. They could also deter potential acquirers of our Company, thereby reducing the likelihood that you could receive a premium for your Common Stock in an acquisition.

The risks and uncertainties we have described are not the only risks that we face.  Additional risks and uncertainties not presently known to us or that we currently deem immaterial may also affect our operations.  The occurrence of these known or unknown risks might cause you to lose all or part of your investment.

See also the statements contained under the heading “Forward-Looking Statements.”

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FORWARD-LOOKING STATEMENTS

This prospectus contains forward-looking statements that involve substantial risks and uncertainties. The forward-looking statements are contained principally in the sections entitled “Prospectus Summary”, “Risk Factors”, “Management’s Discussion and Analysis of Financial Condition and Results of Operations” and “Business” but are also contained elsewhere in this prospectus. In some cases, you can identify forward-looking statements by the words “may”, “might”, “will”, “could”, “would”, “should”, “expect”, “intend”, “plan”, “objective”, “anticipate”, “believe”, “estimate”, “predict”, “project”, “potential”, “continue” and “ongoing,” or the negative of these terms, or other comparable terminology intended to identify statements about the future. These statements involve known and unknown risks, uncertainties and other factors that may cause our actual results, levels of activity, performance or achievements to be materially different from the information expressed or implied by these forward-looking statements. Although we believe that we have a reasonable basis for each forward-looking statement contained in this prospectus, we caution you that these statements are based on a combination of facts and factors currently known by us and our expectations of the future, about which we cannot be certain. Forward-looking statements include, but are not limited to, statements about:

In addition, you should refer to the “Risk Factors” section of this prospectus for a discussion of other important factors that may cause our actual results to differ materially from those expressed or implied by our forward-looking statements. As a result of these factors, we cannot assure you that the forward-looking statements in this prospectus will prove to be accurate or that we will achieve the plans, intentions or expectations expressed or implied in our forward-looking statements. Furthermore, if our forward-looking statements prove to be inaccurate, the inaccuracy may be material. In light of the significant uncertainties in these forward-looking statements, you should not regard these statements as a representation or warranty by us or any other person that we will achieve our objectives and plans in any specified time frame, or at all. Any forward-looking statements we make in this prospectus speak only as of its date, and we undertake no obligation to publicly update any forward-looking statements, whether as a result of new information, future events or otherwise, except as required by law.

You should read this prospectus and the documents that we reference in this prospectus and have filed as exhibits to the Registration Statement, of which this prospectus is a part, completely and with the understanding that our actual future results may be materially different from what we expect. We qualify all of our forward-looking statements by these cautionary statements.

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USE OF PROCEEDS

This prospectus relates to shares of our Common Stock that may be offered and sold from time to time by the selling securityholder. We will receive no proceeds from the sale of shares of Common Stock by Lincoln Park in this offering. However, we may receive gross proceeds of up to $25,000,000 under the Purchase Agreement, including the sale of up to 7,827,204  purchase shares issued or issuable pursuant to the Purchase Agreement, which are being registered hereunder for resale by Lincoln Park.

We intend to use approximately 65% of any proceeds received under the Purchase Agreement towards our research and development efforts which may include, without limitation, (a) retaining additional management, sales, marketing, technical and other staff to our workforce, (b) expanding our research and development facilities, including the purchase of additional laboratory and production equipment, (c) marketing our future products as they are introduced into the marketplace, (d) developing and maintaining collaborative relationships with strategic partners, (e) developing and improving our manufacturing processes and quality controls, and approximately 35% of any proceeds received may be used for increasing our general and administrative activities related to our operations as a reporting public company and related corporate compliance requirements.

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MARKET FOR COMMON EQUITY AND RELATED SHAREHOLDER MATTERS

Market Information

Our Common Stock is quoted on the OTCQB under the symbol “LWLG”. Any over-the-counter market quotations on the OTCQB reflect inter-dealer prices, without retail mark-up, mark-down or commission and may not necessarily represent actual transactions

As of January 20, 2020, we have a total of 87,921,049 shares of Common Stock outstanding, held by approximately 105 shareholders of record. We do not have any shares of preferred stock outstanding.

Dividends

No cash dividends have been declared or paid on our Common Stock to date. The payment of cash dividends in the future, if any, will be contingent upon our Company’s revenues and earnings, if any, capital requirements and general financial condition. The payment of any dividends is within the discretion of our board of directors. Our board of director’s present intention is to retain all earnings, if any, for use in our business operations and, accordingly, the board of directors does not anticipate paying any cash dividends in the foreseeable future.

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MANAGEMENT’S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS

The following management’s discussion and analysis of financial condition and results of operations provides information that management believes is relevant to an assessment and understanding of our plans and financial condition. The following selected financial information is derived from our historical financial statements and should be read in conjunction with such financial statements and notes thereto set forth elsewhere herein and the “Forward-Looking Statements” explanation included herein.

Overview

We are a development stage company moving toward commercialization of next generation electro-optic photonic devices made on its P²IC^TM technology platform which uses in-house proprietary high-activity and high-stability organic polymers. Electro-optical devices convert data from electric signals into optical signals for multiple applications.

Our differentiation at the device level is in higher speed, lower power consumption, simplicity of manufacturing and reliability. We have demonstrated higher speed and lower power consumption in packaged devices, and during 2019, we developed new materials that promise to further lower power consumption. We are currently focused on testing and demonstrating the simplicity of manufacturability and reliability of our devices.

We are initially targeting applications in data communications and telecommunications markets and are exploring other applications for our polymer technology platform.

Materials Development

Our Company designs and synthesizes organic chromophores for use in its own proprietary electro-optic polymer systems and photonic device designs. A polymer system is not solely a material, but also encompasses various technical enhancements necessary for its implementation. These include host polymers, poling methodologies, and molecular spacer systems that are customized to achieve specific optical properties. Our organic electro-optic polymer systems compounds are mixed into solution form that allows for thin film application. Our proprietary electro-optic polymers are designed at the molecular level for potentially superior performance, stability and cost-efficiency. We believe they have the potential to replace more expensive, higher power consuming, slower-performance materials and devices used in fiber-optic communication networks.

Our patented and patent pending molecular architectures are based on a well-understood chemical and quantum mechanical occurrence known as aromaticity. Aromaticity provides a high degree of molecular stability that enables our core molecular structures to maintain stability under a broad range of operating conditions.

We expect our patented and patent-pending optical materials along with trade secrets and licensed materials, to be the core of and the enabling technology for future generations of optical devices, modules, sub-systems and systems that we will develop or potentially out-license to electro-optic device manufacturers. Our Company contemplates future applications that may address the needs of semiconductor companies, optical network companies, Web 2.0 media companies, high performance computing companies, telecommunications companies, aerospace companies, and government agencies.

Device Design and Development

Electro-optic Modulators

Our Company designs its own proprietary electro-optical modulation devices. Electro-optical modulators convert data from electric signals into optical signals that can then be transmitted over high-speed fiber-optic cables. Our modulators are electro-optic, meaning they work because the optical properties of the polymers are affected by electric fields applied by means of electrodes. Modulators are key components that are used in fiber optic telecommunications, data communications, and data centers networks etc., to convey the high data flows that have been driven by applications such as pictures, video streaming, movies etc., that are being transmitted through the internet. Electro-optical modulators are expected to continue to be an essential element as the appetite and hunger for data increases every year.

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Polymer Photonic Integrated Circuits (P²IC^TM)

Our Company also designs its own proprietary polymer photonic integrated circuits (otherwise termed a polymer PIC). A polymer PIC is a photonic device that integrates several photonic functions on a single chip. We believe that our technology can enable the ultra-miniaturization needed to increase the number of photonic functions residing on a semiconductor chip to create a progression like what was seen in the computer integrated circuits, commonly referred to as Moore’s Law. One type of integration is to combine several instances of the same photonic functions such as a plurality of modulators to create a 4 channel polymer PIC. In this case, the number of photonic components would increase by a factor of 4. Another type is to combine different types of devices including from different technology bases such as the combination of a semiconductor laser with a polymer modulator. Our P²IC™ platform encompasses both these types of architecture.

Current photonic technology today is struggling to reach faster device speeds. Our modulator devices, enabled by our electro-optic polymer material systems, work at extremely high frequencies (wide bandwidths) and possess inherent advantages over current crystalline electro-optic material contained in most modulator devices such as lithium niobate (LiNbO3), indium phosphide (InP), silicon (Si), and gallium arsenide GaAs). Our advanced electro-optic polymer platform is creating a new class of modulators and associated PIC platforms that can address higher data rates in a lower cost, lower power consuming manner, with much simpler modulation techniques.

Our electro-optic polymers can be integrated with other materials platforms because they can be applied as a thin film coating in a fabrication clean room such as may be found in semiconductor foundries. Our polymers are unique in that they are stable enough to seamlessly integrate into existing CMOS, Indium Phosphide (InP), Gallium Arsenide (GaAs), and other semiconductor manufacturing lines.

Business Strategy

Our business strategy anticipates that our revenue stream will be derived from one or some combination of the following: (i) technology licensing for specific product application; (ii) joint venture relationships with significant industry leaders; or (iii) the production and direct sale of our own electro-optic device components. Our objective is to be a leading provider of proprietary technology and know-how in the electro-optic device market. In order to meet this objective, we intend to:

Create Organic Polymer-Enabled Electro-Optic Modulators

We intend to utilize our proprietary optical polymer technology to create an initial portfolio of commercial electro-optic polymer product devices with applications for various markets, including telecommunications, data communications and data centers. These product devices will be part of our proprietary photonics integrated circuit (PIC) technology platform.

We expect our initial modulator products will operate at data rates at least 50 Gbaud (capable of 50 Gbps with standard data encoding of NRZ and 100 Gbps with more complex PAM-4 encoding). Our devices are highly linear, enabling the performance required to take advantage of the more advance complex encoding schemes. We are currently developing our polymer technology to operate at the next industry node of 100Gbaud.

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Our Proprietary Products in Development

As part of a two-pronged marketing strategy, our Company is developing several optical devices, which are in various stages of development and that utilize our polymer optical materials. They include:

Ridge Waveguide Modulator

Our ridge electro-optic waveguide modulator was designed and fabricated in our in-house laboratory. The fabrication of our first in-house device is significant to our entire device program and is an important starting point for modulators that are being developed for target markets. We have multiple generations of new materials that we will soon be optimizing for this specific design. In September 2017 we announced that our initial alpha prototype ridge waveguide modulator, enabled by our P²IC™ polymer system, demonstrated bandwidth performance levels that will enable 50 Gbaud modulation in fiber-optic communications. This device demonstrated true amplitude (intensity) modulation in a Mach-Zehnder modulator structure incorporating our polymer waveguides. This important achievement will allow users to utilize arrays of 4 x 50 Gbaud (4x 100 Gbps) polymer modulators using PAM-4 encoding to access 400 Gbps data rate systems. These ridge waveguide modulators are currently being packaged with our partner into prototype packages. We showed an example packaged modulator at our Annual Shareholders Meeting in May 2018.

These prototype packages will enable potential customers to evaluate the performance at 50 Gbaud. Once a potential customer generates technical feedback on our prototype, we expect to be asked to optimize the performance to their specifications. Assuming this is successful, we expect to enter a qualification phase where our prototypes will be evaluated more fully.

In parallel, we are developing modulators for scalability to higher data rates above 50 Gbaud. In September 2018, we showed in conference presentations the potential of our polymer modulator platform to operate at over 100 GHz bandwidth. This preliminary result corresponds to 100 Gbaud data rates using a simple NRZ data encoding scheme or 200 Gbps with PAM-4 encoding. With 4 channel arrays in our P²IC™ platform, the Company thus has the potential to address both 400 Gbps and 800 Gbps markets. While customers may start the engagement at 50 Gbaud, we believe potential customers recognize that scalability to higher speeds is an important differentiator of the polymer technology.

We believe the ridge waveguide modulator represents our first commercially viable device and targets the fiber optics communications market. We have completed internal market analysis and are initially targeting interconnect reach distances of greater than 10km. In these markets, the system network companies are looking to implement modulator-based transceivers that can handle aggregated data rates 100 Gbps and above. The market opportunity for greater than 10km is worth over $1B over the next decade.

Advanced Modulator Structures

As part of supporting further improvement and scalability of our platform, we continue to explore more advanced device structures. Our functional polymer photonics slot waveguide modulator utilizes an existing modulator structure with one of our proprietary electro-optic polymer material systems as the enabling material layer and is functional as an operating prototype device.

Preliminary testing and initial data on our polymer photonics slot waveguide modulators demonstrated several promising characteristics. The tested polymer photonic chip had a 1-millimeter square footprint, enabling the possibility of sophisticated integrated optical circuits on a single silicon substrate. In addition, the waveguide structure was approximately 1/20 the length of a typical inorganic-based silicon photonics modulator waveguide.

With the combination of our proprietary electro-optic polymer material and the extremely high optical field concentration in the slot waveguide modulator, the test modulators demonstrated less than 2.2 volts to operate. Initial speeds exceeded 30-35 GHz in the telecom, 1550 nanometer frequency band. This is equivalent to 4 x 10Gbps, inorganic, lithium niobate modulators that would require approximately 12-16 volts to move the same amount of information.

We continued with our collaborative development of our polymer photonic slot waveguide modulator in 2014 and continued our collaboration with an associated third-party research group in 2017 and 2018. We are now designing slot modulators to operate at data rates greater than 50 Gbaud.

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Our Long-Term Device Development Goal - Multichannel Polymer Photonic Integrated Circuit (P²IC™)

Our P²IC™ platform is positioned to address markets with aggregated data rates of 100 Gbaud, 400 Gbaud, 800 Gbaud and beyond. Our P²IC™ platform will contain a number of photonic devices that may include, over and above polymer-based modulators, photonic devices such as lasers, multiplexers, demultiplexers, detectors, fiber couplers.

While our polymer-based ridge waveguide and slot modulators are currently under development to be commercially viable products, our long-term device development goal is to produce a platform for the 400 Gbps and beyond transceiver market. This has been stated in our photonics product roadmap that is publicly available on our website. The roadmap shows a progression in speed from 50 Gbaud based ridge waveguide modulators to 100 Gbaud based ridge waveguide modulators. The roadmap shows a progression in integration in which the modulators are arrayed to create a flexible, multichannel P²IC™ platform that spans 100 Gbps, 400 Gbps, 800 Gbps, and potentially 1.6 Tbps aggregated data-rate markets.

We showed bandwidths of polymer-based modulator devices at a major international conference (ECOC – European Conference on Optical Communications 2018) with bandwidths that exceeded 100GHz. We noted that to achieve 100Gbaud, the polymer-based modulator only needs to achieve 80GHz bandwidth. During ECOC 2019, we showed environmental stability. We continue to develop our polymer materials and device designs to optimize additional metrics. We are now optimizing the device parameters for very low voltage operation.

Our Target Markets

Cloud computing and data centers

Big data is a general term used to describe the voluminous amount of unstructured and semi-structured data a Company creates -- data that would take too much time and cost too much money to load into a relational database for analysis. Companies are looking to cloud computing in their data centers to access all the data. Inherent speed and bandwidth limits of traditional solutions and the potential of organic polymer devices offer an opportunity to increase the bandwidth, reduce costs and improve speed of access.

Datacenters have grown to enormous sizes with hundreds of thousands and even millions of servers in a single datacenter. The number of so-called “hyperscale” datacenters are expected to continue to increase in number. Due to their size, a single “datacenter” may consist of multiple large warehouse-size buildings on a campus or even several locations distributed around a metropolitan area. Data centers are confronted with the problem of moving vast amounts of data not only around a single data center building, but also between buildings in distributed data center architecture. Links within a single datacenter building may be shorter than 500 meters, though some will require optics capable of 2 km. Between datacenter buildings, there is an increasing need for high performance interconnects over 10km in reach.

Our modulators are suitable for single-mode fiber optic links. We believe that our single mode modulator solutions will be competitive at 500m to 10km link distances, but it will be ideally suited at greater than 10km link distances.

Telecommunications/Data Communications

The telecommunications industry has evolved from transporting traditional analogue voice data over copper wire into the movement of digital voice and data. Telecommunication companies are faced with the enormous increasing challenges to keep up with the resulting tremendous explosion in demand for bandwidth. The metropolitan network is especially under stress now and into the near future. Telecommunications companies provide services to some data center customers for the inter-data center connections discussed above. 5G mobile upgrade, autonomous driving and IoT are expected to increase the need for data stored and processed close to the end user in edge data centers. This application similarly requires optics capable of very high speeds and greater than 10 km reach.

Recent Significant Events and Milestones Achieved

During February and March 2018, we moved our Newark, Delaware synthetic laboratory and our Longmont, Colorado optical testing laboratory and corporate headquarters to office, laboratory and research and development space located at 369 Inverness Parkway, Suite 350, Englewood, Colorado. The 13,420 square feet Englewood facility includes fully functional 1,000 square feet of class 1,000 cleanroom, 500 square feet of class 10,000 cleanroom, chemistry laboratories, and analytic laboratories. The Englewood facility streamlines all of our Company’s research and development workflow for greater operational efficiencies. 

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During March 2018, our Company, together with our packaging partner, successfully demonstrated packaged polymer modulators designed for 50Gbps, which we believe will allow us to scale our P²IC™ platform with our Mach-Zehnder ridge waveguide modulator design as well as other photonics devices competitively in the 100Gbps and 400Gbps datacom and telecommunications applications market. We are currently fine-tuning the performance parameters of these prototypes in preparation for customer evaluations.

During June 2018, our Company Acquired the Polymer Technology Intellectual Property Assets of BrPhotonics Productos Optoelectrónicos S.A., a Brazilian corporation, which significantly advanced our patent portfolio of electro-optic polymer technology with 15 polymer chemistry materials, devices, packaging and subsystems patent and further strengthened our design capabilities to solidify our market position as we prepare to enter the 400Gbps integrated photonics marketplace with a highly competitive, scalable alternative to installed legacy systems. We have now fully integrated the acquired technology into our P²IC (polymer photonic integrated circuit) platform.

Also, during June 2018, our Company promoted polymer PICs and Solidified Polymer PICs as Part of the Photonics Roadmap at the World Technology Mapping Forum in Enschede, Netherlands, which includes our Company’s technology of polymers and polymer PICs that have the potential to drive not only 400Gbps aggregate data rate solutions, but also 800Gbps and beyond.

In August 2018 we announced the completion (ahead of schedule) of our fully equipped on-site fabrication facility, where we are expanding our high-speed test and design capabilities. We also announced the continuation of the building of our internal expertise with the hiring of world-class technical personnel with 100Gbps experience.

In February 2019 we announced a major breakthrough in our development of clean technology polymer materials that target the insatiable demand for fast and efficient data communications in the multi-billion-dollar telecom and data markets supporting Internet, 5G and IoT (Internet of Things) webscale services. The improved thermally stable polymer has more than double the electro-optic response of our previous materials, enabling optical device performance of well over 100 GHz with extremely low power requirements. This addition to the family of Perkinamine^TM polymers will hold back run-away consumption of resources and energy needed to support ever-growing data consumption demands. We continue to conduct testing of the material and assessment of associated manufacturing processes and device structures prior to release to full development.

In March 2019 we created an Advisory Board comprised of three world-class leaders in the photonics industry: Dr. Craig Ciesla, Dr. Christoph S. Harder, and Mr. Andreas Umbach. The Advisory Board will work closely with our Company leadership to enhance our Company’s product positioning and promote our polymer modulator made on our proprietary Faster by Design™ polymer P²IC™ platform. The mission of the Advisory Board will initially be to increase our Company’s outreach into the datacenter interconnect market and later to support expansion into other billion-dollar markets. The Advisory Board members have each been chosen for their combination of deep technical expertise, breadth of experience and industry relationships in the fields of fiber optics communications, polymer and semiconductor materials. Each of the Advisory Board members has experience at both innovators like Lightwave Logic and large industry leaders of the type most likely to adopt game-changing polymer-based products. In addition, they possess operational experience with semiconductor and polymer businesses.

Also, in March 2019, our Company received the “Best Achievement in PIC Platform” award for our 100 GHz polymer platform from the PIC International Conference. The award recognizes innovative advances in the development and application of key materials systems driving today's photonic integrated circuits (PICs) and providing a steppingstone to future devices.

During the second quarter of 2019, our Company promoted its polymers at CoInnovate in May and the World Technology Mapping Forum in June. CoInnovate is a meeting of semiconductor industry experts. The World Technology Mapping Forum is a group authoring a photonics roadmap out to 2030.

In September 2019 at the prestigious European Conference on Communications (ECOC) in Dublin, Ireland,  we showed measured material response over frequency and the resulting optical data bits stream on our clean technology polymer materials, the newest addition to our family of Perkinamine^TM polymers, that meet and exceed of our near-term target speed of 80 GHz  We also released data data demonstrating stability under elevated temperatures in the activated (poled to create data carrying capability) state.

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In October 2019, we reported that energy-saving polymer technology is highlighted in the recently published Integrated Photonics Systems Roadmap - International (IPSR-I).  The roadmap validates the need for low-voltage, high-speed technologies such as ours.

As we move forward to diligently meet our goals, we continue to work closely with our packaging partner for the 50Gbaud and 100 Gbaud prototypes, and we are advancing our reliability and characterization efforts to support our prototyping. We are actively engaged with test equipment manufacturers of the most advanced test equipment to test our state-of-the-art polymer devices. We continue to engage with multiple industry bodies to promote our roadmap. We continue to fine tune our business model with target markets, customers, and technical specifications. Discussions with prospective customers are validating that our modulators are ideally suited for the datacenter and telecommunications markets that are over 10km in length. Details of what these prospective customers are seeking from a prototype are delivered to our technical team.

Capital Requirements

As a development stage company, we do not generate revenues. We have incurred substantial net losses since inception. We have satisfied our capital requirements since inception primarily through the issuance and sale of our Common Stock.

Results of Operations

Comparison of three months ended September 30, 2019 to three months ended September 30, 2018

Revenues

As a development stage company, we had no revenues during the three months ended September 30, 2019 and September 30, 2018. The Company is in various stages of photonic device and material development and evaluation. We expect the next revenue stream to be in product development agreements and prototype devices prior to moving into production.

Operating Expenses

Our operating expenses were $1,575,947 and $1,443,534 for the three months ended September 30, 2019 and 2018, respectively, for an increase of $132,413. This is primarily due to increases in research and development salaries and wages, depreciation, non-cash stock option and warrant amortization, rent and utility expenses and director fees offset by decreases in recruiting fees, moving expenses, legal fees and general and administrative salaries and wages.

Included in our operating expenses for the three months ended September 30, 2019 was $1,134,372 for research and development expenses compared to $984,760 for the three months ended September 30, 2018, for an increase of $149,612. This is primarily due to increases in research and development salaries and wages, depreciation, non-cash stock option and warrant amortization and rent and utility expenses offset by decreases in moving expenses.

Research and development expenses currently consist primarily of compensation for employees and consultants engaged in internal research, product development activities; laboratory operations, prototypes electro-optic device design, development and internal material and device fabrication testing; prototype device processing; costs; and related operating expenses.

We expect to continue to incur substantial research and development expense to develop and commercialize our photonic devices, PIC development and electro-optic materials platform. These expenses will increase as a result of accelerated development effort to support commercialization of our non-linear optical polymer materials technology; to build photonic device prototypes in our in-house laboratories; hiring additional technical and support personnel; engaging a senior technical advisor; pursuing other potential business opportunities and collaborations; customer testing and evaluation; and incurring related operating expenses.

Wages and salaries, including benefits increased $63,637 from $463,760 for the three months ended September 30, 2018 to $527,397 for the three months ended September 30, 2019. The reason for the variation was primarily due to an increase in full time technical personnel working on device and material development.

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Depreciation expense increased $58,892 from $118,302 for the three months ended September 30, 2018 to $177,194 for the three months ended September 30, 2019. The primary reason for the increase was due to the addition of capital equipment for wafer fabrication and testing.

Research and development non-cash stock option and warrant amortization increased $35,481 from $45,429 for the three months ended September 30, 2018 to $80,910 for the three months ended September 30, 2019. The reason for the variation was due to stock options and warrants vesting schedules.

Rent and utilities increased $11,049 from $40,660 for the three months ended September 30, 2018 to $51,709 for the three months ended September 30, 2019 due to the increase in rent for the new facility combining the chemistry lab and device development into one facility.

Moving expenses decreased by $17,786 from $17,786 for the three months ended September 30, 2018 to $0 for the three months ended September 30, 2019. The primary reason for the decrease was the relocation of employees to the new facility during 2018.

General and administrative expense consists primarily of compensation and support costs for management staff, and for other general and administrative costs, including executive, sales and marketing, investor relations, accounting and finance, legal, consulting and other operating expenses.

General and administrative expenses decreased $17,199 to $441,575 for the three months ended September 30, 2019 compared to $458,774 for the three months ended September 30, 2018. The decrease is primarily due to decreases in recruiting fees, legal fees and general and administrative salary and wages offset by increases in general and administrative non-cash stock option and warrant amortization and director fees.

Recruiting fees decreased $24,500 from $24,500 for the three months ended September 30, 2018 to $0 for the three months ended September 30, 2019. The primary reason for the variance was due to a reduction in recruiting firm expenditures.

Legal fees decreased $16,261 from $29,448 for the three months ended September 30, 2018 to $13,187 for the three months ending September 30, 2019. The reason for the variation was due to a reduction in business legal expenditures.

General and administrative wages and salaries decreased $13,196 from $160,444 for the three months ended September 30, 2018 to $147,248 for the three months ended September 30, 2019. The decrease was due to a reduction in headcount.

General and administrative non-cash stock option and warrant amortization increased $18,864 from $66,170 for the three months ended September 30, 2018 to $85,034 for the three months ending September 30, 2019. The reason for the variation was due to stock options and warrants vesting schedules.

Director fees increased $10,000 from $0 for the three months ended September 30, 2018 to $10,000 for the three months ended September 30, 2019. The reason for the increase was due to implementation of director board meeting fees.

We expect general and administrative expense to increase in future periods as we increase the level of corporate and administrative activity, including increases associated with our operation as a public company; and significantly increase expenditures related to the future production and sales of our products.

Other Income (Expense)

Other expense decreased $20,902 from $54,167 for the three months ended September 30, 2018 to $33,265 for the three months ended September 30, 2019, relating to the commitment fee associated with the Purchase Agreement.

Net Loss

Net loss was $1,609,212 and $1,497,701 for the three months ended September 30, 2019 and 2018, respectively, for an increase of $111,511, due primarily to increases in research and development salaries and wages, depreciation, non-cash stock option and warrant amortization, rent and utility expenses and director fees offset by decreases in recruiting fees, decreases in commitment fee associated with the Purchase Agreement, moving expenses, legal fees and general and administrative salaries and wages.

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Comparison of nine months ended September 30, 2019 to nine months ended September 30, 2018

Revenues

As a development stage company, we had no revenues during the nine months ended September 30, 2019 and September 30, 2018. The Company is in various stages of photonic device and material development and evaluation. We expect the next revenue stream to be in product development agreements and prototype devices prior to moving into production.

Operating Expenses

Our operating expenses were $4,870,118 and $4,374,026 for the nine months ended September 30, 2019 and 2018, respectively, for an increase of $496,092. This is primarily due to increases in salaries and wages, depreciation, non-cash stock option and warrant amortization, laboratory and wafer fabrication materials and supplies, product development consulting expenses, director fees, accounting fees, and patent amortization offset by decreases in legal fees, moving expenses, rent and utility expenses, office expenses, recruiting fees, other tax expenses and repair expenses.

Included in our operating expenses for the nine months ended September 30, 2019 was $3,355,887 for research and development expenses compared to $2,830,785 for the nine months ended September 30, 2018, for an increase of $525,102. This is primarily due to increases in research and development salaries and wages, depreciation, laboratory and wafer fabrication materials and supplies, non-cash stock option and warrant amortization, product development consulting expenses and patent amortization offset by decreases in moving expenses, rent and utility expenses and repair expenses.

Research and development expenses currently consist primarily of compensation for employees and consultants engaged in internal research, product development activities; laboratory operations, prototypes electro-optic device design, development and internal material and device fabrication testing; prototype device processing; costs; and related operating expenses.

We expect to continue to incur substantial research and development expense to develop and commercialize our photonic devices, PIC development and electro-optic materials platform. These expenses will increase as a result of accelerated development effort to support commercialization of our non-linear optical polymer materials technology; to build photonic device prototypes in our in-house laboratories; hiring additional technical and support personnel; engaging a senior technical advisor; pursuing other potential business opportunities and collaborations; customer testing and evaluation; and incurring related operating expenses.

Wages and salaries increased $248,041 from $1,302,560 for the nine months ended September 30, 2018 to $1,550,601 for the nine months ended September 30, 2019. The reason for the variation was primarily due to an increase in full time technical personnel working on device and material development.

Depreciation expense increased $158,848 from $270,856 for the nine months ended September 30, 2018 to $429,704 for the nine months ended September 30, 2019. The primary reason for the increase was due to the addition of capital equipment for wafer fabrication and testing.

Laboratory and wafer fabrication materials and supplies increased $101,911 from $257,726 for the nine months ended September 30, 2018 to $359,637 for the nine months ended September 30, 2019. The primary reason for the increase was fabrication of prototype wafers, devices and electro-optic polymer material systems.

Research and development non-cash stock option amortization increased $63,323 from $197,493 for the nine months ended September 30, 2018 to $260,816 for the nine months ended September 30, 2019. The reason for the variation was due to stock options and warrants vesting schedules.

Product development consulting expenses increased $58,775 from $288,246 for the nine months ended September 30, 2018 to $347,021 for the nine months ended September 30, 2019. The primary reason for the increase was due to engaging outside consultants for device development and packaging.

Patent amortization increased by $15,824 from $44,956 for the nine months ended September 30, 2018 to $60,780 for the nine months ended September 30, 2019. The primary reason for the increase was the BrPhotonics patents purchased in September 2018.

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Moving expenses decreased $61,885 from $61,885 for the nine months ending September 30, 2018 to $0 for the nine months ending September 30, 2019. The reason for the variation was due to moving to a new facility during 2018.

Rent and utilities decreased $41,550 from $181,227 for the nine months ended September 30, 2018 to $139,677 for the nine months ended September 30, 2019 due to facility consolidation into a single location during 2018.

Repair expenses decreased $15,384 from $41,461 for the nine months ending September 30, 2018 to $26,077 for the nine months ending September 30, 2019. The reason for the decrease was due to facility consolidation into a single location during 2018.

General and administrative expense consists primarily of compensation and support costs for management staff, and for other general and administrative costs, including executive, sales and marketing, investor relations, accounting and finance, legal, consulting and other operating expenses.

General and administrative expenses decreased $29,010 to $1,514,231 for the nine months ended September 30, 2019 compared to $1,543,241 for the nine months ended September 30, 2018. The decrease is primarily due to decreases in legal fees, office expenses, recruiting fees, moving expenses, rent and utility expenses and other tax expenses offset by increases in general and administrative non-cash stock option and warrant amortization, director fees, general and administrative salary and wages and accounting fees.

Legal fees decreased $85,774 from $202,679 for the nine months ended September 30, 2018 to $116,905 for the nine months ended September 30, 2019. The reason for the variation was due to a reduction in business legal expenditures.

Office expenses decreased $36,966 from $94,175 for the nine months ended September 30, 2018 to $57,209 for the nine months ended September 30, 2019. The reason for the variation was due to facility consolidation into a single location during the first quarter of 2018.

Recruiting fees decreased $36,812 from $40,500 for the nine months ended September 30, 2018 to $3,688 for the nine months ended September 30, 2019. The primary reason for the variance was due to a reduction in recruiting firm expenditures.

Moving expenses decreased $20,606 from $20,606 for the nine months ended September 30, 2018 to $0 for the nine months ended September 30, 2019. The reason for the variation was due to moving to a new facility during the first quarter of 2018.

Rent and utilities decreased $20,259 from $71,357 for the nine months ended September 30, 2018 to $51,098 for the nine months ended September 30, 2019. The reason for the variation was due to facility consolidation into a single location.

Other tax expenses decreased $16,345 from $26,694 for the nine months ended September 30, 2018 to $10,349 for the nine months ended September 30, 2019. The reason for the variation was due to the timing of payments of personal property tax.

General and administrative non-cash stock option and warrant amortization increased $92,466 from $204,314 for the nine months ended September 30, 2018 to $296,780 for the nine months ended September 30, 2019. The reason for the variation was due to stock options and warrants vesting schedules.

Director fees increased $31,500 from $0 for the nine months ended September 30, 2018 to $31,500 for the nine months ended September 30, 2019. The reason for the increase was due to implementation of director board meeting fees.

General and administrative wages and salaries increased $30,502 from $399,243 for the nine months ended September 30, 2018 to $429,745 for the nine months ended September 30, 2019. The increase was due to salary and headcount increases.

Accounting fees increased $19,625 from $106,750 for the nine months ended September 30, 2018 to $126,375 for the nine months ended September 30, 2019. The primary reason for the increase was due to the additional work being an accelerated filer and general accounting expense.

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We expect general and administrative expense to increase in future periods as we increase the level of corporate and administrative activity, including increases associated with our operation as a public company; and significantly increase expenditures related to the future production and sales of our products.

Other Income (Expense)

Other expenses increased $238,555 from $135,146 for the nine months ended September 30, 2018 to $373,701 for the nine months ended September 30, 2019, relating to the commitment fee associated with the Purchase Agreement.

Net Loss

Net loss was $5,243,819 and $4,509,172 for the nine months ended September 30, 2019 and 2018, respectively, for an increase of $734,647, due primarily to increases in salaries and wages and the commitment fee associated with the Purchase Agreement, depreciation, non-cash stock option and warrant amortization, laboratory and wafer fabrication materials and supplies, product development consulting expenses, director fees, accounting fees, and patent amortization offset by decreases in legal fees, moving expenses, rent and utility expenses, office expenses, recruiting fees, other tax expenses and repair expenses.

Comparison of Fiscal 2018 to Fiscal 2017

Revenues

As a development stage company, we had no revenues during the years ended December 31, 2018 and December 31, 2017. The Company is in various stages of photonic device and material development and evaluation. We expect the next revenue stream to be in product development agreements and prototype devices prior to moving into production.

Operating Expenses

Our operating expenses were $5,601,016 and $5,523,538 for the years ended December 31, 2018 and 2017, respectively, for an increase of $77,478. This increase in operating expenses was due primarily to increases in salaries and wages, depreciation, laboratory materials and supplies, rent and utility expenses, consulting expense, travel expenses, office expenses, accounting fees, auditing fees, moving expenses, other tax expenses, director and officer insurance expenses, and repair offset by decreases in non-cash stock option and warrant amortization, legal, laboratory material testing expense and electro-optic device development, patent amortization and patent related expenses,  royalty fees and recruiting fees.   

Included in our operating expenses for the year ended December 31, 2018 was $3,794,565 for research and development expenses compared to $3,519,129 for the year ended December 31, 2017, for an increase of $275,436.  This is primarily due to increases in research and development salaries and wages, depreciation, laboratory materials and supplies, rent and utility expenses, travel expenses, product development consulting expenses, research and development moving expenses, research and development office expenses and repair and maintenance expenses offset by decreases in non-cash stock option amortization, laboratory material testing expense and electro-optic device development, patent amortization and patent related expenses and royalty fees.

Research and development expenses currently consist primarily of compensation for employees and consultants engaged in internal research, product development activities; laboratory operations, internal material and device fabrication testing and prototype electro-optic device design, development and prototype device processing; costs; and related operating expenses.

We expect to continue to incur substantial research and development expense to develop and commercialize our photonic devices PIC development and electro-optic materials platform. These expenses will increase as a result of accelerated development effort to support commercialization of our non-linear optical polymer materials technology; to build photonic device prototypes in our in-house laboratories; hiring additional technical and support personnel; engaging a senior technical advisor; pursuing other potential business opportunities and collaborations; customer testing and evaluation; and incurring related operating expenses.

Wages and salaries increased $428,337 from $1,357,594 for the year ended December 31, 2017 to $1,785,931 for the year ended December 31, 2018. The reason for the variation was primarily due to an increase in full time technical personnel working on device and material development and change in research and development allocation.

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Depreciation expense increased $213,905 from $177,638 for the year ended December 31, 2017 to $391,543 for the year ended December 31, 2018.  The primary reason for the increase was due to the addition of capital equipment for wafer fabrication in the new facility.

Laboratory materials and supplies increased $139,698 from $202,304 for the year ended December 31, 2017 to $342,002 for the year ended December 31, 2018. The primary reason for the increase was fabrication of prototype wafers and devices, and e.o. polymer material systems.

Rent and utility expenses increased $69,793 from $151,932 for the year ended December 31, 2017 to $221,725 for the year ended December 31, 2018. The primary reason for the increase was due to acquiring a larger facility in order to consolidate all the Company’s operations into one facility.

Travel expenses increased by $53,967 to $114,258 for the year ended December 31, 2018 from $60,291 for the year ended December 31, 2017.  The increase was primarily due to employee travel for relocation planning and conferences.

Product development consulting expenses increased $47,290 from $372,981 for the year ended December 31, 2017 to $420,271 for the year ended December 31, 2018.  The primary reason for the increase was due to engaging outside consultants to speed up device development.

Moving expenses increased by $19,983 to $63,511 for the year ended December 31, 2018 from $43,528 for the year ended December 31, 2017.  The primary reason for the increase was the relocation to the new facility.

Office expenses increased by $18,596 to $25,361 for the year ended December 31, 2018 from $6,765 for the year ended December 31, 2017.  The increase was primarily due furnishing the new Colorado facility.

Repair and maintenance expenses increased by $13,726 to $44,459 for the year ended December 31, 2018 from $30,733 for the year ended December 31, 2017. The primary reason for the increase was due to general maintenance in the new Colorado facility.

Research and development non-cash stock option amortization decreased $493,210 from $713,783 for the year ended December 31, 2017 to $220,573 for the year ended December 31, 2018.  The reason for the variation in decreased amortization was the vesting schedules.

Product prototype development and material testing expense decreased $155,149 from $219,650 for the year ended December 31, 2017 to $64,501 for the year ended December 31, 2018. The decrease was primarily due to the move to the new facility and transitioning of outside services in-house.

Patent amortization and patent related expenses decreased by $65,250 to $65,015 for the year ended December 31, 2018 from $130,265 for the year ended December 31, 2017. The primary reason for the decrease was lower cost in patent application prosecution.

Royalty expenses decreased $30,000 to $0 for the year ended December 31, 2018 from $30,000 for the year ended December 31, 2017. The primary reason for the decrease was the termination of a license agreement.

General and administrative expense consists primarily of compensation and support costs for management staff, and for other general and administrative costs, including executive, sales and marketing, investor relations, accounting and finance, legal, consulting and other operating expenses.

General and administrative expenses decreased $197,958 to $1,806,451 for the year ended December 31, 2018 from $2,004,409 for the year ended December 31, 2017. The decrease is primarily due to decreases in legal fees, general and administrative non-cash stock option and warrant amortization and recruiting fees offset by increases in office expenses, rent and utility expenses, accounting fees, general and administrative consulting, auditing fees, travel, moving expenses, general and administrative salary and wages, other tax expenses and director and officer insurance expenses.

Legal fees decreased $262,429 to $91,007 for the year ended December 31, 2018 from $353,436 for the year ended December 31, 2017. The primary reason for the variance was an overall decrease in general legal work.

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General and administrative non-cash stock option and warrant amortization decreased $252,384 from $497,889 for the year ended December 31, 2017 to $245,505 for the year ended December 31, 2018. The reason for the variation was due to stock options and warrants vesting schedules.

Recruiting fees decreased $10,000 to $40,500 for the year ended December 31, 2018 from $50,500 for the year ended December 31, 2017.  The primary reason for the variance was due to a reduction in employment activity with a recruiting firm.

Office expenses increased $60,826 from $44,598 for the year ended December 31, 2017 to $105,424 for the year ended December 31, 2018. The reason for the variation was due to relocating into a larger facility.

Rent and utility expenses increased $43,134 from $43,552 for the year ended December 31, 2017 to $86,686 for the year ended December 31, 2018. The primary reason was due to support of the new larger facility.  

Accounting fees increased $40,666 to $145,750 for the year ended December 31, 2018 from $105,084 for the year ended December 31, 2017. The primary reason for the increase was due to the additional work being an accelerated filer and general accounting expense.

General and administrative consulting fees increased $40,124 from ($15,958) for the year ended December 31, 2017 to $24,166 for the year ended December 31, 2018. The primary reason for the increase was due to a non-cash consulting expense.

Travel expenses increased $32,009 to $73,307 for the year ended December 31, 2018 from $41,298 for the year ended December 31, 2017. The primary reason for the increase was due to travel expense to the new facility and conferences.

General and administrative wages and salaries increased $26,305 from $533,676 for the year ended December 31, 2017 to $559,981 for the year ended December 31, 2018.  The primary reason for the increase was due to increase in fringe benefit costs and additional head count.

Auditing fees increased $24,925 to $87,600 for the year ended December 31, 2018 from $62,675 for the year ended December 31, 2017. The primary reason for the increase was due to the Company’s change in status to an Accelerated Filer, which requires additional testing by the auditors.

Moving expenses increased $20,606 to $20,606 for the year ended December 31, 2018 from $0 for the year ended December 31, 2017. The reason for the variation was due to moving to a new facility.

Other tax expenses increased $16,884 to $29,608 for the year ended December 31, 2018 from $12,724 for the year ended December 31, 2017. The primary reason for the increase was due to sales and use tax on capital equipment for new facility.

Director and officer insurance expense increased $14,207 from $131,787 for the year ended December 31, 2017 to $145,994 for the year ended December 31, 2018. The primary reason for the increase was an increase in insurance premiums.

We expect general and administrative expense to increase in future periods as we increase the level of corporate and administrative activity, including increases associated with our operation as a public company; and significantly increase expenditures related to the future production and sales of our products. 

Other Income (Expense)

Other expenses decreased $53,902 to $171,942 for the year ended December 31, 2018 from $225,844 for the year ended December 31, 2017, relating to the commitment fee associated with the Purchase Agreement.

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Net Loss

Net loss was $5,772,958 and $5,749,382 for the years ended December 31, 2018 and 2017, respectively, for a increase of $23,576, due primarily to increases in salaries and wages, depreciation, laboratory materials and supplies, rent and utility expenses, consulting expenses, travel expenses, office expenses, accounting fees, auditing fees, moving expenses, other tax expenses, director and officer insurance expenses and repair  expenses offset by decreases in non-cash stock option and warrant amortization, legal, laboratory material testing expense and electro-optic device development, patent amortization and patent related expenses, commitment fee associated with the Purchase Agreement, royalty fees and recruiting fees.

Significant Accounting Policies

Our Company's accounting policies are more fully described in Note 1 of Notes to the Financial Statements. As disclosed in Note 1 of Notes to the Financial Statements, the preparation of financial statements in conformity with accounting principles generally accepted in the United States requires management to make estimates and assumptions that affect the amounts reported in the financial statements and accompanying disclosures. Although these estimates are based on our management’s best knowledge of current events and actions our Company may undertake in the future, actual results could differ from the estimates.

Recently Adopted Accounting Pronouncements. In July 2018, the FASB issued ASU No. 2018-11, Leases (Topic 842), Targeted Improvements. The amendments in this Update relieve businesses and organizations from having to present prior comparative years’ results when they adopt the new standard. It also lets landlords and other lessors avoid breaking out the parts of a rental contract that are not specifically being leased, such as the cost of snow removal services, and account for them separately from the base rent. The amendments in this Update are the same as the effective dates and transition requirements in ASU No. 2016-02, Leases.

We are in the process of evaluating the above ASUs and estimating lease liabilities and corresponding right-of-use assets as of January 1, 2019.

Reclassifications. Certain reclassifications have been made to the 2017 financial statement in order to conform to the 2018 financial statement presentation.

Recently Adopted Accounting Pronouncements. In June 2018, the FASB issued ASU No. 2018-07, Compensation – Stock Compensation (Topic 718), Improvements to Nonemployee Share-Based Payment Accounting. The amendments in this Update expand the scope of Topic 718 to include share-based payment transactions for acquiring goods and services from nonemployees. Prior to this Update, Topic 718 applied only to share-based transactions to employees. Consistent with the accounting requirement for employee share-based payment awards, nonemployee share-based payment awards within the scope of Topic 718 are measured at grant-date fair value of the equity instruments that an entity is obligated to issue when the good has been delivered or the service has been rendered and any other conditions necessary to earn the right to benefit from the instruments have been satisfied. The amendments in this Update are effective for public business entities for fiscal years beginning after December 15, 2018, including interim periods within that fiscal year. Early adoption is permitted, but no earlier than an entity’s adoption date of Topic 606. The adoption of this pronouncement on June 30, 2018 had no material impact on the Company’s financial statements.

Reclassifications. Certain reclassifications have been made to the 2017 financial statement in order to conform to the 2018 financial statement presentation.

Stock Based Compensation

Our Company uses the Black-Scholes option pricing model to calculate the grant-date fair value of an award, with the following assumptions for 2018: no dividend yield in all years, expected volatility, based on the Company’s historical volatility, 60% to 90%, risk-free interest rate between 1.89% to 3.06% and expected option life of 5.0 to 10 years.  Prior to May 2018, the expected life was based on the estimated average of the life of options using the “simplified” method, as prescribed in FASB ASC 718, due to insufficient historical exercise activity during recent years.  Starting in May 2018, the expected life became based on the legal contractual life of options. The Company uses the Black-Scholes option pricing model to calculate the grant-date fair value of an award, with the following assumptions for 2017: no dividend yield in all years, expected volatility, based on the Company’s historical volatility, 39% to 87%, risk-free interest rate between 1.16% to 2.37% and expected option life of .03 to 9.08 years.

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As of December 31, 2018, there was $324,497 of unrecognized compensation expense related to non-vested market-based share awards that is expected to be recognized through August 30, 2020.

Liquidity and Capital Resources

For the nine months ended September 30, 2019

During the nine months ended September 30, 2019, net cash used in operating activities was $3,554,398 and net cash used in investing activities was $267,535, which was due primarily to the Company’s research and development activities and general and administrative expenditures. Net cash provided by financing activities for the nine months ended September 30, 2019 was $3,815,085. At September 30, 2019, our cash and cash equivalents totaled $2,167,777, our assets totaled $6,602,627, our liabilities totaled $1,842,315, and we had stockholders’ equity of $4,760,312.

For the nine months ended September 30, 2018

During the nine months ended September 30, 2018, net cash used in operating activities was $3,404,846 and net cash used in investing activities was $1,266,594, which was due primarily to the Company’s research and development activities, general and administrative expenditures and capital expenditures. Net cash provided by financing activities for the nine months ended September 30, 2018 was $3,393,430. At September 30, 2018, our cash and cash equivalents totaled $2,204,317, our assets totaled $5,237,215, our liabilities totaled $418,632, and we had stockholders’ equity of $4,818,583.

For the year ended December 31, 2018

During the year ended December 31, 2018, net cash used in operating activities was $4,400,965 and net cash used in investing activities was $1,432,363, which was due primarily to the Company’s research and development activities and general and administrative expenditures.  Net cash provided by financing activities for the year ended December 31, 2018 was $4,525,626.  At December 31, 2018, our cash and cash equivalents totaled $2,174,625, our assets totaled $5,251,264, our liabilities totaled $344,202, and we had stockholders’ equity of $4,907,062.

For the year ended December 31, 2017

During the year ended December 31, 2017, net cash used in operating activities was $4,409,696 and net cash used in investing activities was $265,532, which was due primarily to the Company’s research and development activities and general and administrative expenditures. Net cash provided by financing activities for the year ended December 31, 2017 was $6,200,711. At December 31, 2017, our cash and cash equivalents totaled $3,482,327, our assets totaled $5,849,770, our liabilities totaled $833,055 and we had stockholders’ equity of $5,016,715.

Sources and Uses of Cash

Our future expenditures and capital requirements will depend on numerous factors, including: the progress of our research and development efforts; the rate at which we can, directly or through arrangements with original equipment manufacturers, introduce and sell products incorporating our polymer materials technology; the costs of filing, prosecuting, defending and enforcing any patent claims and other intellectual property rights; market acceptance of our products and competing technological developments; and our ability to establish cooperative development, joint venture and licensing arrangements. We expect that we will incur approximately $584,000 of expenditures per month over the next 12 months. We expect our Lincoln Park financing (described below) to provide us with sufficient funds to maintain our operations over that period of time. Our current cash position enables us to finance our operations through March 2020 before we will be required to replenish our cash reserves pursuant to the Lincoln Park financing. Our cash requirements are expected to increase at a rate consistent with the Company’s path to revenue growth as we expand our activities and operations with the objective of commercializing our electro-optic polymer technology. We currently have no debt to service.

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On January 21, 2019, our Company entered into the Purchase Agreement with Lincoln Park, pursuant to which Lincoln Park agreed to purchase from us up to $25,000,000 of our Common Stock (subject to certain limitations) from time to time over a 36-month period. Pursuant to the Purchase Agreement, Lincoln Park is obligated to make purchases as the Company directs in accordance with the Purchase Agreement, which may be terminated by the Company at any time, without cost or penalty. Sales of shares will be made in specified amounts and at prices that are based upon the market prices of our Common Stock immediately preceding the sales to Lincoln Park. We expect this financing to provide us with sufficient funds to maintain our operations for the foreseeable future. With the additional capital, we expect to achieve a level of revenues attractive enough to fulfill our development activities and adequate enough to support our business model for the foreseeable future. We cannot assure you that we will meet the conditions of the Purchase Agreement with Lincoln Park in order to obligate Lincoln Park to purchase our shares of Common Stock. In the event we fail to do so, and other adequate funds are not available to satisfy long-term capital requirements, or if planned revenues are not generated, we may be required to substantially limit our operations. This limitation of operations may include reductions in capital expenditures and reductions in staff and discretionary costs.

There are no trading volume requirements or restrictions under the Purchase Agreement, and we will control the timing and amount of any sales of our Common Stock to Lincoln Park. Lincoln Park has no right to require any sales by us, but is obligated to make purchases from us as we direct in accordance with the Purchase Agreement. We can also accelerate the amount of Common Stock to be purchased under certain circumstances. There are no limitations on use of proceeds, financial or business covenants, restrictions on future funding, rights of first refusal, participation rights, penalties or liquidated damages in the Purchase Agreement. Lincoln Park may not assign or transfer its rights and obligations under the purchase agreement.

We expect that our cash used in operations will continue to increase during 2020 and beyond as a result of the following planned activities:

Analysis of Cash Flows

For the nine months ended September 30, 2019

Net cash used in operating activities was $3,554,398 for the nine months ended September 30, 2019, primarily attributable to the net loss of $5,243,819 adjusted by $57,005 in warrants issued for services, $500,591 in options issued for services, $373,888 in Common Stock issued for services, $499,197 in depreciation expenses and patent amortization expenses, $269,630 in prepaid expenses and ($10,890) in accounts payable and accrued expenses. Net cash used in operating activities consisted of payments for research and development, legal, professional and consulting expenses, rent and other expenditures necessary to develop our business infrastructure.

Net cash used by investing activities was $267,535 for the nine months ended September 30, 2019, consisting of $52,022 in cost for intangibles and $215,513 in asset additions primarily for the new Colorado headquarter facility and labs.

Net cash provided by financing activities was $3,815,085 for the nine months ended September 30, 2019 and consisted of $4,165,585 in proceeds from resale of Common Stock to Lincoln Park offset by $350,500 repayment of equipment purchased.

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For the nine months ended September 30, 2018

Net cash used in operating activities was $3,404,846 for the nine months ended September 30, 2018, primarily attributable to the net loss of $4,509,172 adjusted by $62,731 in warrants issued for services, $339,076 in options issued for services, $135,333 in Common Stock issued for services, $322,495 in depreciation expenses and patent amortization expenses, $10,084 net loss on disposal of equipment, $268,560 in prepaid expenses and ($33,953) in accounts payable and accrued expenses. Net cash used in operating activities consisted of payments for research and development, legal, professional and consulting expenses, rent and other expenditures necessary to develop our business infrastructure.

Net cash used by investing activities was $1,266,594 for the nine months ended September 30, 2018, consisting of $371,320 in cost for intangibles and $897,774 in asset additions primarily for the new Colorado headquarter facility offset by proceeds of $2,500 on the sale of equipment.

Net cash provided by financing activities was $3,393,430 for the nine months ended September 30, 2018 and consisted of $3,612,400 in proceeds from resale of Common Stock to Lincoln Park and $161,500 in proceeds from exercise of warrants and options offset by $380,470 repayment of equipment purchased.

For the year ended December 31, 2018

Net cash used in operating activities was $4,400,965 for the year ended December 31, 2018, primarily attributable to the net loss of $5,772,958 adjusted by $78,390 in warrants issued for services, $387,688 in options issued for services, $172,192 in Common Stock issued for services, $465,795 in depreciation expenses and patent amortization expenses, $10,084 net loss on disposal of equipment, $247,288 in prepaid expenses and $10,556 in accounts payable and accrued expenses.  Net cash used in operating activities consisted of payments for research and development, legal, professional and consulting expenses, rent and other expenditures necessary to develop our business infrastructure.

Net cash used by investing activities was $1,432,363 for the year ended December 31, 2018, consisting of $397,479 in cost for intangibles and $1,037,384 in asset additions primarily for the new Colorado headquarter facility offset by proceeds of $2,500 on the sale of equipment.

Net cash provided by financing activities was $4,525,626 for the year ended December 31, 2018 and consisted of $4,863,535 in proceeds from resale of Common Stock to Lincoln Park and $161,500 in proceeds from exercise of warrants and options offset by $499,409 repayment of equipment purchased.

Off-Balance Sheet Arrangements

As of September 30, 2019, we do not have an interest in any off-balance sheet arrangements as defined in Item 303(a)(4) of Regulation S-K that have or are reasonably likely to have a current or future effect on our financial condition, changes in financial condition, revenues or expenses, results of operations, liquidity, capital expenditures, or capital resources that is material to investors.

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BUSINESS

Overview

We were incorporated under the laws of the State of Nevada on June 24, 1997 and in 2004 we acquired PSI-TEC Corp., and in 2006 we merged with PSI-TEC Corp. PSI-TEC Corp. was incorporated under the laws of the State of Delaware on September 12, 1995. In 2008 we changed our name to Lightwave Logic, Inc. Unless the context otherwise requires, all references to the “Company,” “we,” “our” or “us” and other similar terms means Lightwave Logic, Inc., a Nevada corporation.

Our principal executive office is located at 369 Inverness Parkway, Suite 350, Englewood, CO  80112, and our telephone number is (720) 340-4949. Our website address is www.lightwavelogic.com. No information found on our website is part of this Registration Statement. Also, this prospectus includes the names of various government agencies and the trade names of other companies. Unless specifically stated otherwise, the use or display by us of such other parties' names and trade names in this prospectus is not intended to and does not imply a relationship with, or endorsement or sponsorship of us by, any of these other parties.

Materials Development

Our Company designs and synthesizes organic chromophores for use in its own proprietary electro-optic polymer systems and photonic device designs. A polymer system is not solely a material, but also encompasses various technical enhancements necessary for its implementation. These include host polymers, poling methodologies, and molecular spacer systems that are customized to achieve specific optical properties. Our organic electro-optic polymer systems compounds are mixed into solution form that allows for thin film application. Our proprietary electro-optic polymers are designed at the molecular level for potentially superior performance, stability and cost-efficiency. We believe they have the potential to replace more expensive, higher power consuming, slower-performance materials and devices used in fiber-optic communication networks.

Our patented and patent pending molecular architectures are based on a well-understood chemical and quantum mechanical occurrence known as aromaticity. Aromaticity provides a high degree of molecular stability that enables our core molecular structures to maintain stability under a broad range of operating conditions.

We expect our patented and patent-pending optical materials along with trade secrets and licensed materials, to be the core of and the enabling technology for future generations of optical devices, modules, sub-systems and systems that we will develop or potentially out-license to electro-optic device manufacturers. Our Company contemplates future applications that may address the needs of semiconductor companies, optical network companies, Web 2.0 media companies, high performance computing companies, telecommunications companies, aerospace companies, and government agencies. 

Device Design and Development

Electro-optic Modulators

Our Company designs its own proprietary electro-optical modulation devices. Electro-optical modulators convert data from electric signals into optical signals that can then be transmitted over high-speed fiber-optic cables. Our modulators are electro-optic, meaning they work because the optical properties of the polymers are affected by electric fields applied by means of electrodes. Modulators are key components that are used in fiber optic telecommunications, data communications, and data centers networks etc., to convey the high data flows that have been driven by applications such as pictures, video streaming, movies etc., that are being transmitted through the internet. Electro-optical modulators are expected to continue to be an essential element as the appetite and hunger for data increases every year.

Polymer Photonic Integrated Circuits (P²IC^TM)

Our Company also designs its own proprietary polymer photonic integrated circuits (otherwise termed a polymer PIC). A polymer PIC is a photonic device that integrates several photonic functions on a single chip. We believe that our technology can enable the ultra-miniaturization needed to increase the number of photonic functions residing on a semiconductor chip to create a progression like what was seen in the computer integrated circuits, commonly referred to as Moore’s Law. One type of integration is to combine several instances of the same photonic functions such as a plurality of modulators to create a 4 channel polymer PIC. In this case, the number of photonic components would increase by a factor of 4. Another type is to combine different types of devices including from different technology bases such as the combination of a semiconductor laser with a polymer modulator. Our P²IC™ platform encompasses both these types of architecture.

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Current photonic technology today is struggling to reach faster device speeds. Our modulator devices, enabled by our electro-optic polymer material systems, work at extremely high frequencies (wide bandwidths) and possess inherent advantages over current crystalline electro-optic material contained in most modulator devices such as lithium niobate (LiNbO3), indium phosphide (InP), silicon (Si), and gallium arsenide GaAs). Our advanced electro-optic polymer platform is creating a new class of modulators and associated PIC platforms that can address higher data rates in a lower cost, lower power consuming manner, with much simpler modulation techniques.

Our electro-optic polymers can be integrated with other materials platforms because they can be applied as a thin film coating in a fabrication clean room such as may be found in semiconductor foundries. Our polymers are unique in that they are stable enough to seamlessly integrate into existing CMOS, Indium Phosphide (InP), Gallium Arsenide (GaAs), and other semiconductor manufacturing lines.

Glossary

Glossary of select technology terms to provide you with a better understanding our Company’s technology and devices:

Electro-optic devices - Electro-optic devices convert data from electric signals into optical signals for use in communications systems and in optical interconnects for high-speed data transfer.

Electro-optic material - Electro-optic material is the core active ingredient in high-speed fiber-optic telecommunication systems. Electro-optic materials are materials that are engineered at the molecular level. Molecular level engineering is commonly referred to as “nanotechnology.”

Electro-optic modulators - Electro-optic (E/O) modulators are electro-optic devices that perform electric-to-optic conversions within the infrastructure of the internet. Data centers may also benefit from this technology through devices that could significantly increase bandwidth and speed while decreasing costs. Polymer E/O modulators can be designed and fabricated with multiple structures such as Ridge waveguide and slot waveguide. The waveguides allow the light to be efficiently coupled into and out of the modulators, and provide a basis for integrating modulators together.

Photonic Devices - Photonic devices are components for creating, manipulating or detecting light. This can include modulators, laser diodes, light-emitting diodes, solar and photovoltaic cells, displays and optical amplifiers. Other examples are devices for modulating a beam of light and for combining and separating beams of light of different wavelength.

Polymers - Polymers, also known as plastics, are large carbon-based molecules that bond many small molecules together to form a long chain. Polymer materials can be engineered and optimized using nanotechnology to create a system in which unique surface, electrical, chemical and electro-optic characteristics can be controlled. Materials based on polymers are used in a multitude of industrial and consumer products, from automotive parts to home appliances and furniture, as well as scientific and medical equipment.

Our Business Opportunity

Lightwave Logic, Inc. is developing next generation proprietary photonic devices that are based on our advanced electro-optical polymer material systems. Current legacy technology is based on inorganic crystalline materials, which has allowed for the proliferation of data over fiber optic cables. However, there are inherent molecular deficiencies that have prevented this technology from scaling down in price and up in functionality, especially in terms of $/Gbps. This is primarily due to a closed valence structure that does not allow for the molecular improvements. The valence or valency of an element is a measure of its combining power with other atoms when it forms chemical compounds or molecules. Also, the physical properties of a crystal do not allow for its implementation into highly miniaturize slot structures that are in simple terms the pathways that light travels through in the device.

Organic polymer materials on the other hand, have free electrons that allow for limitless potential to combine with other molecular structures, which allows for multiple options and combinations to improving performance characteristics. Importantly, because they can be applied to optical structures in thin-film liquid form, it is possible to imbue electro-optic ability to highly miniaturized slot structures. Organic polymer materials are also vastly cheaper to manufacture in comparison to growing exotic crystals that are prone to contamination and further must be sliced into thin wafers. Our Company believes that the combination of less expensive manufacturing cost, ease of application, and better scalability, together with a lower cost of ownership due to marked less heat dissipation (requiring less cooling), will create enormous demand for our products.

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Many companies’ early attempts at developing commercially reliable organic polymers were stymied due to the difficulty of creating organic molecules that could remain electro-optically active after being subjected to the high heat of semiconductor manufacturing temperatures (such as silicon CMOS, InP, GaAs etc.). These early attempts also encountered difficulty synthesizing materials that could withstand photochemical bleaching (loss of sensitivity to specific frequencies) and material degradation due to high operating temperatures.

Over the last several years, our Company has made various scientific breakthroughs that have allowed for the synthesis of proprietary organic polymer materials that can withstand extremely high process temperatures of 175⁰C. Additionally, these materials have demonstrated photochemical stability, even after being subjected to tensor light for over 4,000 hours and exhibited little electro optic degradation even after 2,500 hours of continuous exposure to temperatures at 110⁰C – exceeding typical commercial operating temperatures of approximately 85⁰C, as found in data center applications. After successfully achieving material test results that either met or exceeded commercial requirements (subsequently confirmed by an outside entity), in late 2016, the Company began production of its first photonic prototype device, a ridge waveguide modulator.

Our First Product – The Ridge Waveguide Modulator

A ridge waveguide modulator is a type of modulator where the waveguide is fabricated within a layer of our electro-optic polymer system. Various cladding materials and electrodes are layered over the core polymer. The polymer materials are then part of an integrated photonics platform that can house other photonic devices, such as lasers, waveguides etc.

In April 2017 we achieved bandwidth suitable for 25Gbps data rates in an all-organic polymer ridge waveguide intensity modulator prototype, a significant improvement over our initial 10Gbps device modulator prototype that was announced in 2016. This breakthrough was significant because a 25Gbps data rate is important to the optical networking industry because this data rate is a major node to achieve 100 Gbps (using 4 channels of 25 Gbps). In July 2017 we advanced our high-speed modulation performance to satisfy 28Gbps data rates for QSFP28 standards and 100Gbps data center applications.

In September 2017 we achieved outstanding performance of our ridge waveguide Mach-Zehnder modulators ahead of schedule, with bandwidth performance levels that will enable 50Gbps modulation in fiber-optic communications. This important achievement will allow users to utilize arrays of 4 x 50Gbps polymer modulators using PAM-4 encoding to access 400Gbps data rate systems. Pulse-Amplitude Modulation (PAM-4) is an encoding scheme that can double the amount of data that can be transmitted.

We are now optimizing our high-performance modulators against typical specifications that are required by the fiber communications industry. Furthermore, we are packaging our modulators with our packaging partner so that potential customers can evaluate our high-performance modulators in their systems. One of the most under-evaluated processes of developing high speed devices onto a new and novel technology platform is robustness and reliability. We have already made extensive progress with our polymer materials on this front, and now we are integrating our robust polymer materials onto an integrated photonics platform to provide customers with a more miniaturized, higher performance solution for their data rich systems.

We have also shown that with standard simulation and modeling of our devices, there is a potential to scale the high-speed performance beyond that of 50Gbps, thus providing a technology platform for even greater data rates in the future. This means that our technology platform using polymers is both scalable in high performance as well as scalable in miniaturization and low cost, something that the fiber communications industry has been searching for a long time.

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While our initial focus is to address data communications and telecommunications network applications along with cloud computing/data center needs, we believe that in the future we will have additional opportunities to address other applications such as: backplane optical interconnects, photovoltaic cells, medical applications, satellite reconnaissance, navigation systems, radar applications, optical filters, spatial light modulators; and all-optical switches.

Electro-Optic Polymer Production – Our Approach vs. the BLA Approach

Our Electro-Optic Material Approach

Our core material expertise relates to the production of high-performance, high-stability electro-optic polymers for high-speed (wide bandwidth) telecommunication and data communications applications. More specifically, it lies in a less mainstream, yet firmly established, scientific phenomenon called aromaticity. Aromaticity causes a high degree of molecular stability. It is a molecular arrangement wherein atoms combine into multi-membered rings and share their electrons among each other. Aromatic compounds are stable because the electronic charge distributes evenly over a great area preventing hostile moieties, such as oxygen and free radicals, from finding an opening to attack.

Previous and Current Competitive Organic Electro-Optic Polymer Efforts

For the past several decades, diverse corporate interests, including, to our knowledge, IBM, Lockheed Martin, DuPont, AT&T Bell Labs, Honeywell, Motorola, HP, 3M, and others in addition to numerous universities and U.S. Government Agencies, have attempted to produce high-performance, high-stability electro-optic polymers for high-speed (wide bandwidth) telecommunication applications. These efforts were largely unsuccessful due, in our opinion, to the industry's singular adherence to an industry pervasive engineering model known as the Bond Length Alternation ("BLA") theory model, which none of our patented molecular designs rely upon. The BLA model, like all other current industry-standard molecular designs, consists of molecular designs containing long strings of atoms called polyene chains. Longer polyene chains provide higher electro-optic performance, but are also more susceptible to environmental threats, which result in unacceptably low-performing, thermally unstable electro-optic polymers.

As a result, high frequency modulators engineered with electro-optic polymers designed on the BLA model or any other polyene chain design models are unstable over typical operating temperature ranges, and often exhibit performance degradation within days, hours or even minutes. Similarly, lower frequency modulators exhibit comparable failings, but to a lesser extent. These flaws, in most cases, have prevented commercial quality polymer-based modulators from entering the commercial marketplace. The thermal stability of these devices does not generally meet the minimum Telcordia GR-468 operating temperature range (-40 degrees Celsius to +85 degrees Celsius) much less the harsher MILSPEC 883D (military specification) range of -55 degrees Celsius to 150 degrees Celsius. While many new applications do not require full military specifications for polymers, many potential customers prefer to see polymer operate at or near these conditions to convey confidence in the material system. We understand from initial conversations with data center architects and designers that the temperature specifications that our materials achieve are compliant with their equipment design needs.

We are aware of other academic and commercial development efforts—some by larger companies with vastly more financial resources than we possess. However, we believe that no one yet has developed organic polymer materials that have demonstrated the combination of thermal stability, photochemical stability that can meet or exceed commercial specifications.

Our Electro-Optic Photonic P²IC^TM Device Approach

Our electro-optic devices are built around our proprietary organic polymer material systems that we believe will enable better performance than the current embedded legacy technology built around inorganic materials. We also believe that the inherent flexibility of being able to apply our organic polymer materials in liquid thin-film form will accelerate the move toward ultra-miniaturization of Polymer Photonic Integrated Circuits (P²IC^TM) by increasing the number of photonic circuits on a single chip. Polymer photonics (previously referred in industry as silicon organic hybrid (SOH)) is the application of polymers on to a platform such as silicon where there are both active and passive photonic component designs. In polymer photonics, polymer devices such as modulators, waveguides, and multiplexers can be fabricated on to a silicon platform that acts as a package as well as a base for mounting lasers (which are needed to source the light).

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Our initial device, a ridge waveguide modulator, though highly miniaturized utilizes conventional design and fabrication techniques in the industry. Our future devices will utilize silicon photonics (SiP) technology, which can support highly miniaturized slot waveguides structures etched in large format, low cost, and less expensive silicon wafers coated with our organic electro-optic polymers. The low-cost structure compares well to compound semiconductor technologies such as GaAs (Gallium arsenide) and InP (Indium Phosphide), which suffer from small format wafers that do not allow the economies of scale in high volume fabrication plants. The degree of miniaturization possible of the slot modulator using SiP is not technically feasible to accomplish with inorganic crystalline materials. Although this may not always remain the case, presently there are nearly insurmountable technical difficulties that are inherent to a crystalline molecule.

Although we believe that our polymers will be the key differentiating factor in Polymer photonic devices, we do not currently possess the technical skills and instrumentation necessary to fabricate and test PICs at this dramatically reduced scale and intend to seek an external partner to assist with development.  

Our Intellectual Property

Our research and development efforts over the last 10 years have yielded our Company an extensive patent portfolio as well as critical trade secrets, unpatented technology and proprietary knowledge related to our optical polymer materials. Our intellectual property portfolio has expanded significantly over the last year as we are developing our P²IC™ into prototypes. We filed 12 patents during 2018 and 2019 and are currently in the process of readying a number of other inventions for formal filings in 2020 and 2021. We expect to continue innovating with our P²IC platform during 2020, and expect to at least maintain this level of invention at our Company during the whole of 2019. For 2018 our focus was to establish the world’s first unique Perkinamine^™ polymer based integrated photonics circuit portfolio of patents to support our working prototypes.]

Also in 2018, we acquired the Polymer Technology Intellectual Property Assets of BrPhotonics Productos Optoelectrónicos S.A., a Brazilian corporation, which significantly advanced our patent portfolio of electro-optic polymer technology with 15 polymer chemistry materials, devices, packaging and subsystems patents and further strengthened our design capabilities to solidify our market position as we prepare to enter the 400Gbps integrated photonics marketplace with a highly competitive, scalable alternative to installed legacy systems.

In addition to the 12 patents we filed during 2018 and 2019, we expect to file new patents in 2020 and 2021. In total, our patent portfolio consists of 49 granted patents that include 39 from the US, 1 from Canada, 5 from the EU, 2 from Japan and 2 from China.

Our materials patent portfolio has also strengthened significantly in 2017 with the filing of additional new patent applications on our core Perkinamine^™ molecular compounds as well as recent, innovative inventions that are expected to protect our P²IC polymer PIC platform from potential competition.

Included in our patent portfolio are the following nonlinear optic chromophore designs:

Our strategic plan is to utilize our core proprietary technology and leverage our proprietary optical materials to be the core of and the enabling technology for future generations of optical devices, modules, sub-systems and systems that we will develop or potentially out-license to electro-optic device manufacturers. Our Company contemplates future applications that may address the needs of semiconductor companies, aerospace companies and government agencies.

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We rely on a combination of patents, patent applications, trademarks, trade secrets and contractual provisions to protect our technologies. Further, employees are required to surrender any inventions or intellectual property developed as part of their employment agreements. We also have a policy of requiring prospective business partners to enter into non-disclosure agreements (NDAs) before disclosure of any of our confidential or proprietary information. Our Company can make no assurances that we will be able to effectively protect our technologies and know-how or that third parties will not be able to develop similar technologies and know-how independently.

The anti-aromatic nature of these structures dramatically improves the "zwitterionic-aromatic push-pull" of the systems, providing for low energy charge transfer. Low energy charge transfer is important for the production of extremely high electro-optic character.

Heterocyclical Steric Hindering System This patent describes a nitrogenous heterocyclical structure for the integration of steric hindering groups that are necessary for the nanoscale material integration. Due to the [pi]-orbital configuration of the nitrogen bridge, this structure has been demonstrated not to interfere with the conductive nature of the electronic conductive pathway and thus is non-disruptive to the electro-optic character of the core molecular construction. The quantum mechanical design of the system is designed to establish complete molecular planarity (flatness) for optimal performance.

Totally Integrated Material Engineering System This patent covers material integration structures under a design strategy known as Totally Integrated Material Engineering. These integration structures provide for the "wrapping" of the core molecule in sterically hindering groups that maximally protect the molecule from environmental threats and maximally protect it from microscopic aggregation (which is a major cause of performance degradation and optical loss) within a minimal molecular volume. These structures also provide for the integration of polymerizable groups for integration of materials into a highly stable cross-linked material matrix.

Recent Significant Events and Milestones Achieved

During February and March 2018, we moved our Newark, Delaware synthetic laboratory and our Longmont, Colorado optical testing laboratory and corporate headquarters to office, laboratory and research and development space located at 369 Inverness Parkway, Suite 350, Englewood, Colorado. The 13,420 square feet Englewood facility includes fully functional 1,000 square feet of class 1,000 cleanroom, 500 square feet of class 10,000 cleanroom, chemistry laboratories, and analytic laboratories. The Englewood facility streamlines all of our Company’s research and development workflow for greater operational efficiencies. 

During March 2018, our Company, together with our packaging partner, successfully demonstrated packaged polymer modulators designed for 50Gbps, which we believe will allow us to scale our P²IC™ platform with our Mach-Zehnder ridge waveguide modulator design as well as other photonics devices competitively in the 100Gbps and 400Gbps datacom and telecommunications applications market. We are currently fine-tuning the performance parameters of these prototypes in preparation for customer evaluations.

During June 2018, our Company Acquired the Polymer Technology Intellectual Property Assets of BrPhotonics Productos Optoelectrónicos S.A., a Brazilian corporation, which significantly advanced our patent portfolio of electro-optic polymer technology with 15 polymer chemistry materials, devices, packaging and subsystems patent and further strengthened our design capabilities to solidify our market position as we prepare to enter the 400Gbps integrated photonics marketplace with a highly competitive, scalable alternative to installed legacy systems. We have now fully integrated the acquired technology into our P²IC (polymer photonic integrated circuit) platform.

Also, during June 2018, our Company promoted polymer PICs and Solidified Polymer PICs as Part of the Photonics Roadmap at the World Technology Mapping Forum in Enschede, Netherlands, which includes our Company’s technology of polymers and polymer PICs that have the potential to drive not only 400Gbps aggregate data rate solutions, but also 800Gbps and beyond.

In August 2018 we announced the completion (ahead of schedule) of our fully equipped on-site fabrication facility, where we are expanding our high-speed test and design capabilities. We also announced the continuation of the building of our internal expertise with the hiring of world-class technical personnel with 100Gbps experience.

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In February 2019 we announced a major breakthrough in our development of clean technology polymer materials that target the insatiable demand for fast and efficient data communications in the multi-billion-dollar telecom and data markets supporting Internet, 5G and IoT (Internet of Things) webscale services. The improved thermally stable polymer has more than double the electro-optic response of our previous materials, enabling optical device performance of well over 100 GHz with extremely low power requirements. This addition to the family of Perkinamine^TM polymers will hold back run-away consumption of resources and energy needed to support ever-growing data consumption demands. We continue to conduct testing of the material and assessment of associated manufacturing processes and device structures prior to release to full development.

In March 2019 we created an Advisory Board comprised of three world-class leaders in the photonics industry: Dr. Craig Ciesla, Dr. Christoph S. Harder, and Mr. Andreas Umbach. The Advisory Board will work closely with our Company leadership to enhance our Company’s product positioning and promote our polymer modulator made on our proprietary Faster by Design™ polymer P²IC™ platform. The mission of the Advisory Board will initially be to increase our Company’s outreach into the datacenter interconnect market and later to support expansion into other billion-dollar markets. The Advisory Board members have each been chosen for their combination of deep technical expertise, breadth of experience and industry relationships in the fields of fiber optics communications, polymer and semiconductor materials. Each of the Advisory Board members has experience at both innovators like Lightwave Logic and large industry leaders of the type most likely to adopt game-changing polymer-based products. In addition, they possess operational experience with semiconductor and polymer businesses.

Also, in March 2019, our Company received the “Best Achievement in PIC Platform” award for our 100 GHz polymer platform from the PIC International Conference. The award recognizes innovative advances in the development and application of key materials systems driving today's photonic integrated circuits (PICs) and providing a steppingstone to future devices.

During the second quarter of 2019, our Company promoted its polymers at CoInnovate in May and the World Technology Mapping Forum in June. CoInnovate is a meeting of semiconductor industry experts. The World Technology Mapping Forum is a group authoring a photonics roadmap out to 2030.

In September 2019 at the prestigious European Conference on Communications (ECOC) in Dublin, Ireland,  we showed measured material response over frequency and the resulting optical data bits stream on our clean technology polymer materials, the newest addition to our family of Perkinamine^TM polymers, that meet and exceed of our near-term target speed of 80 GHz  We also released data data demonstrating stability under elevated temperatures in the activated (poled to create data carrying capability) state.

In October 2019, we reported that energy-saving polymer technology is highlighted in the recently published Integrated Photonics Systems Roadmap - International (IPSR-I).  The roadmap validates the need for low-voltage, high-speed technologies such as ours.

As we move forward to diligently meet our goals, we continue to work closely with our packaging partner for the 50Gbaud and 100 Gbaud prototypes, and we are advancing our reliability and characterization efforts to support our prototyping. We are actively engaged with test equipment manufacturers of the most advanced test equipment to test our state-of-the-art polymer devices. We continue to engage with multiple industry bodies to promote our roadmap. We continue to fine tune our business model with target markets, customers, and technical specifications. Discussions with prospective customers are validating that our modulators are ideally suited for the datacenter and telecommunications markets that are over 10km in length. Details of what these prospective customers are seeking from a prototype are delivered to our technical team.

The Global Photonic Device Market

General Overview

Lightwave Logic has been reviewing the latest market data as well as its own internal data for its business strategy, and below we detail the global market dynamics both in terms of data traffic as well as how PIC based technologies will grow in the fiber communications segment of the market.

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As we have already seen with products such as smart phones, lap top computers, and personal digital assistants (PDAs), Internet traffic is one of the important metrics that is being used to show activity in fiber communications, and particularly telecommunications as well as data communications (which includes datacenters and high-performance computing). Internet Protocol (IP) traffic has typically been used to gauge the amount of data that is being used on the internet as shown in the graph below (sourced from Cisco VNI in 2018). The metric is Exabytes per month. An Exabyte is 1E18 which is 1000 Petabytes, or 1000,000 Terabytes or a billion Gigabytes of data. As seen from the graph which has a strong growth of 22% CAGR (2015-2020), the majority of the traffic is being driven by video, traffic, and is fast approaching the metric of Zetta which is 1E21 bytes of data. Some estimates are discussing the further metric of Yotta which is 1E24 bytes of data over the next decade, which is also expected to be driven for the most part by video.

Within the overall market trends of IP traffic growth, the internet will need to be able to support high volumes of data traffic. In order to do this, the fiber-optic infrastructure that allows data to be communicated between network nodes such as datacenters, within datacenters, and optical network switches etc., has to be upgraded. Today, fiber-optic networks are a combination of long, medium and short optical interconnects that range from 3 meters (or 1yard) to over 1000km depending on application in the optical network. Optical components, typically known as photonics components are used to build the fiber-optic infrastructure and consist of things like: laser diode, photodetectors, multipliers, modulators, transceivers etc. These are known as discrete components, while a mix of these components that are integrated or connected on a single substrate (such as silicon, InP, GaAs etc.) are called PICs (Photonic Integrated Components). The summary photonics market has been reviewed in 2018 and is shown below. The summary photonics market is forecast to grow to $43B by 2025 with a 7% CAGR (20-25) that includes both discrete and PIC photonic components. The summary photonics components market is forecasted to reach $23B in 2018.  

Within the summary photonics components market, three major segments exist: WAN (wide area networks), access, and Datacom. The WAN segment is forecast to grow to $27B by 2025 with a 19% CARG (20-25) and the Datacom segment is forecast to grow to $12.1B by 2025 with 22% CAGR (20-25). As can be seen from the graph below, the growth of the WAN and Datacom segments is forecasted to be very strong over the next decade and provide the engine for growth in the overall global photonics components market.

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One of the key metrics that is needed for any overall market analysis is how photonics components will grow over the next decade from a PIC perspective. This is important as the trend to integrate photonics components is beginning to accelerate. The trend has been driven by customer applications that require smaller photonic component solutions, lower power, high data rates, larger buildings for longer interconnect lengths, and more economic in terms of $/Gbps. PIC technologies, i.e. those technologies that include integrated photonics are forecasted to grow to ~$30B by 2025 with 16% CAGR (20-25). These technologies include InP which is the current incumbent, GaAs, and other newer integrated technology solutions such as SiP (silicon photonics), polymer photonics, and dielectric photonics. The forecast of ~$30B is approximately 69% of the summary photonics components market by 2025, which represents a huge acceleration for PIC based technologies over the next decade. This also means while PIC based technologies are $7B today with 24% of the photonics components market, PIC based technologies become de facto by 2025.

While the rise of PIC based technologies is exciting, what also is exciting in the photonics component market is the rise of fiber-optic transceivers. Transceivers are small boxes located at the end of each fiber-optic link that house photonics components and PIC components which send and receive data. While the global overall photonic components market is expected to reach $43B by 2025, the photonics transceivers sub-segment is forecasted to grow to $25B by this time. This represents that transceivers will accelerate to 58% of the global overall photonics market by 2025 and become a major driver for optical networking over the next decade.

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The key segments in photonics based fiber-optic transceivers achieved $12B in 2018 with growth from 9 different segments that include: AOC, CATV, Fibre Channel, DWDM, Ethernet-datacom, WAN-client side, Radio etc., based transceivers. Three of these segments are forecasted to grow very well to achieve revenues of $25B by 2025, with the biggest contributions from DWDM, Ethernet-datacom, and WAN-client based transceivers.

The transceiver growth shows which sub-segments that will utilize small boxes at the ends of fiber-optic interconnects, it is well known that transceiver trends over the past decade have been towards smaller boxes i.e. smaller transceiver formats and footprints (such as SFF, SFP, QSFP, and many others), with higher densities of photonics components designed into them. It is expected over the forecast period that transceivers will be an excellent platform for the accelerating trends of PICs in both telecom and datacom applications. The graph below shows the PIC transceiver forecast to 2025. PIC transceivers are forecast to reach $20B by 2025 with 17% CARG (20-25) growing from ~$4B in 2018. What is more interesting is that by about 2021, PIC transceivers will lead discrete photonic component transceivers from a revenue standpoint. This means that the trend to integrate photonics components inside a transceiver is accelerating quickly, driven by the customer interest for smaller, denser, and higher performance metrics of transceivers. This trend is ideal for our polymer based integrated photonics platform to have a huge impact in the market segment over the next decade.

Within the PIC transceivers market there are a number of sub-segments that summate to $20B by 2025. The major segments that drive this forecast are Ethernet, DWDM, and WAN-client-side applications as can be seen from the graph below. In particular these segments are technologically driven by PIC based technologies that operate at 100Gbps and 400Gbps data rates that generally are considered high performance solutions.

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Data rates and high performance of transceivers can be seen by the graph below which depicts PIC based technologies in the Ethernet sub-segment. For Ethernet applications only, transceivers are driven by 100GE based PIC technologies. The market is forecast with 100GE to grow to $4.5B by 2025 with 6% CAGR (20-25) and with 400GE to grow to $0.98B by 2025 with 16% CAGR (20-25). This is a clear drive for the PIC based transceivers in the Ethernet application is 100GE over the forecast period and sets the scene for polymer based integrated photonics to have the opportunity to grow extremely quickly.

As the Company is developing polymer based photonic devices such as fiber-optic modulators, these devices translate electric signals into optical signals and allow laser based technology to operate effectively at 50Gbps and beyond. Lasers with modulator are used in fiber communication systems to transfer data over fiber-optic networks today and are expected to be a key driver in photonics components for PIC based technological solutions over the next decade. Optical data transfer using lasers and modulators is significantly faster and more efficient than transfer technologies using only electric signals, permitting more cost-effective use of bandwidth for broadband Internet and voice services.

Our Target Markets

Cloud computing and data centers

Big data is a general term used to describe the voluminous amount of unstructured and semi-structured data a Company creates -- data that would take too much time and cost too much money to load into a relational database for analysis. Companies are looking to cloud computing in their data centers to access all the data. Inherent speed and bandwidth limits of traditional solutions and the potential of organic polymer devices offer an opportunity to increase the bandwidth, reduce costs and improve speed of access.

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Datacenters have grown to enormous sizes with hundreds of thousands and even millions of servers in a single datacenter. The number of so-called “hyperscale” datacenters are expected to continue to increase in number. Due to their size, a single “datacenter” may consist of multiple large warehouse-size buildings on a campus or even several locations distributed around a metropolitan area. Data centers are confronted with the problem of moving vast amounts of data not only around a single data center building, but also between buildings in distributed data center architecture. Links within a single datacenter building may be shorter than 500 meters, though some will require optics capable of 2 km. Between datacenter buildings, there is an increasing need for high performance interconnects over 10km in reach.

Our modulators are suitable for single-mode fiber optic links. We believe that our single mode modulator solutions will be competitive at 500m to 10km link distances, but it will be ideally suited at greater than 10km link distances.

Telecommunications/Data Communications

The telecommunications industry has evolved from transporting traditional analogue voice data over copper wire into the movement of digital voice and data. Telecommunication companies are faced with the enormous increasing challenges to keep up with the resulting tremendous explosion in demand for bandwidth. The metropolitan network is especially under stress now and into the near future. Telecommunications companies provide services to some data center customers for the inter-data center connections discussed above. 5G mobile upgrade, autonomous driving and IoT are expected to increase the need for data stored and processed close to the end user in edge data centers. This application similarly requires optics capable of very high speeds and greater than 10 km reach.

Industry issues of scaling

The key issues facing the fiber-optic communications industry are the economic progress and scalability of any PIC based technological platform. The polymer platform is unique in that it is truly scalable. Scalable means being able to scale up for high speed data rates, while simultaneously being able to scale down in cost. This allows a competitive cost per data rate or cost per Gbps metric to be achieved.

Fiber optic datacenter and high-performance computing customers want to achieve the metric of $1/Gbps @ 400Gbps (this essentially means a single mode fiber optic link that has a total cost of $400 and operates with a data rate of 400Gbps à which also means that each transceiver at each end of the fiber optic link must be able to be priced at $200), but as industry tries to match this target, it is already falling behind as can be seen in the Figure below which plots generic typical PIC based technology:

In the above figures (where the left-hand graph is a linear vertical scale, and the right-hand graph is a log scale), it can be seen that the orange curve plots the customer expectation, while the other color curves show $/Gbps improvement over time for various high-speed data rate transceivers using PIC based technologies. A gap is appearing between what customer expect and what the technologists can produce.

Polymers play an important role in PICs over the next decade as they can reduce or close the gap between customer expectations and technical performance through effective scaling increase of high performance with low cost. This is shown in the Figure below how polymers have the potential to scale to the needs of the customers over the next 3-5years.

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Some of the things needed to achieve the scaling performance of polymers in n integrated photonics platform is within sight today:

Business Strategy

Our business strategy anticipates that our revenue stream will be derived from one or some combination of the following: (i) technology licensing for specific product application; (ii) joint venture relationships with significant industry leaders; or (iii) the production and direct sale of our own electro-optic device components. Our objective is to be a leading provider of proprietary technology and know-how in the electro-optic device market. In order to meet this objective, we intend to:

Create Organic Polymer-Enabled Electro-Optic Modulators

We intend to utilize our proprietary optical polymer technology to create an initial portfolio of commercial electro-optic polymer product devices with applications for various markets, including telecommunications, data communications and data centers. These product devices will be part of our proprietary photonics integrated circuit (PIC) technology platform.

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We expect our initial modulator products will operate at data rates at least 50 Gbaud (capable of 50 Gbps with standard data encoding of NRZ and 100 Gbps with more complex PAM-4 encoding). Our devices are highly linear, enabling the performance required to take advantage of the more advance complex encoding schemes. We are currently developing our polymer technology to operate at the next industry node of 100Gbaud.

Continue to Expand Our Intellectual Property Portfolio and Reliance on Trade Secrets

We plan to continuously advance the development of unique organic electro-optic polymer materials along with proprietary designs and device configurations. We intend to protect our technology by filing patent applications where appropriate or by obtaining exclusive technology rights where available. However, in some cases, we will refrain from protecting certain proprietary information with patents in favor of trade secrets.

Continue to Recruit Technical Expertise

In December 2011, we retained Dr. Frederick Leonberger, PhD as our Senior Advisor. Dr. Leonberger is the former Chief Technology Officer of JDS Uniphase, Inc. We previously retained EOvation Advisors LLC, a technology and business advisory firm founded by Dr. Frederick Leonberger, as a consultant to the Company. Dr. Leonberger is presently assisting our Company with strategic planning and the design of optical modulators that we intend to develop. In May 2017, Dr. Leonberger was elected to our Board of Directors and serves as a member of the operations committee and assists with the technical direction and strategy of the Company.

In July 2018 we retained Dr. Karen Liu, a former industry analyst and marketing executive in datacom and telecom fiber optic communications, as our Vice President of Sales and Marketing to advance our customer-facing position in the datacom and telecom markets and to assist with engaging with customers on our 400Gbps and 800Gbps prototypes.

Our Research and Development Process

Our research and development process consist of the following steps:

We have and expect to continue to make significant operating and capital expenditures for research and development. Our research and development expenses were $3,355,887 and $2,830,785 for the nine months ended September 30, 2019 and 2018, respectively, and $3,794,565 and $3,519,129 for the years ended December 31, 2018 and 2017, respectively.

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Our Proprietary Products in Development

As part of a two-pronged marketing strategy, our Company is developing several optical devices, which are in various stages of development and that utilize our organic nonlinear optical materials. They include:

Ridge Waveguide Modulator

Our ridge electro-optic waveguide modulator was designed and fabricated in our in-house laboratory. The fabrication of our first in-house device is significant to our entire device program and is an important starting point for modulators that are being developed for target markets. We have multiple generations of new materials that we will soon be optimizing for this specific design. In September 2017 we announced that our initial alpha prototype ridge waveguide modulator, enabled by our P²IC™ polymer system, demonstrated bandwidth performance levels that will enable 50 Gbaud modulation in fiber-optic communications. This device demonstrated true amplitude (intensity) modulation in a Mach-Zehnder modulator structure incorporating our polymer waveguides. This important achievement will allow users to utilize arrays of 4 x 50 Gbaud (4x 100 Gbps) polymer modulators using PAM-4 encoding to access 400 Gbps data rate systems. These ridge waveguide modulators are currently being packaged with our partner into prototype packages. We showed an example packaged modulator at our Annual Shareholders Meeting in May 2018.

These prototype packages will enable potential customers to evaluate the performance at 50 Gbaud. Once a potential customer generates technical feedback on our prototype, we expect to be asked to optimize the performance to their specifications. Assuming this is successful, we expect to enter a qualification phase where our prototypes will be evaluated more fully.

In parallel, we are developing modulators for scalability to higher data rates above 50 Gbaud. In September 2018, we showed in conference presentations the potential of our polymer modulator platform to operate at over 100 GHz bandwidth. This preliminary result corresponds to 100 Gbaud data rates using a simple NRZ data encoding scheme or 200 Gbps with PAM-4 encoding. With 4 channel arrays in our P²IC™ platform, the Company thus has the potential to address both 400 Gbps and 800 Gbps markets. While customers may start the engagement at 50 Gbaud, we believe potential customers recognize that scalability to higher speeds is an important differentiator of the polymer technology.

We believe the ridge waveguide modulator represents our first commercially viable device and targets the fiber optics communications market. We have completed internal market analysis and are initially targeting interconnect reach distances of greater than 10km. In these markets, the system network companies are looking to implement modulator-based transceivers that can handle aggregated data rates 100 Gbps and above. The market opportunity for greater than 10km is worth over $1B over the next decade.

Advanced Modulator Structures

As part of supporting further improvement and scalability of our platform, we continue to explore more advanced device structures. Our functional polymer photonics slot waveguide modulator utilizes an existing modulator structure with one of our proprietary electro-optic polymer material systems as the enabling material layer and is functional as an operating prototype device.

Preliminary testing and initial data on our polymer photonics slot waveguide modulators demonstrated several promising characteristics. The tested polymer photonic chip had a 1-millimeter square footprint, enabling the possibility of sophisticated integrated optical circuits on a single silicon substrate. In addition, the waveguide structure was approximately 1/20 the length of a typical inorganic-based silicon photonics modulator waveguide.

With the combination of our proprietary electro-optic polymer material and the extremely high optical field concentration in the slot waveguide modulator, the test modulators demonstrated less than 2.2 volts to operate. Initial speeds exceeded 30-35 GHz in the telecom, 1550 nanometer frequency band. This is equivalent to 4 x 10Gbps, inorganic, lithium niobate modulators that would require approximately 12-16 volts to move the same amount of information.

We continued with our collaborative development of our polymer photonic slot waveguide modulator in 2014 and continued our collaboration with an associated third-party research group in 2017 and 2018. We are now designing slot modulators to operate at data rates greater than 50 Gbaud.

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Our Long-Term Device Development Goal - Multichannel Polymer Photonic Integrated Circuit (P²IC™)

Our P²IC™ platform is positioned to address markets with aggregated data rates of 100 Gbaud, 400 Gbaud, 800 Gbaud and beyond. Our P²IC™ platform will contain a number of photonic devices that may include, over and above polymer-based modulators, photonic devices such as lasers, multiplexers, demultiplexers, detectors, fiber couplers.

While our polymer-based ridge waveguide and slot modulators are currently under development to be commercially viable products, our long-term device development goal is to produce a platform for the 400 Gbps and beyond transceiver market. This has been stated in our photonics product roadmap that is publicly available on our website. The roadmap shows a progression in speed from 50 Gbaud based ridge waveguide modulators to 100 Gbaud based ridge waveguide modulators. The roadmap shows a progression in integration in which the modulators are arrayed to create a flexible, multichannel P²IC™ platform that spans 100 Gbps, 400 Gbps, 800 Gbps, and potentially 1.6 Tbps aggregated data-rate markets.

We showed bandwidths of polymer-based modulator devices at a major international conference (ECOC – European Conference on Optical Communications 2018) with bandwidths that exceeded 100GHz. We noted that to achieve 100Gbaud, the polymer-based modulator only needs to achieve 80GHz bandwidth. During ECOC 2019, we showed environmental stability. We continue to develop our polymer materials and device designs to optimize additional metrics. We are now optimizing the device parameters for very low voltage operation.

Other Potential Applications for Our Products

We believe that there are myriad potential applications for our organic polymer materials and devices outside of our initial focus of data communications, telecommunications and data centers. These potential applications encompass areas as diverse as military, space, optical computing, and life sciences. We believe that as viable organic polymer materials gain acceptance, their increased flexibility, functionality and low cost will create new applications that may not yet be technically feasible. Two such future applications with revolutionary potential are:

All-Optical Switches

An all-optical switch is one that enables signals in optical fibers or networks to be selectively switched from one fiber or circuit to another. Many device designs have been developed and commercialized in today’s telecom networks to effect optical switching by using mechanical or electrical control elements to accomplish the switching event. Future networks will require all-optical switches that can be more rapidly activated with a low energy and short duration optical (light) control pulse.

Multi-Channel Optical Modem

The availability of low cost electro-optic modulators will enable low cost multichannel optical modems that will use many wavelengths in parallel and employ high efficiency modulation techniques such as QAM (quadrature amplitude modulation). Such modems would enable an order of magnitude increase in the Internet capacity of legacy fiber. Our Company is in the early feasibility stage of such a multichannel optical modem.

Our Past Government Program Participation

Our Company has been a participant in several vital government sponsored research and development programs with various government agencies that protect the interests of our country. The following is a list of some of the various divisions of government agencies that have provided us with advisory, financial and/or materials support in the pursuit of high-speed electro-optic materials. We are not currently partnered with, strategically related to, or financially supported by any governmental agency at this time, however, we may explore future opportunities as our Company grows and gains the additional resources and personnel necessary to support these efforts. Our previous relationships included:

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Our Competition

Competitive Technologies - PIC Based Technologies

PIC technologies have historically been driven using III-V compound semiconductors, namely InP, although GaAs remains a strong PIC platform, and is expected to strengthen via the VCSEL based 3D sensing applications. Indium Phosphide has been used since the 1980s as the first PIC platform with laser modulator chips where both the laser and modulator were fabricated monolithically. Since the 1980s, there have been InP based transmitters, receivers, and other functional elements that all support the fiber-communications industry. In fact, over the past 3 decades, the fiber communications industry has driven the increased performance, miniaturization and simplicity in packaging for PIC based technologies. Also, back in the 1980s, ‘optoelectronics’ was the key word to describe having both electronic and photonic functions or devices on a single chip. This was known in early publications as an optoelectronics integrated circuit (OEIC). Today optoelectronics is synonymous with ‘photonics’, and hence the common-place use of ‘photonics integrated circuits’ for PICs.

In the below figure, it can be seen in red that the incumbent technology for PICs is InP. InP is capable of providing a number of devices and opportunities in both electronics as well as photonics. InP main weakness from a function standpoint is that although it can provide HFETs, JFETs, bipolar electronic devices, it has not been able to successfully penetrate LSI, or VLSI with digital IC circuitry. Chips such as ASICs are not practically available with the InP platform – mostly due to advancement in electronic transistor design, and also through limited maturity in large format wafer manufacturing. Today the majority of InP fabrication is based on 4” or 100mm wafers, and only in the past year have folks been seriously looking at 6” or 150mm InP wafer infrastructure. From the photonics standpoint, there are very good reasons why InP is the incumbent technology – it provides world class performance in lasers, modulators, simple electronics such as drivers and TIAs (transimpedance amplifiers), as well as highly performing active and passive devices such as SOAs, waveguides, spot-size converters, and mux/demux blocks such as AWG and Eschelle gratings.

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Over the past decade, the rise of silicon-based photonics has accelerated quickly (as can be seen in blue in the Figure). Silicon has a huge history in electronics, and it’s been said by many that if the existing infrastructure could be utilized effectively, then the cost of producing photonics with similar fabrication, design, testing, and simulation tools, would become competitive with the current incumbent technology: InP. As can be seen by the figure, silicon is capable of handling many photonics devices in addition to all electronic functionality with CMOS and BiCMOS based technologies. The only photonic device that remains impossible (at least for the time being) is the emitter or laser where light is generated. This has spawned a new segment for silicon photonics (SiP) where engineers and scientists have developed creative ways to implement InP into device, wafer, and epi-designs that are silicon based. These solutions are typically referred to as heterogeneous solutions where both InP and silicon are utilized to create PIC platforms with emitter or laser-based functionality.

While the red area of the Figure represents the incumbent technology InP, the blue areas, Silicon Photonics, the middle areas that are shaded green represent PIC based technologies that can utilize either III-V compound semiconductor platforms such as InP, GaAs, even GaN, as well as silicon platforms such as silicon wafers, and various combinations of silicon-based materials such as SOI (silicon on insulator), SiGe etc. The green areas are represented by both polymers and dielectric materials that can be deposited onto either silicon or III-V material wafers. These combinations of technology allow flexibility in PIC designs where both polymers and dielectrics can provide a multitude of active and passive photonic devices such as: waveguides (W/G), spot size converters (SSC), modulators (such as Mach Zehnder and slot types), multipliers and demultipliers (Mux/Demux variants such as AWGs, MMI, and Echelle gratings). The interesting part of the polymer and dielectric technology is that combinations of active and passive devices can be mixed and matched with either III-V compound devices as well as silicon based, heterogeneous based devices to design more effective and efficient PICs. For polymers, very low voltage can be utilized for low cost, low power consumption, very high-speed modulators that can be deposited onto a semiconductor platform. For dielectric photonics, very low temperature sensitivity mux/demux devices (such as athermal designs) can be deposited onto a semiconductor platform. As can be seen from the Figure, polymer and dielectric technology suffers from that the fact that high density ICs and laser-based emitters are not available but could be integrated with the appropriate designs for the PIC with III-V compound semiconductors and/or silicon based technology that have both DSP/ASIC type circuits and laser emitters.

PIC technologies have a number various and broad applications as can be seen by the Figure below. In this Figure applications range from fiber optic communications, self-driving vehicles, sensing, internet of things, bio-photonics, healthcare, industrial, military, high performance computing etc.

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PIC technologies are based upon semiconductor wafers (such as III-V compound semiconductors – InP, GaAs etc.) as well as silicon wafers (which can be tailored to become SiGe heterogeneous, SOI, etc.). As these platforms are semiconductor based, the wafers are processed in fabs or fabrication facilities to produce devices. As a general rule, silicon has the largest wafers with 8” (200mm) and 12” (300mm) format discs. GaAs typically is running 3” (75mm), 4” (100mm) and 6” (150mm) wafers in production fabs or fabrication plants around the world. There is an expectation that GaAs will eventually move to 8” (200mm) wafers in the next 5 years. InP is in production today on 2” (50mm), 3” (75mm) and 4” (100mm) wafers with an expectation to move to 6” (150mm) in the next 5 years. Heterogeneous solutions with silicon photonics that utilize materials such as SiGe and InP are typically 8” (200mm) and 12” (300mm) format wafers. Polymer photonics can be deposited on either III-V compound semiconductor wafers as well as silicon wafers which makes it suitable for the next generation of PIC based technological platforms for the fiber communications industry.

The supply chain for the PIC industry starts with the wafer development and continues through epitaxial growth, device fabrication, optical sub-assembly, module or transceiver builds, and sub-systems which are implemented into optical networking applications. Within these supply chain segments, a number of combinations of technology can be utilized. For example, CMOS IC circuits can be fabricated onto silicon wafers together with silicon photonics, heterogeneous solutions,that could have the advantage of polymer active devices, and dielectric passive devices on board. InP may be combined with polymer photonics to house on-board or on-wafer emitters to source light for the optical signaling with modulators. Included in the wafers can be combinations of electrical and optical circuitry. Electrical circuitry is usually set up as both as single as well as multilevel interconnects. Optical circuitry is usually set up as a waveguide or optical layer as part of the device fabrication design. PICs can interconnect electrical devices with photonic devices, and also increase chip functionality through the use of electrical and optical active and passive device solutions. Polymer technologies can provide active device function through for example Mach Zehnder modulators, as well as providing passive device function with waveguides, multipliers, and demultipliers.

Competitors

The markets we are targeting for our electro-optic polymer technology are intensely competitive. Among the largest fiber-optic component manufactures are Finisar, Lumentum, Oclaro, NeoPhotonics, Molex, Avago. Additionally, the five largest inorganic modulator component manufacturers hold approximately 85% of the electro-optic modulator component market. They are Lumentum, Sumitomo, Oclaro, Fujitsu and ThorLabs. These companies are heavily invested in the production of crystalline-based electro-optic modulator technologies, as well as the development of novel manufacturing techniques and modulator designs.

Our Plan to Compete

We believe that as our organic polymer technology gains industry acceptance, we will be poised to obtain a significant portion of the component manufacturing market. Electro-optic polymers demonstrate several advantages over other technologies, such as inorganic-based technologies, due to their reduced manufacturing and processing costs, higher performance and lower power requirements. Our patented organic polymers and future electro-optic photonic devices have demonstrated significant stability advantages over our known competitor's materials.

We believe the principal competitive factors in our target markets are:

We believe that our current business planning will position our Company to compete adequately with respect to these factors. Our future success is difficult to predict because we are an early stage company with all of our potential products still in development.

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Many of our existing and potential competitors have substantially greater research and product development capabilities and financial, scientific, marketing and human resources than we do. As a result, these competitors may:

Employees

We currently have 19 full-time employees, and we retain several independent contractors on an as-needed basis. Based on our current development plan we expect to add 2 to 4 additional full-time employees in 2020. We believe that we have good relations with our employees.

Properties and Laboratory Facilities

Our principal executive offices and research and development facility is located at our new office, laboratory and research and development space located at 369 Inverness Parkway, Suite 350, Englewood, Colorado. The new 13,420 square feet Englewood facility includes fully functional 1,000 square feet of class 1,000 cleanroom, 500 square feet of class 10,000 cleanroom, 220 square feet of class 100 cleanroom, chemistry laboratories, and analytic laboratories. The new Englewood facility streamlines all of our Company’s research and development workflow for greater operational efficiencies.

Legal Proceedings

We are not currently a party to or engaged in any material legal proceedings and we are not aware of any litigation or threatened litigation of a material nature. However, we may be subject to various claims and legal actions arising in the ordinary course of business from time to time.

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MANAGEMENT

Identity of directors, executive officers and significant employees

Business experience of directors, executive officers, and significant employees

Dr. Michael Lebby. Dr. Lebby has served as our Chief Executive Officer since May 1, 2017 and as a director of our Company since August 26, 2015. He also previously served a member of our Operations Committee until April 30, 2017.  Dr. Lebby is in charge of the overall general management of the Company and supervision of Company policies, setting the Company’s strategies, formulating and overseeing the Company’s business plan, raising capital, expanding the Company’s management team and the general promotion of the Company From June 2013 to 2015, Dr. Lebby has served as President and CEO of OneChip Photonics, Inc., a privately held company headquartered in Ottawa, Canada, that is a leading provider of low-cost, small-footprint, high-performance indium phosphide (InP)-based photonic integrated circuits (PICs) and PIC-based optical sub-assemblies (OSAs) for the Data Center markets. Also, from 2013 to 2015 Dr. Lebby presently served as part-time full professor, and chair of optoelectronics at Glyndwr University in Wales, UK, to bring forward advanced materials, device, and integrated photonics based technologies for the datacenter and high performance computing markets.  During the period 2014 to 2016, Dr. Lebby focused on a foundry based model for InP-based photonic integrated circuits (PICs) and optoelectronic integrated circuits (OEICs) in the datacenter segment and was been instrumental in assembling California’s proposal (via USC) to the Federal Government for an integrated photonics manufacturing institute. Dr. Lebby holds a Doctor of Engineering, a Ph.D., a MBA and a bachelor’s degree, all from the University of Bradford, United Kingdom.  Dr. Lebby has well over 200 issued utility patents with the USPTO. This number expands to over 450 if international derivative patents are included.

Mr. James S. Marcelli. Mr. Marcelli has served as an officer and director of our Company since August 2008. Since May 2012, Mr. Marcelli has served as our Company’s President and Chief Operating Officer, and he was named our Secretary in March 2018. Previously, from August 2008 to April 2012, Mr. Marcelli served as our President and Chief Executive Officer. Mr. Marcelli is in charge of the day-to-day operations of our Company and its movement to a fully functioning commercial corporation, and also serves as our Company’s principal financial officer. Since 2000, Mr. Marcelli has served as the president and chief executive officer of Marcelli Associates, a consulting company that offers senior management consulting, mentoring, and business development services to start-up and growth companies. Business segments Mr. Marcelli has worked with included an Internet networking gaming center, high-speed custom gaming computers, high tech manufacturing businesses and business service companies.

Thomas E. Zelibor, Rear Admiral, USN (Ret). RADM Zelibor has served as our Chair of the Board of Directors (non-executive) since May 1, 2017. Previously, has served as our Chief Executive Officer and Chair of the Board of Directors (executive) from May 2012 to April 30, 2017. Mr. Zelibor also previously served as Chair of the Board of Directors (non-executive) of our Company since October 2011 and has served as a director of our Company since July 2008. He also previously served on our Operation Committee. Mr. Zelibor is currently the Chief Executive Officer of the Space Foundation and a director of Nuvectra Corp. Mr. Zelibor previously served as the Chief Executive Officer and President of Zelibor & Associates, LLC, a management-consulting firm and as the Chief Executive Officer and President of Flatirons Solutions Corp. Prior to that time, Mr. Zelibor served in the U.S. Navy in a number of positions, including as the Dean of the College of Operational and Strategic Leadership at the United States Naval War College where he was responsible for the adoption of a corporate approach to leadership development; Director of Global Operations, United States Strategic Command; Director, Space, Information Warfare, Command and Control on the Navy staff; Department of the Navy, Deputy Chief Information Officer (CIO), Navy; Commander, Carrier Group Three and Commander, Naval Space Command. Mr. Zelibor earned his bachelor’s degree from the United States Naval Academy and has been a participant in the Senior Leader in Residence Program and a visiting scholar for the Zell Center for Risk Research at the Kellogg School of Management, Northwestern University.

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Dr. Joseph A. Miller, Jr. Dr. Miller has served as a director of our Company since May 10, 2011. From 2002 to May 2012, Dr. Miller served as Executive Vice President and Chief Technology Officer of Corning Incorporated, having joined Corning Incorporated in 2001 as Senior Vice President and Chief Technology Officer. Prior to joining Corning Incorporated, Dr. Miller was with E.I. DuPont de Nemours, Inc., where he served as Chief Technology Officer and Senior Vice President for Research and Development since 1994. Dr. Miller began his career with DuPont in 1966. Dr. Miller previously served as a director and Non-executive Chairman of Nuvectra Corp., and as a director for Greatbatch, Inc. He holds a doctorate degree in Chemistry from Penn State University.

Mr. Ronald A. Bucchi. Mr. Ronald A. Bucchi has served as a director of our Company since June 11, 2012, and he currently serves as the Chair of our Audit Committee. Mr. Bucchi is currently a self-employed C.P.A., CGMA with a specialized practice that concentrates in CEO consulting, strategic planning, mergers, acquisitions, business sales and tax. He works with domestic and international companies. Mr. Bucchi is a former member of the board of directors of First Connecticut Bancorp, Inc., having served as Lead Director, Chair of the Audit Committee, Governance Chairman and a member of the Asset Liability Committee and Loan Committee. The Bank sold in September of 2018. He is currently a member of the Advisory Board of Baker Street Scientific, Inc., the Treasurer and a member of the Board of Directors of the Petit Family Foundation, Inc. and the Farmington Bank Foundation, Inc. He has served on numerous other community boards and is past Chairman of the Wheeler Clinic and the Wheeler YMCA. He is a member of the Connecticut Society of Certified Public Accountants, American Institute of Certified Public Accountants, Chartered Global Management Accountant and the National Association of Corporate Directors. Mr. Bucchi is a graduate of the Harvard Business School Executive Education program with completed course studies in general board governance, audit and compensation and a graduate of Central Connecticut State University where he received his B.S. in Accounting.

Mr. Siraj Nour El-Ahmadi. Mr. El-Ahmadi has served as a director of our Company since October 2, 2013, and he currently serves a member of our Audit Committee. Since 2004, Mr. El-Ahmadi has served as Founder, President and Chief Executive Officer of Menara Networks, a developer of innovative products and solutions that simplify layered optical transport networks. Mr. El-Ahmadi has over 17 years of experience in optical transmission in particular and the telecom industry in general. Prior to founding Menara, Mr. El-Ahmadi served as Vice President-Marketing & Product Management at Nortel where he was responsible for the OPTera LH 4000 ULR product (acquired from Qtera) that achieved over $200M in revenues in its first two years. Prior to that, Mr. El-Ahmadi was the Product Architect & Vice President of Product Management at Qtera Corporation, a successful technology start-up acquired by Nortel in 2000 for $3.25 billion. Mr. El-Ahmadi also held a Senior Manager position at Bell Northern Research and worked as a Transmission Engineer at WilTel (WorldCom) where he evaluated and deployed the world first bidirectional EDFA and bi-directional WDM transmission. Mr. El-Ahmadi holds a BS and MS in Electrical Engineering from the University of Oklahoma, is a member of Eta Kappa Nu and is the inventor of 11 patents, issued or pending, in the area of optical communications. He has authored a number of publications and is a frequent speaker at telecom and optical networking events and conferences.

Dr. Frederick J. Leonberger. Dr. Leonberger has served as a director of our Company since April 1, 2017. Since 2010, Dr. Leonberger has served as the Principal of EOvation Advisors LLC, a private technology and business advisory firm and presently serves as a board member for various private photonics companies. Dr. Leonberger is a widely known technologist and industry leader in the field of photonics and fiber optics. For nearly 40 years he has been a leading contributor to the development of a variety of important optical devices, company leadership, product and business strategy, and commercialization. The integrated optical modulator technology he and his colleagues pioneered has been used pervasively for over 20 years to encode data at multi-Gb/s rates in long-haul fiber optic networks (the Internet "superhighways"). He previously served as senior vice president and chief technology officer of JDS Uniphase Corporation (JDSU, now Lumentum), a leading optical components company, from 1995 until his retirement in 2003, where he played a lead role in technology strategy, mergers and acquisitions and intellectual property activities. Prior to JDSU, he was co-founder and general manager of United Technologies Photonics (UTP), a high-speed optical modulator company, and held research management positions at United Technologies Research Center (UTRC) and MIT Lincoln Laboratory. He is a member of the National Academy of Engineering and the recipient of several industry awards.

The Board of Directors believes that each of the Directors named above has the necessary qualifications to be a member of the Board of Directors. Each Director has exhibited during his prior service as a director the ability to operate cohesively with the other members of the Board of Directors. Moreover, the Board of Directors believes that each director brings a strong background and skill set to the Board of Directors, giving the Board of Directors as a whole competence and experience in diverse areas, including corporate governance and board service, finance, management and industry experience.

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Our bylaws provide that the number of directors who constitute our Board of Directors is determined by resolution of the Board of Directors, but the total number of directors constituting the entire Board of Directors shall not be less than three or more than nine. Our Board of Directors currently consists of seven directors. Our Board of Directors is divided into three classes, as nearly equal in number as possible, designated: Class I, Class II and Class III, with staggered terms and with each director serving for a term ending on the date of the third annual meeting following the annual meeting at which such director was elected; provided that the term of each director shall continue until the election and qualification of a successor and be subject to such director's earlier death, resignation or removal.

Director Independence

Although we are currently traded on the OTCQB Market, our Board of Directors has reviewed each of the Directors’ relationships with the Company in conjunction with NASDAQ Listing Rule 5605(a)(2) that provides that an “independent director” is ‘a person other than an executive officer or employee of the Company or any other individual having a relationship which, in the opinion of the Company's Board of Directors, would interfere with the exercise of independent judgment in carrying out the responsibilities of a director.’ Our Board of Directors has affirmatively determined that the following directors, Dr. Joseph A. Miller, Jr., Ronald A. Bucchi, Siraj Nour El-Ahmadi and William C. Pickett, III (served as a director from 2008 to August 15, 2018) are/were independent directors in that they are/were independent of management and free of any relationship that would interfere with their independent judgment as members of our Board of Directors. In making such determination, our Board of Directors considered the relationships that each such non-employee director has with our Company and all other facts and circumstances that our Board of Directors deemed relevant in determining their independence, including the beneficial ownership of our capital stock by each non-employee director. The following members of our Board of Directors, Thomas E. Zelibor, Dr. Michael S. Lebby, James S. Marcelli and Dr. Frederick J. Leonberger are not are independent directors pursuant to the standards described above.

Our Company does not have a separately designated nominating or compensation committee or committee performing similar functions; therefore, our full Board of Directors currently serves in these capacities.

Family Relationships

There are no family relationships among any of our current or former directors or executive officers.

Involvement in Certain Legal Proceedings

We are not aware of any of our directors or officers being involved in any legal proceedings in the past ten years relating to any matters in bankruptcy, insolvency, criminal proceedings (other than traffic and other minor offenses), or being subject to any of the items set forth under Item 401(f) of Regulation S-K.

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EXECUTIVE COMPENSATION

Summary Compensation Table

(1)

The named executive officer’s compensation includes the amount for services rendered to the Company in his capacity as both an officer and a director.

(2)

The aggregate fair value of awards and options in columns (e) and (f) are computed in accordance with FASB ASC 718. The amounts shown in columns (f) do not reflect dollar amounts actually received by our named executive officers.

(3)

The amount in column (g) reflects a salary gross up for long term disability premium payments.

(4)

Dr. Lebby became our Chief Executive Officer on May 1, 2017. The amount in column (g) also includes a salary gross up for long term disability premium payments of $2,840, in 2018 and $2,963 in 2019.

(5)

The amounts in column (g) include a salary gross up for long term disability premium payments of $2,355 in 2018 and 2,245 in 2019.

At no time during the last fiscal year was any outstanding option otherwise modified or re-priced, and there was no tandem feature, reload feature, or tax-reimbursement feature associated with any of the stock options we granted to our executive officers or otherwise.

We grant stock awards and stock options to our executive officers based on their level of experience and contributions to our Company. The aggregate fair value of awards and options are computed in accordance with FASB ASC 718 and are reported in the Summary Compensation Table above in the columns (e) and (f).

Employee, Severance, Separation and Change in Control Agreements

Dr. Michael S. Lebby Employee Agreement- Chief Executive Officer

On March 20, 2017, we entered into an employment agreement with Dr. Michael S. Lebby (the “Lebby Employment Agreement”). The term of the Lebby Employment Agreement commenced on May 1, 2017 for a period of 24 months, following which time the Lebby Employment Agreement will be renewed for successive 12-month periods at the end of each term upon the written agreement of the parties that shall be delivered by each party to the other not less than 60 days prior to the expiration of the existing term. Upon entering into the Lebby Employment Agreement, Dr. Lebby was granted (i) 350,000 stock options, which have an exercise price of $0.70 per share and are fully vested at this time. In the event of a change in control of our Company, Dr. Lebby’s options shall remain exercisable as set forth in Dr. Lebby’s stock option agreement. On April 8, 2019, we entered into an amended employee agreement with Dr. Lebby to (i) increase his base salary to $278,250 per year effective May 1, 2019, (ii) provide him with eligibility to receive bonus compensation to be determined by the Board of Directors from time to time in its sole discretion, and (iii) extend his employee agreement’s expiration date to April 30, 2021.

If Dr. Lebby’s employment terminates upon the expiration of the term of the Lebby Employment Agreement, and the Company elects for any reason not to renew the Lebby Employment Agreement for an additional 12-month term, then our Company will continue to pay to Dr. Lebby the compensation described in the Lebby Employment Agreement for a period of 9 months the after the termination. If Dr. Lebby’s employment is terminated by the Company without cause during the term of the Lebby Employment Agreement, the Company will pay to Dr. Lebby’s the compensation described in the Lebby Employment Agreement for the remainder of the term of Lebby Employment Agreement or 12 months, whichever is longer.

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Mr. James S. Marcelli Employee Agreement- President; Chief Operating Officer

On August 10, 2015, we entered into a new employment agreement with Mr. Marcelli, which was amended during 2015 and 2017 (collectively, the “Marcelli Employment Agreement”), which replaced his previous employment agreement, as amended. The term of the Marcelli Employment Agreement commenced on January 1, 2014 and expires December 31, 2019, following which time the Marcelli Employment Agreement will be renewed for successive 12-month periods at the end of each term upon the written agreement of the parties that shall be delivered by each party to the other not less than 60 days prior to the expiration of the existing term. Upon entering into the Marcelli Employment Agreement, Mr. Marcelli was granted (i) 50,000 stock options, which have an exercise price of $0.67 per share and are fully vested at this time. In the event of a change in control of our Company, Mr. Marcelli’s options shall remain exercisable as set forth in Mr. Marcelli’s stock option agreement. On April 8, 2019, we entered into an amended employee agreement with Mr. Marcelli, to (i) increase his base salary to $262,500 per year effective May 1, 2019, (ii) provide him with eligibility to receive bonus compensation to be determined by the Board of Directors from time to time in its sole discretion, and (iii) extend his employee agreement’s expiration date to December 31, 2021.

If Mr. Marcelli’s employment terminates upon his death and key man life insurance is in place for Mr. Marcelli, our Company will continue to pay the compensation described in the Marcelli Employment Agreement to his estate through the remainder of the term of the Marcelli Employment Agreement, or 12 months, whichever is longer. If Mr. Marcelli’s employment terminates upon the expiration of the term of the Marcelli Employment Agreement, and the Company elects for any reason not to renew the Marcelli Employment Agreement for an additional 12-month term, then our Company will continue to pay to Mr. Marcelli the compensation described in the Marcelli Employment Agreement for a period of 9 months the after the termination. If Mr. Marcelli’s employment is terminated by the Company without cause during the term of the Marcelli Employment Agreement, the Company will pay to Mr. Marcelli the compensation described in the Marcelli Employment Agreement for the remainder of the term of Marcelli Employment Agreement or 12 months, whichever is longer.

Potential Payments Upon Termination or Change In Control

Pursuant to employment agreements we have entered into with our executives and the terms of our 2016 Equity Incentive Plan, our executives are entitled to certain benefits in the event of a change in control of our Company or the termination of their employment under specified circumstances, including termination following a change in control. We believe these benefits help us compete for and retain executive talent and are generally in line with severance packages offered to executives by the companies in our peer group. We also believe that these benefits would serve to minimize the distraction caused by any change in control scenario and reduce the risk that key talent would leave the Company before any such transaction closes, which could reduce the value of the Company if such transaction failed to close.

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Outstanding Equity Awards At Fiscal Year-End

The table below summarizes all of the outstanding equity awards for our named executive officers as of December 31, 2019, our latest fiscal year end.

(1)

Dr. Lebby received an option to purchase up to: (i) 200,000 shares of Common Stock, of which 50,000 shares vested on August 26, 2015 and the remaining shares vest in equal annual installments of 50,000 options per year commencing on August 26, 2016; (ii) 50,000 shares of Common Stock, of which 20,000 shares vested on February 11, 2016 and the remaining shares vested quarterly in equal installments of 10,000 options per quarter commencing on April 1, 2016; (iii) 50,000 shares of Common Stock, of which 20,000 shares vested on January 17, 2017 and the remaining shares vested quarterly in equal installments of 10,000 options per quarter commencing on April 1, 2017; (iv) 350,000 shares of Common Stock, which vest quarterly over one year in equal installments of 87,500 shares per quarter beginning May 1, 2017; (iv) 350,000 shares of Common Stock, which vest quarterly over one year in equal installments of 87,500 shares per quarter beginning May 1, 2017 (v) 100,000 shares of Common Stock, of which 12,500 shares vested on May 1, 2019 and the remaining shares vested quarterly in equal installments of 12,500 options per quarter commencing on August 1, 2019.

(2)

Mr. Marcelli received an option to purchase up to (i) 50,000 shares of Common Stock, of which 12,500 shares vested on August 10, 2015 and the remaining shares vested quarterly in equal installments of 12,500 shares; (ii) 1,150,000 shares of Common Stock at an exercise price of $.70 that vested immediately; and (iii) up to 100,000 shares of Common Stock, of which 25,000 shares vested on August 1, 2013 and the remaining shares vested quarterly in equal installments of 25,000 shares commencing on October 1, 2013; (iv) 100,000 shares of Common Stock, of which 12,500 shares vested on May 1, 2019 and the remaining shares vested quarterly in equal installments of 12,500 options per quarter commencing on August 1, 2019.

(3)

 In the event of a change in control of our Company, such person’s options will become fully vested and/or exercisable, as the case may be, immediately prior to such change in control, and shall remain exercisable as set forth in their stock option agreement.

No stock options, SARs and similar instruments were exercised, and no stock, including restricted stock, restricted stock units and similar instruments vested, by or for any of our named executive officer during the last completed fiscal year.

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Compensation of Directors

Set forth below is a summary of the compensation of our directors during our December 31, 2019 fiscal year.

(1)

Dr. Lebby served solely as a director until May 1, 2017 when he was named as an executive officer and a director. Dr. Lebby’s total 2019 compensation is set forth in the Summary Compensation Table set forth above.

(2)

Mr. Zelibor served as an executive officer and director until April 30, 2017. During 2019, Mr. Zelibor received compensation under the Director Compensation Program of $2,000 per attendance at an in-person meeting and $700 per participation in a teleconference meeting.  On January 14, 2019, Mr. Zelibor received an option to purchase up to up to 110,000 shares of Common Stock at an exercise price of $.84 that vest pursuant to the following schedule: 27,500 shares vested immediately; and the remaining options vest in 3 equal quarterly installments of 27,500 options per year, beginning on April 1, 2019.  As of December 31, 2019, Mr. Zelibor holds options to purchase up to 1,400,000 shares of Common Stock.

(3)

Mr. Marcelli serves as an executive officer and a director but receives no additional compensation for serving as a director. Mr. Marcelli’s total 2019 compensation is set forth in the Summary Compensation Table set forth above. As of December 31, 2019, Mr. Marcelli holds options to purchase up to 1,300,000 shares of Common Stock.

(4)

On July 31, 2018 William C. Pickett III resigned as a director, and As of December 31, 2019, Mr. Pickett holds options to purchase up to 690,000 shares of Common Stock.

(5)

During 2019, Dr. Miller received compensation under the Director Compensation Program of $2,000 per attendance at an in-person meeting and $700 per participation in a teleconference meeting.  On January 14, 2019, Dr. Miller received an option to purchase up to up to 60,000 shares of Common Stock at an exercise price of $0.84 that vest pursuant to the following schedule: 15,000 shares vested immediately; and the remaining options vest in 3 equal quarterly installments of 15,000 options per year, beginning on April 1, 2019. As of December 31, 2019, Dr. Miller holds options to purchase up to 510,000 shares of Common Stock.

(6)

During 2019, Mr. Bucchi received compensation under the Director Compensation Program of $2,000 per attendance at an in-person meeting and $700 per participation in a teleconference meeting.  On January 14, 2019, Mr. Bucchi received an option to purchase up to up to 80,000 shares of Common Stock at an exercise price of $0.84 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal quarterly installments of 20,000 options per year, beginning on April 1, 2019. As of December 31, 2019, Mr. Bucchi holds options to purchase up to 680,000 shares of Common Stock.

(7)

During 2019, Mr. El-Ahmadi received compensation under the Director Compensation Program of $2,000 per attendance at an in-person meeting and $700 per participation in a teleconference meeting.  On January 14, 2019, Mr. El-Ahmadi received an option to purchase up to up to 60,000 shares of Common Stock at an exercise price of $0.84 that vest pursuant to the following schedule: 15,000 shares vested immediately; and the remaining options vest in 3 equal quarterly installments of 15,000 options per year, beginning on April 1, 2019. As of December 31, 2019, Mr. El-Ahmadi holds options to purchase up to 510,000 shares of Common Stock.

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(8)

During 2019, Dr. Leonberger received compensation under the Director Compensation Program of $2,000 per attendance at an in-person meeting and $700 per participation in a teleconference meeting.  During 2019, Dr. Leonberger received $11,500 per month in cash as compensation for serving on our Operations Committee. On January 14, 2019, Dr. Leonberger received an option to purchase up to up to 60,000 shares of Common Stock at an exercise price of $0.84 that vest pursuant to the following schedule: 15,000 shares vested immediately; and the remaining options vest in 3 equal quarterly installments of 15,000 options per year, beginning on April 1, 2019.  As of December 31, 2019, Dr. Leonberger holds options to purchase up to 310,000 shares of Common Stock and warrants to purchase up to 725,000 shares of Common Stock.

In the event of a change in control of our Company, all of the above options become fully vested and/or exercisable, as the case may be, immediately prior to such change in control, and shall remain exercisable as set forth in their stock option agreement.

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CERTAIN RELATIONSHIPS AND RELATED PARTY TRANSACTIONS

Transactions with Related Persons

Dr. Frederick J. Leonberger, through EOvation Advisors LLC, has served as a senior advisor to our Company since December 2011, with emphasis on modulator/technology development. Information regarding compensation paid to Dr. Leonberger in 2018 and 2019 is described in the section entitled “Executive Compensation.”

See also, the transactions set forth in Note 11 to the Audited Financial Statements for the years ended December 31, 2018 and 2017, and Note 11 to the Unaudited Financial Statements for the interim period ended September 30, 2019.

Policies and Procedures for Related-Party Transactions

Our Company does not have any formal written policies or procedures for related party transactions, however in practice, our board of directors reviews and approves all related party transactions and other matters pertaining to the integrity of management, including potential conflicts of interest, trading in our securities, or adherence to standards of business conduct.

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SECURITY OWNERSHIP OF CERTAIN BENEFICIAL OWNERS AND MANAGEMENT

The following table sets forth, as of January 22, 2020, the names, addresses, amount and nature of beneficial ownership and percent of such ownership of each person or group known to our Company to be the beneficial owner of more than five percent (5%) of our Common Stock:

Security Ownership of Certain Beneficial Owners

(1)

In care of our Company at 369 Inverness Parkway, Suite 350, Englewood, CO 80112.

(2)

To our best knowledge, as of the date hereof, such holders had the sole voting and investment power with respect to the voting securities beneficially owned by them, unless otherwise indicated herein. Includes the person's right to obtain additional shares of Common Stock within 60 days from the date hereof.

(4)

Based on 87,921,049 shares of Common Stock outstanding on January 22, 2020. Does not include shares underlying: (i) options to purchase shares of our Common Stock under our 2007 Employee Stock Plan and our 2016 Equity Incentive Plan; or (ii) outstanding warrants to purchase shares of our Common Stock.

The following table sets forth, as of January 22, 2020, the names, addresses, amount and nature of beneficial ownership and percent of such ownership of our Common Stock of each of our officers and directors, and officers and directors as a group:

Security Ownership of Management

———————

* Less than 1%.

(1)

In care of our Company at 369 Inverness Parkway, Suite 350, Englewood, CO 80112.

(2)

To our best knowledge, as of the date hereof, such holders had the sole voting and investment power with respect to the voting securities beneficially owned by them, unless otherwise indicated herein. Includes the person's right to obtain additional shares of Common Stock within 60 days from January 22, 2020.

(3)

Based on 87,793,132 shares of Common Stock outstanding on January 22, 2020. Does not include shares underlying: (i) options to purchase shares of our Common Stock under our 2007 Employee Stock Plan and our 2016 Equity Incentive Plan and (ii) outstanding warrants to purchase shares of our Common Stock.

(4)

If a person listed on this table has the right to obtain additional shares of Common Stock within 60 days from January 16, 2020, the additional shares are deemed to be outstanding for the purpose of computing the percentage of class owned by such person but are not deemed to be outstanding for the purpose of computing the percentage of any other person.

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(5)

Consists of 62,643 shares of Common Stock and an option to purchase up to 700,000 shares of Common Stock exercisable within 60 days from January 22, 2020.

(6)

Consists of 246,700 shares of Common Stock, an option to purchase up to 1,350,000 shares of Common Stock exercisable within 60 days from January 22, 2020.

(7)

Consists of 50,124 shares of Common Stock, an option to purchase up to 1,427,500 shares of Common Stock exercisable within 60 days from January 22,  2020.

(8)

Consists of 13,400 shares of Common Stock, options to purchase up to 525,000 shares of Common Stock exercisable within 60 days from January 22,  2020.

(9)

Consists of 174,000 shares of Common Stock, an option to purchase up to 700,000 shares of Common Stock exercisable within 60 days from January 22,  2020. Mr. Bucchi disclaims beneficial ownership of 53,000 shares held by his spouse.

(10)

Consists of an option to purchase up to 525,000 shares of Common Stock exercisable within 60 days from January 22,  2020.

(11)

Consists of an option to purchase up to 275,000 shares of Common Stock exercisable within 60 days from January 22,  2020 and warrants to purchase up to 725,000 shares of Common Stock exercisable within 60 days from January 22,  2020.

We are not aware of any arrangements that could result in a change of control.

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THE LINCOLN PARK TRANSACTION

General

On January 21, 2019, we entered into the Purchase Agreement with Lincoln Park, pursuant to which Lincoln Park agreed to purchase from us up to $25,000,000 of our Common Stock (subject to certain limitations) from time to time over a 36-month period. In connection with the Purchase Agreement, the Company also entered into a registration rights agreement with Lincoln Park whereby the Company agreed to file registration statements, with the SEC covering the shares of the Company’s Common Stock that may be issued to Lincoln Park under the Purchase Agreement. While a registration statement covering such shares of Common Stock issuable under the Purchase Agreement is effective, we may, from time to time and at its sole discretion, direct Lincoln Park to purchase up to 125,000 shares of our Common Stock on any such business day, which may be increased to up to 200,000 shares depending on certain conditions as set forth in the Purchase Agreement (and subject to adjustment for any reorganization, recapitalization, non-cash dividend, stock split, reverse stock split or other similar transaction as provided in the Purchase Agreement); provided that in no event shall Lincoln Park purchase more than $500,000 worth of our Common Stock on any single business day (each, a “Regular Purchase”). Under certain circumstances, we may also, in our sole discretion, direct Lincoln Park on each purchase date to make “accelerated purchases” on the following business day up to the lesser of (i) two (2) times the number of shares purchased pursuant to a Regular Purchase or (ii) 30% of the trading volume on the accelerated purchase date at a purchase price equal to the lesser of (i) the closing sale price on the accelerated purchase date and (ii) 95% of the accelerated purchase date’s volume weighted average price. Except as described in this prospectus, there are no trading volume requirements or restrictions under the Purchase Agreement, and we control the timing and amount of any sales of our Common Stock to Lincoln Park. However, in no event may the Company sell any amount of shares that would result in Lincoln Park beneficially owning more than 4.99% of the Company’s Common Stock. The purchase price of the up to 200,000 shares that may be sold to Lincoln Park under the Purchase Agreement in a Regular Purchase on any business day will be based on the market price of our Common Stock immediately preceding the time of sale as computed under the Purchase Agreement without any fixed discount.

The purchase price per share will be equitably adjusted for any reorganization, recapitalization, non-cash dividend, forward or reverse stock split, or other similar transaction occurring during the business days used to compute such price. We may at any time in our sole discretion terminate the Purchase Agreement without fee, penalty or cost upon one business day’s prior notice.

The Purchase Agreement contains customary representations, warranties, covenants, closing conditions and indemnification and termination provisions by, among and for the benefit of the parties. Lincoln Park has covenanted not to cause or engage in any manner whatsoever, any direct or indirect short selling or hedging of the Company’s Common Stock. Lincoln Park may not assign or transfer its rights and obligations under the Purchase Agreement, and the Purchase Agreement may be terminated by the Company at any time at its discretion without any cost to the Company.

In consideration for entering into the Purchase Agreement, the Company issued to Lincoln Park 350,000 shares of Common Stock as a commitment fee and is obliged to issue up to an additional 812,500 commitment shares, pro rata for no consideration, when and if Lincoln Park purchases (at the Company’s discretion) the $25,000,000 aggregate commitment.  For example, if we elect, at our sole discretion, to require Lincoln Park to purchase $50,000 of our stock then we would issue 1,625 additional commitment shares, which is the product of $50,000 (the amount we have elected to sell) divided by $25,000,000 (remaining total amount we can sell Lincoln Park pursuant to the Purchase Agreement) multiplied by 812,500 (the total number of additional commitment shares). The additional commitment shares will only be issued pursuant to this formula if and when we elect at our discretion to sell stock to Lincoln Park.

As January 22, 2020, 7,161,840 shares of Common Stock have been issued to Lincoln Park under the Purchase Agreement for gross proceeds of $4,979,625, which includes 6,650,000 purchase shares and 511,840 commitment shares, and 7,022,136 of such shares have been resold by Lincoln Park under the Prior Registration Statement.

Purchase of Shares under the Purchase Agreement

Under the Purchase Agreement, on any business day selected by us, we may direct Lincoln Park to purchase up to 125,000 shares of our Common Stock on any such business day as a Regular Purchase.  On any day that the closing sale price of our Common Stock is not below $1.00 the purchase amount may be increased, at our sole discretion, to up to 150,000 shares per purchase and on any day that the closing sale price of our Common Stock is not below $1.50 the purchase amount may be increased, at our sole discretion, to up to 200,000 shares per purchase, at our sole discretion, to up to $500,000 per purchase. The purchase price per share for each such Regular Purchase will be equal to the lower of:

·

the lowest sale price for our Common Stock on the purchase date of such shares; or

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·

the arithmetic average of the three lowest closing sale prices for our Common Stock during the 12 consecutive business days ending on the business day immediately preceding the purchase date of such shares.

In addition to Regular Purchases described above, we may also direct Lincoln Park, on any business day on which we have properly submitted a Regular Purchase notice and the closing sale price of the Common Stock is above $0.40 (subject to adjustment for any reorganization, recapitalization, non-cash dividend, stock split, reverse stock split or other similar transaction as provided in the Purchase Agreement),  to purchase an additional amount of our Common Stock, which we refer to as an “Accelerated Purchase,” not to exceed the lesser of:

·

30% of the aggregate shares of our Common Stock traded during normal trading hours on the purchase date; and

·

two times the number of purchase shares purchased pursuant to the corresponding Regular Purchase.

The purchase price per share for each such Accelerated Purchase will be equal to the lower of:

·

95% of the volume weighted average price during (i) the entire trading day on the purchase date, if the volume of shares of our Common Stock traded on the purchase date has not exceeded a volume maximum calculated in accordance with the Purchase Agreement, or (ii) the portion of the trading day of the purchase date (calculated starting at the beginning of normal trading hours) until such time at which the volume of shares of our Common Stock traded has exceeded such volume maximum; or

·

the closing sale price of our Common Stock on the purchase date.

We may also direct Lincoln Park, not later than 1:00 p.m., Eastern time, on a business day on which an Accelerated Purchase has been completed and all of the shares to be purchased thereunder (and under the corresponding Regular Purchase) have been properly delivered to Lincoln Park in accordance with the Purchase Agreement prior to such time on such business day, and provided that the closing sale price of the Common Stock is above $0.40 (subject to adjustment for any reorganization, recapitalization, non-cash dividend, stock split, reverse stock split or other similar transaction as provided in the Purchase Agreement), to purchase an additional amount of our Common Stock, which we refer to as an “Additional Accelerated Purchase,” not to exceed the lesser of:

·

30% of the aggregate shares of our Common Stock traded during normal trading hours on the purchase date; and

·

two times the number of purchase shares purchased pursuant to the corresponding Regular Purchase.

The purchase price per share for each such Additional Accelerated Purchase will be equal to the lower of:

·

95% of the volume weighted average price during (i) the entire trading day on the purchase date, if the volume of shares of our Common Stock traded on the purchase date has not exceeded a volume maximum calculated in accordance with the Purchase Agreement, or (ii) the portion of the trading day of the purchase date (calculated starting at the beginning of normal trading hours) until such time at which the volume of shares of our Common Stock traded has exceeded such volume maximum; or

·

the closing sale price of our Common Stock on the purchase date.

In the case of both Regular Purchases and Accelerated Purchases, the purchase price per share will be equitably adjusted for any reorganization, recapitalization, non-cash dividend, stock split, reverse stock split or other similar transaction occurring during the business days used to compute the purchase price.

Other than as set forth above, there are no trading volume requirements or restrictions under the Purchase Agreement, and we will control the timing and amount of any sales of our Common Stock to Lincoln Park.

Events of Default

Events of default under the Purchase Agreement include the following:

·

the effectiveness of the registration statement of which this prospectus forms a part lapses for any reason (including, without limitation, the issuance of a stop order), or any required prospectus supplement and accompanying prospectus are unavailable for the resale by Lincoln Park of our Common Stock offered hereby, and such lapse or unavailability continues for a period of 10 consecutive business days or for more than an aggregate of 30 business days in any 365-day period;

·

suspension by our principal market of our Common Stock from trading for a period of one business day;

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·

the de-listing of our Common Stock from our principal market, provided our Common Stock is not immediately thereafter trading on the New York Stock Exchange, the NASDAQ Global Market, the NASDAQ Global Select Market, the NASDAQ Capital Market, the NYSE MKT, the NYSE Arca, or the OTCQX operated by the OTC Markets Group, Inc. (or nationally recognized successor thereto);

·

the transfer agent’s failure for three business days to issue to Lincoln Park shares of our Common Stock which Lincoln Park is entitled to receive under the Purchase Agreement;

·

any breach of the representations or warranties or covenants contained in the Purchase Agreement or any related agreement which has or which could have a material adverse effect on us subject to a cure period of five business days;

·

any voluntary or involuntary participation or threatened participation in insolvency or bankruptcy proceedings by or against us; or

·

if at any time we are not eligible to transfer our Common Stock electronically or a material adverse change in our business, financial condition, operations or prospects has occurred.

Lincoln Park does not have the right to terminate the Purchase Agreement upon any of the events of default set forth above. During an event of default, all of which are outside of Lincoln Park’s control, shares of our Common Stock cannot be sold by us or purchased by Lincoln Park under the Purchase Agreement.

Our Termination Rights

We have the unconditional right, at any time, for any reason and without any payment or liability to us, to give notice to Lincoln Park to terminate the Purchase Agreement. In the event of bankruptcy proceedings by or against us, the Purchase Agreement will automatically terminate without action of any party.

No Short-Selling or Hedging by Lincoln Park

Lincoln Park has agreed that neither it nor any of its affiliates shall engage in any direct or indirect short-selling or hedging of our Common Stock during any time prior to the termination of the Purchase Agreement.

Prohibitions on Variable Rate Transactions

There are no restrictions on future financings, rights of first refusal, participation rights, penalties or liquidated damages in the Purchase Agreement or Registration Rights Agreement other than a prohibition on entering into a “Variable Rate Transaction,” as defined in the Purchase Agreement.

Effect of Performance of the Purchase Agreement on Our Stockholders

All 8,477,864 shares registered in this offering which have been or may be issued or sold by us to Lincoln Park under the Purchase Agreement are expected to be freely tradable. It is anticipated that shares registered in this offering will be sold over a period of up to 36-months from February of 2019. The sale by Lincoln Park of a significant amount of shares registered in this offering at any given time could cause the market price of our Common Stock to decline and to be highly volatile. Sales of our Common Stock to Lincoln Park, if any, will depend upon market conditions and other factors to be determined by us. We may ultimately decide to sell to Lincoln Park all, some or none of the additional shares of our Common Stock that may be available for us to sell pursuant to the Purchase Agreement. If and when we do sell shares to Lincoln Park, after Lincoln Park has acquired the shares, Lincoln Park may resell all, some or none of those shares at any time or from time to time in its discretion. Therefore, sales to Lincoln Park by us under the Purchase Agreement may result in substantial dilution to the interests of other holders of our Common Stock. In addition, if we sell a substantial number of shares to Lincoln Park under the Purchase Agreement, or if investors expect that we will do so, the actual sales of shares or the mere existence of our arrangement with Lincoln Park may make it more difficult for us to sell equity or equity-related securities in the future at a time and at a price that we might otherwise wish to effect such sales. However, we have the right to control the timing and amount of any additional sales of our shares to Lincoln Park and the Purchase Agreement may be terminated by us at any time at our discretion without any cost to us.

Pursuant to the terms of the Purchase Agreement, we have the right, but not the obligation, to direct Lincoln Park to purchase up to $25,000,000 of our Common Stock. Depending on the price per share at which we sell our Common Stock to Lincoln Park pursuant to the Purchase Agreement, we may need to sell to Lincoln Park under the Purchase Agreement more shares of our Common Stock than are offered under this prospectus in order to receive aggregate gross proceeds equal to the $25,000,000 total commitment available to us under the Purchase Agreement. If we choose to do so, we must first register for resale under the Securities Act such additional shares of our Common Stock, which could cause additional substantial dilution to our stockholders. The number of shares ultimately offered for resale by Lincoln Park under this prospectus is dependent upon the number of shares we direct Lincoln Park to purchase under the Purchase Agreement.

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The following table sets forth the amount of gross proceeds we would receive from Lincoln Park from our sale of shares to Lincoln Park under the Purchase Agreement at varying purchase prices:

———————

(1)

Although the Purchase Agreement provides that we may sell shares of Common Stock valued at up to $25,000,000, the shares of Common Stock registered hereunder may or may not cover all the shares of Common Stock we ultimately sell to Lincoln Park under the Purchase Agreement, depending on the purchase price per share. As a result, we have included in this column only those shares of Common Stock that we are registering in this offering that have not previously been sold to Lincoln Park.

(2)

The number of registered shares to be issued excludes any commitment shares because no proceeds will be attributable to such commitment shares, and excludes shares that may be issued to Lincoln Park under the Purchase Agreement which are not registered in this offering.

(3)

The denominator is based on 87,921,049 shares outstanding as of January 22, 2020, adjusted to include the number of shares of Common Stock set forth in the adjacent column which we would have issued to Lincoln Park (including commitment shares) based on the applicable assumed average purchase price per purchase share.

(4)

The closing sale price of our shares on January 22, 2020.

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SELLING SECURITYHOLDER

The shares of Common Stock being offered by the selling securityholder are those which may be issued to Lincoln Park pursuant to the Purchase Agreement. We are registering these shares of Common Stock in order to permit Lincoln Park, as the selling securityholder, to offer the shares for resale from time to time. Should we direct Lincoln Park to purchase shares in the Offering, it may resell such shares pursuant to the shares being registered hereunder pursuant to the Purchase Agreement.

Lincoln Park is not a licensed broker-dealer or affiliate of a licensed broker-dealer unless otherwise stated in the Plan of Distribution.

Except as otherwise set forth in the footnotes herein below, neither Lincoln Park  nor any of its affiliates have held a position or office, or had any other material relationship, with us within the past three years.

We do not know when or in what amounts Lincoln Park  may offer shares for sale. Lincoln Park  may elect not to sell any or all of the shares offered by this prospectus. Because Lincoln Park  may offer all, some or none of the shares, we cannot estimate the number of the shares that will be held by Lincoln Park  after completion of this offering. However, for purposes of this table, we have assumed that, after completion of the offering, all of the shares covered by this prospectus will be sold by Lincoln Park .

The following table presents information regarding Lincoln Park pursuant to the Purchase Agreement. The information concerning beneficial ownership has been taken from our stock transfer records and information provided by the selling securityholder and is dated as of January 22, 2020. Beneficial ownership has been calculated in accordance with the rules of the SEC, which generally attribute beneficial ownership of securities to persons who possess sole or shared voting power or investment power with respect to those securities and include shares of Common Stock issuable pursuant to the exercise of stock options or warrants that are either immediately exercisable or exercisable within 60 days of January 22, 2020.

———————

(1)  Josh Scheinfeld and Jonathan Cope, the principals of Lincoln Park, are deemed to be beneficial owners of all of the shares of Common Stock owned by Lincoln Park. Messrs. Scheinfeld and Cope have shared voting and disposition power over such shares being offered under this prospectus.

(2)  Excludes the 8,338,160 shares which may be issued to Lincoln Park hereunder in connection with the Purchase Agreement. Includes (i) 139,704  shares of Common stock previously purchased under Purchase Agreement and not resold as of January 22, 2020; (ii) 828,660 warrants to purchase Common Stock, the underlying shares of which were registered under the Prior Registration Statement, purchased by Lincoln Park in the December 30, 2015 private placement and (iii) 1,125,010 warrants to purchase Common Stock, the underlying shares of which were registered under the Prior Registration Statement, purchased by Lincoln Park in the June 15, 2015 private placement. The underlying shares of the foregoing warrants are subject to blocker provisions which restrict the exercise of such instrument if, as a result of such exercise, Lincoln Park, the holder, together with its affiliates and any other person whose beneficial ownership of Common Stock would be aggregated with Lincoln Park for purposes of Section 13(d) of the Exchange Act, would cause Lincoln Park to beneficially own in excess of 4.99% of our then issued and outstanding shares of Common Stock (including the shares of Common Stock issuable upon such exercise), as such percentage ownership is determined in accordance with the terms of each warrant. Any warrant that is not currently exercisable because of a blocker is not deemed to be beneficially owned by Lincoln Park. See the description under the heading “The Lincoln Park Transaction” for more information about the Purchase Agreement.

(3)  The numerator is the number of shares beneficially owned by Lincoln Park as of January 22, 2020. The denominator is based on 87,921,049 shares outstanding as of January 22, 2020, which includes the number of shares beneficially owned by Lincoln Park before this offering, and excludes any shares which may be sold in this offering which are not already beneficially owned by Lincoln Park.

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(4)  Although the Purchase Agreement provides that we may sell up to $25,000,000 of our Common Stock to Lincoln Park, only 8,477,864 shares of our Common Stock are being offered under this prospectus, which represents: (i) 650,660 shares issuable to Lincoln Park as commitment shares pro-rata in connection with the purchase of shares of our Common Stock under the Purchase Agreement, which were registered under the Prior Registration Statement and have not been issued; (ii) 1,687,500 shares of our Common Stock that may be sold by us to Lincoln Park at our discretion from time to time as purchase shares under the Purchase Agreement, which were registered under the Prior Registration Statement and have not been issued; (iii) 139,704 shares of our Common Stock that have been issued to Lincoln Park and not resold as of January 22, 2020, which were registered under the Prior Registration Statement and (iv) 6,000,000 newly registered shares of our Common Stock that may be sold by us to Lincoln Park at our discretion from time to time as purchase shares under the Purchase Agreement following the effectiveness of the registration statement of which this prospectus is a part. Depending on the price per share at which we sell our Common Stock to Lincoln Park pursuant to the Purchase Agreement, we may need to sell to Lincoln Park under the Purchase Agreement more shares of our Common Stock than are offered under this prospectus in order to receive aggregate gross proceeds equal to the $25,000,000 total commitment available to us under the Purchase Agreement. If we choose to do so, we must first register for resale under the Securities Act such additional shares. The number of shares ultimately offered for resale by Lincoln Park is dependent upon the number of shares we sell to Lincoln Park under the Purchase Agreement.

(5)  Calculated by dividing (i) the total number of shares beneficially owned by Lincoln Park on January 22, 2020, assuming all shares of Common Stock registered hereunder have been resold by Lincoln Park, by (ii) the number of shares of our Common Stock outstanding as of January 22, 2020, as adjusted to include the 8,338,160 shares which may be issued to Lincoln Park hereunder in connection with the Purchase Agreement that are registered hereunder.

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DESCRIPTION OF OUR COMMON STOCK

Each outstanding share of Common Stock is entitled to one vote on all matters to be submitted to a vote of the stockholders. Holders do not have preemptive rights, so we may issue additional shares that may reduce each holder’s voting and financial interest in our Company. Cumulative voting does not apply to the election of directors, so holders of more than 50% of the shares voted for the election of directors can elect all of the directors. All elections for directors shall be decided by a plurality vote; all other questions shall be decided by majority vote except as otherwise provided by Nevada Statutes. Our bylaws permit the holders of the same percentage of all stockholders entitled to vote at a meeting to take action by written consent without a meeting.

Holders of Common Stock are entitled to receive dividends when, as and if declared by the board of directors out of funds legally available therefor. In the event of liquidation, dissolution or winding up of our Company, holders are entitled to share ratably in all assets remaining available for distribution to them after payment of liabilities and after provision has been made for each class of stock, if any, having preference over the Common Stock. Holders do not have any conversion, redemption provisions or other subscription rights. All of the outstanding shares of Common Stock are fully paid and non-assessable.

As of January 22, 2020, our articles of incorporation authorizes us to issue 250,000,000 shares of Common Stock, par value $0.001 per share, and 1,000,000 shares of preferred stock, par value $0.001 per share. As of January 22, 2020, 87,921,049 shares of Common Stock were outstanding and no shares of preferred stock were outstanding.

Nevada Anti-Takeover Law and Charter and Bylaws Provisions

Nevada Revised Statutes sections 78.378 to 78.3793 provide state regulation over the acquisition of a controlling interest in certain Nevada corporations unless our articles of incorporation or bylaws of the corporation provide that the provisions of these sections do not apply. Our articles of incorporation and bylaws do not state that these provisions do not apply. The statute creates a number of restrictions on the ability of a person or entity to acquire control of a Nevada company by setting down certain rules of conduct and voting restrictions in any acquisition attempt, among other things. The statute is limited to corporations that are organized in the state of Nevada and that have 200 or more shareholders, at least 100 of whom are shareholders of record and residents of the State of Nevada; and does business in the State of Nevada directly or through an affiliated corporation. Because of these conditions, the statute does not apply to our Company.

Provisions of our articles of incorporation and our bylaws may delay or discourage transactions involving an actual or potential change in our control or change in our management. Therefore, these provisions could adversely affect the price of our Common Stock. Among other things, our articles of incorporation and our bylaws  (i) provide that the bylaws may be altered, amended or repealed and new bylaws may be adopted only by the board of directors, (ii) provide that the authorized number of directors, which may not be less than three or more than nine, may be changed only by resolution of the board of directors, (iii) permit our board of directors to issue up to 1,000,000 shares of preferred stock, with any rights, preferences and privileges as they may designate, including the right to approve an acquisition or other change in our control and (iv) our articles of incorporation provide that the shareholders shall not have pre-emptive rights to acquire unissued shares of the stock of the Company.

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PLAN OF DISTRIBUTION

8,477,864 shares of our Common Stock may be offered by this prospectus by Lincoln Park pursuant to the Purchase Agreement. The Common Stock may be sold or distributed from time to time by Lincoln Park directly to one or more purchasers or through brokers, dealers, or underwriters who may act solely as agents at market prices prevailing at the time of sale, at prices related to the prevailing market prices, at negotiated prices, or at fixed prices, which may be changed. The sale of the Common Stock offered by this prospectus could be affected in one or more of the following methods:

·

ordinary brokers’ transactions;

·

transactions involving cross or block trades;

·

through brokers, dealers, or underwriters who may act solely as agents;

·

“at the market” into an existing market for the Common Stock;

·

in other ways not involving market makers or established business markets, including direct sales to purchasers or sales effected through agents;

·

in privately negotiated transactions; or

·

any combination of the foregoing.

In order to comply with the securities laws of certain states, if applicable, the shares may be sold only through registered or licensed brokers or dealers. In addition, in certain states, the shares may not be sold unless they have been registered or qualified for sale in the state or an exemption from the state’s registration or qualification requirement is available and complied with.

Lincoln Park is an “underwriter” within the meaning of Section 2(a)(11) of the Securities Act.

Lincoln Park has informed us that it intends to use an unaffiliated broker-dealer to effectuate all sales, if any, of the Common Stock that it may purchase from us pursuant to the Purchase Agreement. Such sales will be made at prices and at terms then prevailing or at prices related to the then current market price. Each such unaffiliated broker-dealer will be an underwriter within the meaning of Section 2(a)(11) of the Securities Act. Lincoln Park has informed us that each such broker-dealer will receive commissions from Lincoln Park that will not exceed customary brokerage commissions.

Brokers, dealers, underwriters or agents participating in the distribution of the shares as agents may receive compensation in the form of commissions, discounts, or concessions from Lincoln Park and/or purchasers of the Common Stock for whom the broker-dealers may act as agent. The compensation paid to a particular broker-dealer may be less than or in excess of customary commissions. Neither we nor Lincoln Park can presently estimate the amount of compensation that any agent will receive. We know of no existing arrangements between Lincoln Park or any other stockholder, broker, dealer, underwriter or agent relating to the sale or distribution of the shares offered by this prospectus. At the time a particular offer of shares is made, a prospectus supplement, if required, will be distributed that will set forth the names of any agents, underwriters or dealers and any compensation from Lincoln Park, and any other required information.

We will pay the expenses incident to the registration, offering, and sale of the shares to Lincoln Park. We have agreed to indemnify Lincoln Park and certain other persons against certain liabilities in connection with the offering of shares of Common Stock hereunder, including liabilities arising under the Securities Act or, if such indemnity is unavailable, to contribute amounts required to be paid in respect of such liabilities. Lincoln Park has agreed to indemnify us against liabilities under the Securities Act that may arise from certain written information furnished to us by Lincoln Park specifically for use in this prospectus or, if such indemnity is unavailable, to contribute amounts required to be paid in respect of such liabilities.

Lincoln Park has represented to us that at no time prior to the Purchase Agreement has Lincoln Park or its agents, representatives or affiliates engaged in or effected, in any manner whatsoever, directly or indirectly, any short sale (as such term is defined in Rule 200 of Regulation SHO of the Exchange Act) of our Common Stock or any hedging transaction, which establishes a net short position with respect to our Common Stock. Lincoln Park agreed that during the term of the Purchase Agreement, it, its agents, representatives or affiliates will not enter into or effect, directly or indirectly, any of the foregoing transactions.

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We have advised Lincoln Park that it is required to comply with Regulation M promulgated under the Exchange Act. With certain exceptions, Regulation M precludes the selling stockholder, any affiliated purchasers, and any broker-dealer or other person who participates in the distribution from bidding for or purchasing, or attempting to induce any person to bid for or purchase any security which is the subject of the distribution until the entire distribution is complete. Regulation M also prohibits any bids or purchases made in order to stabilize the price of a security in connection with the distribution of that security. All of the foregoing may affect the marketability of the securities offered by this prospectus.

This offering will terminate on the earlier of (i) termination of the Purchase Agreement or (ii) the date that all shares offered by this prospectus have been sold by Lincoln Park.

Our Common Stock is traded on the OTCQB under the symbol “LWLG.”

When we refer to Lincoln Park in this prospectus, we mean Lincoln Park Capital Fund LLC, and the pledgees, donees, permitted transferees, assignees, successors, and others who later come to hold any of Lincoln Park’s interests in shares of our Common Stock other than through a public sale.

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LEGAL MATTERS

The validity of the securities being offered by this prospectus has been passed upon for us by Snell & Wilmer LLP, Reno, Nevada.

EXPERTS

Morison Cogen LLP, our independent registered public accounting firm, has audited our balance sheets as of December 31, 2018 and 2017 and the related statements of operations, stockholders’ equity, and cash flows for each of the years in the two years in the period ended December 31, 2018, and the related notes (herein referred to as “financial statements”), as set forth in their report, which is incorporated by reference in the prospectus and elsewhere in this registration statement. We have included our financial statements in this prospectus and elsewhere in the registration statement. Our consolidated financial statements are incorporated by reference in reliance on Morison Cogen LLP’s report, given on their authority as experts in accounting and auditing.

INCORPORATION OF CERTAIN DOCUMENTS BY REFERENCE

All documents subsequently filed by the Registrant with the SEC pursuant to Sections 13(a), 13(c), 14 and 15(d) of the Exchange Act (other than those made pursuant to Item 2.02 or Item 7.01 of Form 8-K or other information “furnished” to the SEC) prior to the filing of a post-effective amendment which indicates that all securities offered have been sold or which deregisters all securities then remaining unsold, shall be deemed to be incorporated by reference in this Registration Statement and to be part hereof from the date of filing of such documents. These documents include periodic reports, such as Proxy Statements, Annual Reports on Form 10-K, Quarterly Reports on Form 10-Q and Current Reports on Form 8-K (other than the portions of those documents not deemed to be filed, which is deemed not to be incorporated by reference in this Registration Statement). Any statement contained in a document incorporated or deemed to be incorporated herein by reference shall be deemed to be modified or superseded for purposes of this Registration Statement to the extent that a statement contained herein or in any other subsequently filed document which also is or is deemed to be incorporated by reference herein modifies or supersedes such statement. 

We will provide to each person, including any beneficial owner, to whom a prospectus is delivered a copy of any of the filings incorporated by reference  at no cost, if you submit a request to us by writing or telephoning us at the following mailing address or telephone number:

Lightwave Logic, Inc.

369 Inverness Parkway, Suite 350

Englewood, CO

Attn: James S. Marcelli

Jim@lightwavelogic.com

(720) 340-4949

Copies of these documents may also be accessed free of charge on our website at www.lightwavelogic.com.

WHERE YOU CAN FIND ADDITIONAL INFORMATION

We filed with the Securities and Exchange Commission a registration statement under the Securities Act of 1933 for the shares of Common Stock in this offering. This prospectus does not contain all of the information in the registration statement and the exhibits and schedule that were filed with the registration statement. For further information with respect to us and our Common Stock, we refer you to the registration statement and the exhibits and schedule that were filed with the registration statement. Statements contained in this prospectus about the contents of any contract or any other document that is filed as an exhibit to the registration statement are not necessarily complete, and we refer you to the full text of the contract or other document filed as an exhibit to the registration statement. The Securities and Exchange Commission maintains a website that contains reports, proxy and information statements, and other information regarding registrants that file electronically with the SEC. The address of the website is www.sec.gov.

We file periodic reports under the Securities Exchange Act of 1934, including annual, quarterly and special reports, and other information with the Securities and Exchange Commission. These periodic reports and other information are available on the website of the Securities and Exchange Commission referred to above.

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We make available free of charge on or through our internet website our annual reports on Form 10-K, quarterly reports on Form 10-Q, current reports on Form 8-K, and amendments to those reports filed or furnished pursuant to Section 13(a) or 15(d) of the Securities Exchange Act of 1934 as soon as reasonably practicable after we electronically file such material with, or furnish it to, the Securities and Exchange Commission.

DISCLOSURE OF COMMISSION POSITION ON INDEMNIFICATION
FOR SECURITIES ACT LIABILITY

Insofar as indemnification for liabilities arising under the Securities Act may be permitted to directors, officers or persons controlling the registrant pursuant to the foregoing provisions, the registrant has been informed that in the opinion of the SEC such indemnification is against public policy as expressed in the Securities Act and is, therefore, unenforceable.

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LIGHTWAVE LOGIC, INC.

FINANCIAL STATEMENTS

SEPTEMBER 30, 2019

(UNAUDITED)

DECEMBER 31, 2018 AND 2017

(AUDITED)

F-1

LIGHTWAVE LOGIC, INC.

BALANCE SHEETS

See accompanying notes to these financial statements.

F-2

LIGHTWAVE LOGIC, INC.

STATEMENTS OF OPERATIONS

FOR THE THREE MONTHS AND NINE MONTHS ENDING SEPTEMBER 30, 2019 AND 2018

(UNAUDITED)