Difference between revisions of "Team:Virginia/Entrepreneurship"
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| − | <a class=" | + | <a class="mainitem" href="https://2020.igem.org/Team:Virginia">HOME</a> |
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<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia">Main</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia">Main</a> | ||
| − | <a class="hvr-sweep-to-right" href="#abstract">Abstract | + | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia#abstract">Abstract</a> |
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<a class="mainitem" href="#project">PROJECT</a> | <a class="mainitem" href="#project">PROJECT</a> | ||
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<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Description">Description</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Description">Description</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Design">Design</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Design">Design</a> | ||
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<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Results">Results</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Results">Results</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Model">Modeling</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Model">Modeling</a> | ||
| + | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Engineering">Engineering</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Implementation">Implementation</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Implementation">Implementation</a> | ||
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<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Notebook">Notebook</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Notebook">Notebook</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Safety">Safety</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Safety">Safety</a> | ||
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<a class="mainitem" href="#parts">PARTS</a> | <a class="mainitem" href="#parts">PARTS</a> | ||
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| − | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/New_parts"> | + | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/New_parts"> Parts</a> |
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<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Members">Members</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Members">Members</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Attributions">Attributions</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Attributions">Attributions</a> | ||
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<a class="mainitem" href="#about">RESOURCES</a> | <a class="mainitem" href="#about">RESOURCES</a> | ||
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| − | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Papers"> | + | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Papers">Sources</a> |
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/nucleic_acids">Nucleic Acids</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/nucleic_acids">Nucleic Acids</a> | ||
<a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Protocols">Protocols</a> | <a class="hvr-sweep-to-right" href="https://2020.igem.org/Team:Virginia/Protocols">Protocols</a> | ||
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<div>Entrepreneurship</div> | <div>Entrepreneurship</div> | ||
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| − | <div class="sectionTitle" id="Section 1">Kickstarting Virginia iGEM’s | + | <div class="sectionTitle" id="Section 1">Kickstarting Virginia iGEM’s Entrepreneurship Committee</div> |
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Starting an entrepreneurship committee was a natural calling for the Virginia iGEM 2020 team – with the launch of iGEM’s new EPIC committee and increasing concerns regarding IP protection, the establishment of an entrepreneurship committee was a no brainer. There was a rising necessity for a space where our teammates could hold discussions and debates addressing our countless questions on commercialization, patentability, and more importantly, the implications of our product. Essentially, our team needed a space where we could hone our skills in creative problem solving, negotiation, and networking in the business sector. We needed to develop a culture which carefully balanced the open-source innovative nature of iGEM. With enough research, informational interviews, and inspiration from iGEM EPIC, we were able to justify the creation. At the time of a global pandemic and national public health crisis, we craved to be even more intentional about our work than before, and entrepreneurship offered the perfect opportunity to ignite this passion. | Starting an entrepreneurship committee was a natural calling for the Virginia iGEM 2020 team – with the launch of iGEM’s new EPIC committee and increasing concerns regarding IP protection, the establishment of an entrepreneurship committee was a no brainer. There was a rising necessity for a space where our teammates could hold discussions and debates addressing our countless questions on commercialization, patentability, and more importantly, the implications of our product. Essentially, our team needed a space where we could hone our skills in creative problem solving, negotiation, and networking in the business sector. We needed to develop a culture which carefully balanced the open-source innovative nature of iGEM. With enough research, informational interviews, and inspiration from iGEM EPIC, we were able to justify the creation. At the time of a global pandemic and national public health crisis, we craved to be even more intentional about our work than before, and entrepreneurship offered the perfect opportunity to ignite this passion. | ||
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<div class="sectionTitle" id="Section 2">Our Journey with IP Protection </div> | <div class="sectionTitle" id="Section 2">Our Journey with IP Protection </div> | ||
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| − | Questions about what constitutes a public disclosure first arose in conversation between the wet lab and human practices committees. Bridging the gap between our team, the university, and the Charlottesville (Cville) community required openly sharing our thoughts and ideas to seek expertise and collaboration on | + | Questions about what constitutes a public disclosure first arose in conversation between the wet lab and human practices committees. Bridging the gap between our team, the university, and the Charlottesville (Cville) community required openly sharing our thoughts and ideas to seek expertise and collaboration on Manifold. However, we had to be aware of the implications that public disclosures would pose if we had any plans on commercializing our foundational advance in the future. Our lack of expertise in the space in combination with our curiosity to learn more led to our reaching out to lawyers at Cville BioHub—Cville’s diverse biotech center. |
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| − | Vance helped us to understand the ins and outs patent filing logistics. He shared his expertise about biotech startups and gave us some key insight into the startup landscape in Cville and iGEM. Insights gathered included: | + | Mr. Vance helped us to understand the ins and outs patent filing logistics. He shared his expertise about biotech startups and gave us some key insight into the startup landscape in Cville and iGEM. Insights gathered included: |
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<div class="section"> | <div class="section"> | ||
<ol> | <ol> | ||
<li> A public disclosure constitutes any non-confidential disclosure of our idea or invention in a public environment. This meant one-on-one Zoom calls with experts and mentors would not be an issue, but it would be smart on our part to file for a Provisional Patent Application (PPA) a few weeks before the iGEM wiki freeze </li> | <li> A public disclosure constitutes any non-confidential disclosure of our idea or invention in a public environment. This meant one-on-one Zoom calls with experts and mentors would not be an issue, but it would be smart on our part to file for a Provisional Patent Application (PPA) a few weeks before the iGEM wiki freeze </li> | ||
| − | <li> Can we write the PPA ourselves? Absolutely! We should draw thorough diagrams illustrating our invention and learn from previous biotech parents to map out our PPA. We should also refer to the official Manual of Patent Examining Procedure | + | <li> Can we write the PPA ourselves? Absolutely! We should draw thorough diagrams illustrating our invention and learn from previous biotech parents to map out our PPA. We should also refer to the official Manual of Patent Examining Procedure to ensure our work is lawful</li><br/> |
</ol></div> | </ol></div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | Vance enabled us to take charge of our own IP protection and we could not have done so without his help. | + | Mr. Vance enabled us to take charge of our own IP protection and we could not have done so without his help. |
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | Keshap, on the other hand, was important in helping us to understand corporate law. He gave us great advice on how to run a team like a business, and consider the future impact of the decisions we made. Insights included: | + | Mr. Keshap, on the other hand, was important in helping us to understand corporate law. He gave us great advice on how to run a team like a business, and consider the future impact of the decisions we made. Insights included: |
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<li> Vested equity is a technique where equity is ‘vested’ or secured over time-- this way, teammates will have to earn their equity over time by adding evident value to the team</li> | <li> Vested equity is a technique where equity is ‘vested’ or secured over time-- this way, teammates will have to earn their equity over time by adding evident value to the team</li> | ||
<li> We must be smart about our decision making and constantly consider the implications of our decisions. For example, <i> if we file our PPA before the wiki, is 9 months long enough to secure a proof-of-concept?</i> We had to have a plan 9 months ahead of time, and consult with various experts in synthetic biology and startup law to make an informed decision. This also meant considering bioethics-- understanding the good and bad impacts of our device on the end-user-- which led to the publishing of our Code of Ethical Conduct by human practices. </li> | <li> We must be smart about our decision making and constantly consider the implications of our decisions. For example, <i> if we file our PPA before the wiki, is 9 months long enough to secure a proof-of-concept?</i> We had to have a plan 9 months ahead of time, and consult with various experts in synthetic biology and startup law to make an informed decision. This also meant considering bioethics-- understanding the good and bad impacts of our device on the end-user-- which led to the publishing of our Code of Ethical Conduct by human practices. </li> | ||
| − | <li>Maintain touch with your stakeholders and constantly networking is integral to keeping our creativity sharp and our opportunities open.</li> | + | <li>Maintain touch with your stakeholders and constantly networking is integral to keeping our creativity sharp and our opportunities open.</li><br/> |
</ol> | </ol> | ||
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | Thanks to Nikki, David, and Rahul, we | + | Thanks to Nikki, David, and Rahul, we learned a lot about what it takes to go from a competitive iGEM team idea to a startup. Putting their advice into practice, we were able to have our PPA reviewed by Mr. Vance, and by the end of September, our PPA was accepted by the USPTO. |
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| − | Industry research was an integral component in contextualizing the use and applications of | + | Industry research was an integral component in contextualizing the use and applications of Manifold. The chemical manufacturing industry is one of the biggest in the world, producing over $5 trillion worth of chemicals per year. It is a mature market that grows on par with the world economy, at an annual rate of 3%. The key players are established companies from around the world, including DowDuPont in the US; BASF, Evonik and Bayer in Germany; Sinopec in China; Sumitomo, Mitsui, Nippon Kayaku and Mitsubishi in Japan; LG Chem in Korea; and DSM in the Netherlands. The market comprises four subsegments that overlap to differing degrees - diversified chemicals, fine chemicals, specialty chemicals and commodity chemicals <div class="ref">[1]<span>Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].</span></div>. |
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | Consolidation within the industry, caused by subpar market expansion and increased globalization, has led to less competition and fewer rivals being able to gain market share from the chemical titans previously mentioned. As key players in the chemical industry continue to innovate, synthetic biology is quickly becoming a go-to for solutions aimed at lowering costs and synthesizing novel products. Many synthetic biology companies are already leading the charge; Amyris has engineered yeast to produce the antimalarial Artemenisin, Geltor is using synthetic biology to produce collagen substitutes, Biossance is biochemically synthesizing squalane, Evolva is producing nootkatone via fermentation, Conagen is using bacteria to produce vanillin, Antheia is biosynthetically manufacturing opioids with yeast, and Renew is using microbes to produce cannabinoids | + | Consolidation within the industry, caused by subpar market expansion and increased globalization, has led to less competition and fewer rivals being able to gain market share from the chemical titans previously mentioned. As key players in the chemical industry continue to innovate, synthetic biology is quickly becoming a go-to for solutions aimed at lowering costs and synthesizing novel products. Many synthetic biology companies are already leading the charge; Amyris has engineered yeast to produce the antimalarial Artemenisin, Geltor is using synthetic biology to produce collagen substitutes, Biossance is biochemically synthesizing squalane, Evolva is producing nootkatone via fermentation, Conagen is using bacteria to produce vanillin, Antheia is biosynthetically manufacturing opioids with yeast, and Renew is using microbes to produce cannabinoids <div class="ref">[2]<span>“Synthetic biology is shaking up these 5 industries-Some of them might surprise you - SynBioBeta,” Synbiobeta.com, 11-Feb-2020. [Online]. Available: https://synbiobeta.com/synthetic-biology-is-shaking-up-these-5-industries-some-of-them-might-surprise-you/. [Accessed: 27-Oct-2020].</span></div>. |
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | We, Virginia iGEM, are in the early stages of a paradigm shift towards a sustainable economy, and interest in green chemicals has never been as strong as it is now. Whether this continued push comes from companys’ own initiatives or from government subsidies, a move away from environmentally damaging catalysts and energy intensive reaction conditions is widely regarded as essential | + | We, Virginia iGEM, are in the early stages of a paradigm shift towards a sustainable economy, and interest in green chemicals has never been as strong as it is now. Whether this continued push comes from companys’ own initiatives or from government subsidies, a move away from environmentally damaging catalysts and energy intensive reaction conditions is widely regarded as essential <div class="ref">[1]<span>Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].</span></div>. |
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | Capital intensity poses a threat to the manufacturing industry. Manufacturers have to analyze long term demand-trends to decide whether to expand or shut down large plants, which can often leave them vulnerable due to short term market volatility. The advantage of synthetic biology is that biosynthetic processes can be scaled up or down with unprecedented ease, allowing for more motility. Another advantage is that biochemical plants can be placed near feedstocks or end-markets, reducing transportation costs and turnaround times | + | Capital intensity poses a threat to the manufacturing industry. Manufacturers have to analyze long term demand-trends to decide whether to expand or shut down large plants, which can often leave them vulnerable due to short term market volatility. The advantage of synthetic biology is that biosynthetic processes can be scaled up or down with unprecedented ease, allowing for more motility. Another advantage is that biochemical plants can be placed near feedstocks or end-markets, reducing transportation costs and turnaround times <div class="ref">[1]<span>Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].</span></div>. |
</div> | </div> | ||
<div class="paragraph"> | <div class="paragraph"> | ||
| − | The synthetic biology industry’s rapid expansion has been forecasted by many established financial companies and economic institutions. McKinsey and Company, a global consulting firm, recently reported that biological approaches could end up producing 60% of physical inputs to the world economy | + | The synthetic biology industry’s rapid expansion has been forecasted by many established financial companies and economic institutions. McKinsey and Company, a global consulting firm, recently reported that biological approaches could end up producing 60% of physical inputs to the world economy <div class="ref">[3]<span> Innovations transforming economies and O. Lives, “The Bio Revolution,” Mckinsey.com. [Online]. Available: https://www.mckinsey.com/~/media/McKinsey/Industries/Pharmaceuticals%20and%20Medical%20Products/Our%20Insights/The%20Bio%20Revolution%20Innovations%20transforming%20economies%20societies%20and%20our%20lives/May_2020_MGI_Bio_Revolution_Report.pdf. [Accessed: 27-Oct-2020].</span></div>. Boston Consulting Group predicted the synthetic biology industry to grow at an annual rate of 34% from $6 billion in 2018 to $20 billion in 2022 <div class="ref">[4]<span>M. Portincaso, A. Gourévitch, S. Gross-Selbeck, and T. Reichert, “How Deep Tech Can Help Shape the New Reality,” BCG Global, 21-Jul-2020. [Online]. Available: https://www.bcg.com/publications/2020/how-deep-tech-can-shape-post-covid-reality. [Accessed: 27-Oct-2020]</span></div>. A report published by the European Commission suggested that biotechnological approaches could replace 30% of petroleum derived products in the EU by 2030 <div class="ref">[5]<span>Nature News. [Online]. Available: https://www.nature.com/articles/d42473-020-00220-x. [Accessed: 27-Oct-2020].</span></div>. The Organization of Economic Development published a report in 2009, named “The Bioeconomy to 2030”, that estimated the bioeconomy market at $1.6 trillion by the end of the decade. The report also stated that 39% of the bioeconomy would consist of using smart cells for industrial production of sustainable biomaterials such as PET bottles, synthetic rubber, dietary supplements, cosmetics and others <div class="ref">[6]<span>M. Samejima and A. Attorney, “Efforts Towards Open Innovation,” Nedo.go.jp. [Online]. Available: https://www.nedo.go.jp/content/100889935.pdf. [Accessed: 27-Oct-2020].</span></div>. |
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| − | We then decided to narrow down the scope of our research to the market we would first be targeting. The market size for resveratrol was about $62 million in 2017, and is expected to grow to around $140 million by 2026 with a forecasted compound annual growth rate of 9.7% | + | We then decided to narrow down the scope of our research to the market we would first be targeting. The market size for resveratrol was about $62 million in 2017, and is expected to grow to around $140 million by 2026 with a forecasted compound annual growth rate of 9.7% <div class="ref">[7]<span>C. M. Insights, “Resveratrol Market to Surpass US$ 159.1 Million by 2026 – Coherent Market Insights,” GlobeNewswire News Room, 21-Nov-2018. [Online]. Available: https://www.globenewswire.com/news-release/2018/11/21/1655234/0/en/Resveratrol-Market-to-Surpass-US-159-1-Million-by-2026-Coherent-Market-Insights.html. [Accessed: 27-Oct-2020]</span></div>. China is the largest manufacturer of resveratrol, followed by Europe, while North America is the largest consumer. The majority of resveratrol production in Europe comes in the form of grape skin extract, while the Chinese market focuses on knotweed extraction. These extraction processes utilize many environmentally harmful chemicals, such as methanol, ethanol, hydrochloric acid and methyl tert butyl ether <div class="ref">[8]<span>A. I. Romero-Pérez, R. M. Lamuela-Raventós, C. Andrés-Lacueva, and M. C. de La Torre-Boronat, “Method for the quantitative extraction of resveratrol and piceid isomers in grape berry skins. Effect of powdery mildew on the stilbene content,” J. Agric. Food Chem., vol. 49, no. 1, pp. 210–215, 2001.</span></div>, <div class="ref">[9]<span>D.-G. Wang, W.-Y. Liu, and G.-T. Chen, “A simple method for the isolation and purification of resveratrol from Polygonum cuspidatum,” Journal of Pharmaceutical Analysis, 10-Dec-2012. [Online]. Available: https://www.sciencedirect.com/science/article/pii/S2095177912001426. [Accessed: 27-Oct-2020]</span></div>. The main companies comprising 80% of the resveratrol market are: DSM, Evolva, Sabinsa, InterHealth, Maypro, Laurus Labs, JF-NATURAL, Great Forest Biomedical, Shaanxi Ciyuan Biotech, Chengdu Yazhong, Changsha Huir Biological-tech, Xi'an Gaoyuan Bio-Chem and Xi'an <div class="ref">[10]<span>“Resveratrol Market size 2020 industry share, demand, top players, industry size, future growth by 2026,” MarketWatch, 19-Oct-2020. [Online]. Available: https://www.marketwatch.com/press-release/resveratrol-market-size-2020-industry-share-demand-top-players-industry-size-future-growth-by-2026-2020-10-18. [Accessed: 27-Oct-2020].</span></div>. |
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| − | In chapter 5 of ‘Peanuts: Processing Technology and Product Development’ (2016), published by the Institute of Food Science and Technology at the Chinese Academy of Agricultural Sciences in Beijing, the price for a kilogram of 95%+ pure resveratrol is stated as being between 8,000-10,000$US. If our system was able to reach near perfect yields and we simply purchased p-coumaric acid in bulk from Sigma-Aldrich, then it would be able to produce a kilogram of pure resveratrol for half the price - around $4,000. The chapter also indicated that global resveratrol production in 2016 was at 50-60 tonnes, while the demand for the same time period was over 100 tonnes, underlining the great future prospects for the resveratrol market and the possibility for new manufacturers to enter the market | + | In chapter 5 of ‘Peanuts: Processing Technology and Product Development’ (2016), published by the Institute of Food Science and Technology at the Chinese Academy of Agricultural Sciences in Beijing, the price for a kilogram of 95%+ pure resveratrol is stated as being between 8,000-10,000$US. If our system was able to reach near perfect yields and we simply purchased p-coumaric acid in bulk from Sigma-Aldrich, then it would be able to produce a kilogram of pure resveratrol for half the price - around $4,000. The chapter also indicated that global resveratrol production in 2016 was at 50-60 tonnes, while the demand for the same time period was over 100 tonnes, underlining the great future prospects for the resveratrol market and the possibility for new manufacturers to enter the market <div class="ref">[11]<span>Q. Wang et al., “Peanut by-products utilization technology,” in Peanuts: Processing Technology and Product Development, Elsevier, 2016, pp. 211–325.</span></div>. |
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To further our vision, our team came up with an all-encompassing business plan to map out the steps required to establish a start-up. Everything hinges on verifiable lab results that can be used to establish a proof-of-concept and support claims on the Nonprovisional Patent. | To further our vision, our team came up with an all-encompassing business plan to map out the steps required to establish a start-up. Everything hinges on verifiable lab results that can be used to establish a proof-of-concept and support claims on the Nonprovisional Patent. | ||
</div> | </div> | ||
| − | <div class=" | + | <div class="nonParagraph"> |
<ol> | <ol> | ||
| − | <li>File Provisional Patent Application (PPA) through the USPTO (completed) </li> | + | <li>File Provisional Patent Application (PPA) through the USPTO <b>(completed)</b> </li> |
| − | <li>Secure filing date for Provisional Patent (completed) </li> | + | <li>Secure filing date for Provisional Patent <b>(completed)</b> </li> |
| − | <li>Incorporate LLC in Delaware | + | <li>Produce lab results for proof-of-concept </li> |
| − | + | <li>Incorporate LLC in Delaware | |
| − | + | <ol> | |
| − | + | <li>Shareholders Agreement</li> | |
| − | + | <li>Foreign Qualification to operate in VA</li> | |
| − | + | <li>Federal Tax Number</li> | |
| − | + | <li>Agreement for transfer of IP ownership to LLC</li> | |
| − | </li><li> | + | </ol> |
| − | + | </li> | |
| − | </div> | + | <li>Submit Project Proposal for NSF SBIR grant</li> |
| + | <li>Find lab space | ||
| + | <ol> | ||
| + | <li>Reach out to biotech companies in the Charlottesville area </li> | ||
| + | <li>Negotiate with the University </li> | ||
| + | </ol> | ||
| + | </li> | ||
| + | <li>Submit NSF SBIR Full Grant Application </li> | ||
| + | <li>Produce lab results for claims in Nonprovisional patent </li> | ||
| + | <li>Submit Nonprovisional patent </li> | ||
| + | <li>Find investors or look into an incubator | ||
| + | <ol> | ||
| + | <li>Charlottesville Angel Network </li> | ||
| + | <li>Y-Combinator</li> | ||
| + | </ol> | ||
| + | </li> | ||
| + | </ol></div> | ||
| + | <div class="paragraph"> | ||
| + | Once the team has a finished product, it would reach out to resveratrol suppliers to request information on their wholesale purchase costs. Manifold's business strategy would then vary based on responses. Either Manifold could become a chemical manufacturer itself and create its own distribution network, or it could license out the technology to the largest manufacturers. If the team were to move forward with the former route, then many up front costs would have to be taken care of. Permanent lab space, bioreactors, and purification machinery would all have to be purchased or leased. Transportation costs would also have to be taken into consideration. | ||
</div> | </div> | ||
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<div class="paragraph"> | <div class="paragraph"> | ||
| − | + | Breaking into the resveratrol industry is, however, not the main goal of the project. Manufacturing resveratrol or licensing Manifold is primarily for generating initial revenues that can bolster investor confidence and allow for expansion of the company, in addition to providing the foundation for other high-demand drug production. We strongly believe that Manifold could become a plug-and-play system for biosynthetically manufacturing a cornucopia of different chemicals. All that would be required is to change the sequence relating to the enzyme attached to the DNA scaffolds and our modified BMCs could house a huge variety of different pathways. A limitation to be noted is that precursors for encapsulated pathways need to be small enough to enter through the BMC’s pores. Some biochemical pathways the team could work to integrate into the Manifold system are nootkatone, which is derived from acetyl-CoA, and vanillin, which is derived from p-coumaric acid and was extensively researched by the 2013 UBC team <div class="ref">[12]<span>“Team:British Columbia/project/vanillin - 2013.Igem.Org,” Igem.org. [Online]. Available: https://2013.igem.org/Team:British_Columbia/Project/Vanillin. [Accessed: 27-Oct-2020].</span></div>. The pathway for squalene also seems to lend itself to the Manifold system. By selecting these chemicals, the team hopes to gain interest from synthetic biology companies such as Biossance, Evolva and Conagen. </div> | |
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</div> | </div> | ||
| + | <div class="sectionTitle" id="Section 6">References</div> | ||
| + | <div class="bar"></div> | ||
| + | <div class="section"> | ||
| + | [1] Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [2] “Synthetic biology is shaking up these 5 industries-Some of them might surprise you - SynBioBeta,” Synbiobeta.com, 11-Feb-2020. [Online]. Available: https://synbiobeta.com/synthetic-biology-is-shaking-up-these-5-industries-some-of-them-might-surprise-you/. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [3] Innovations transforming economies and O. Lives, “The Bio Revolution,” Mckinsey.com. [Online]. Available: https://www.mckinsey.com/~/media/McKinsey/Industries/Pharmaceuticals%20and%20Medical%20Products/Our%20Insights/The%20Bio%20Revolution%20Innovations%20transforming%20economies%20societies%20and%20our%20lives/May_2020_MGI_Bio_Revolution_Report.pdf. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [4] M. Portincaso, A. Gourévitch, S. Gross-Selbeck, and T. Reichert, “How Deep Tech Can Help Shape the New Reality,” <i>BCG Global</i>, 21-Jul-2020. [Online]. Available: https://www.bcg.com/publications/2020/how-deep-tech-can-shape-post-covid-reality. [Accessed: 27-Oct-2020]<br/><br/> | ||
| + | [5] Nature News. [Online]. Available: https://www.nature.com/articles/d42473-020-00220-x. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [6] M. Samejima and A. Attorney, “Efforts Towards Open Innovation,” Nedo.go.jp. [Online]. Available: https://www.nedo.go.jp/content/100889935.pdf. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [7] C. M. Insights, “Resveratrol Market to Surpass US$ 159.1 Million by 2026 – Coherent Market Insights,” <i>GlobeNewswire News Room</i>, 21-Nov-2018. [Online]. Available: https://www.globenewswire.com/news-release/2018/11/21/1655234/0/en/Resveratrol-Market-to-Surpass-US-159-1-Million-by-2026-Coherent-Market-Insights.html. [Accessed: 27-Oct-2020]<br/><br/> | ||
| + | [8] A. I. Romero-Pérez, R. M. Lamuela-Raventós, C. Andrés-Lacueva, and M. C. de La Torre-Boronat, “Method for the quantitative extraction of resveratrol and piceid isomers in grape berry skins. Effect of powdery mildew on the stilbene content,” <i>J. Agric. Food Chem.</i>, vol. 49, no. 1, pp. 210–215, 2001.<br/><br/> | ||
| + | [9] D.-G. Wang, W.-Y. Liu, and G.-T. Chen, “A simple method for the isolation and purification of resveratrol from Polygonum cuspidatum,” <i>Journal of Pharmaceutical Analysis</i>, 10-Dec-2012. [Online]. Available: https://www.sciencedirect.com/science/article/pii/S2095177912001426. [Accessed: 27-Oct-2020]<br/><br/> | ||
| + | [10] “Resveratrol Market size 2020 industry share, demand, top players, industry size, future growth by 2026,” MarketWatch, 19-Oct-2020. [Online]. Available: https://www.marketwatch.com/press-release/resveratrol-market-size-2020-industry-share-demand-top-players-industry-size-future-growth-by-2026-2020-10-18. [Accessed: 27-Oct-2020].<br/><br/> | ||
| + | [11] Q. Wang et al., “Peanut by-products utilization technology,” in <i>Peanuts: Processing Technology and Product Development</i>, Elsevier, 2016, pp. 211–325.<br/><br/> | ||
| + | [12] “Team:British Columbia/project/vanillin - 2013.Igem.Org,” Igem.org. [Online]. Available: https://2013.igem.org/Team:British_Columbia/Project/Vanillin. [Accessed: 27-Oct-2020].<br/><br/> | ||
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Latest revision as of 03:31, 28 October 2020
Index:
Entrepreneurship
Kickstarting Virginia iGEM’s Entrepreneurship Committee
Starting an entrepreneurship committee was a natural calling for the Virginia iGEM 2020 team – with the launch of iGEM’s new EPIC committee and increasing concerns regarding IP protection, the establishment of an entrepreneurship committee was a no brainer. There was a rising necessity for a space where our teammates could hold discussions and debates addressing our countless questions on commercialization, patentability, and more importantly, the implications of our product. Essentially, our team needed a space where we could hone our skills in creative problem solving, negotiation, and networking in the business sector. We needed to develop a culture which carefully balanced the open-source innovative nature of iGEM. With enough research, informational interviews, and inspiration from iGEM EPIC, we were able to justify the creation. At the time of a global pandemic and national public health crisis, we craved to be even more intentional about our work than before, and entrepreneurship offered the perfect opportunity to ignite this passion.
Our Journey with IP Protection
Questions about what constitutes a public disclosure first arose in conversation between the wet lab and human practices committees. Bridging the gap between our team, the university, and the Charlottesville (Cville) community required openly sharing our thoughts and ideas to seek expertise and collaboration on Manifold. However, we had to be aware of the implications that public disclosures would pose if we had any plans on commercializing our foundational advance in the future. Our lack of expertise in the space in combination with our curiosity to learn more led to our reaching out to lawyers at Cville BioHub—Cville’s diverse biotech center.
Nikki Hastings, the Executive Director of Cville BioHub, was fundamental in helping the team understand how to become better connected with the Charlottesville community while simultaneously protecting our technology, while lawyers David Vance and Rahul Keshap helped us to navigate startup law.
Mr. Vance helped us to understand the ins and outs patent filing logistics. He shared his expertise about biotech startups and gave us some key insight into the startup landscape in Cville and iGEM. Insights gathered included:
- A public disclosure constitutes any non-confidential disclosure of our idea or invention in a public environment. This meant one-on-one Zoom calls with experts and mentors would not be an issue, but it would be smart on our part to file for a Provisional Patent Application (PPA) a few weeks before the iGEM wiki freeze
- Can we write the PPA ourselves? Absolutely! We should draw thorough diagrams illustrating our invention and learn from previous biotech parents to map out our PPA. We should also refer to the official Manual of Patent Examining Procedure to ensure our work is lawful
Mr. Vance enabled us to take charge of our own IP protection and we could not have done so without his help.
Mr. Keshap, on the other hand, was important in helping us to understand corporate law. He gave us great advice on how to run a team like a business, and consider the future impact of the decisions we made. Insights included:
- It is important to clearly define leadership roles within the team-- team members wear multiple hats in a startup, but the ultimate responsibility must belong to someone to get the work done
- Vested equity is a technique where equity is ‘vested’ or secured over time-- this way, teammates will have to earn their equity over time by adding evident value to the team
- We must be smart about our decision making and constantly consider the implications of our decisions. For example, if we file our PPA before the wiki, is 9 months long enough to secure a proof-of-concept? We had to have a plan 9 months ahead of time, and consult with various experts in synthetic biology and startup law to make an informed decision. This also meant considering bioethics-- understanding the good and bad impacts of our device on the end-user-- which led to the publishing of our Code of Ethical Conduct by human practices.
- Maintain touch with your stakeholders and constantly networking is integral to keeping our creativity sharp and our opportunities open.
Thanks to Nikki, David, and Rahul, we learned a lot about what it takes to go from a competitive iGEM team idea to a startup. Putting their advice into practice, we were able to have our PPA reviewed by Mr. Vance, and by the end of September, our PPA was accepted by the USPTO.
Industry Research
Industry research was an integral component in contextualizing the use and applications of Manifold. The chemical manufacturing industry is one of the biggest in the world, producing over $5 trillion worth of chemicals per year. It is a mature market that grows on par with the world economy, at an annual rate of 3%. The key players are established companies from around the world, including DowDuPont in the US; BASF, Evonik and Bayer in Germany; Sinopec in China; Sumitomo, Mitsui, Nippon Kayaku and Mitsubishi in Japan; LG Chem in Korea; and DSM in the Netherlands. The market comprises four subsegments that overlap to differing degrees - diversified chemicals, fine chemicals, specialty chemicals and commodity chemicals
[1]Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].
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Consolidation within the industry, caused by subpar market expansion and increased globalization, has led to less competition and fewer rivals being able to gain market share from the chemical titans previously mentioned. As key players in the chemical industry continue to innovate, synthetic biology is quickly becoming a go-to for solutions aimed at lowering costs and synthesizing novel products. Many synthetic biology companies are already leading the charge; Amyris has engineered yeast to produce the antimalarial Artemenisin, Geltor is using synthetic biology to produce collagen substitutes, Biossance is biochemically synthesizing squalane, Evolva is producing nootkatone via fermentation, Conagen is using bacteria to produce vanillin, Antheia is biosynthetically manufacturing opioids with yeast, and Renew is using microbes to produce cannabinoids
[2]“Synthetic biology is shaking up these 5 industries-Some of them might surprise you - SynBioBeta,” Synbiobeta.com, 11-Feb-2020. [Online]. Available: https://synbiobeta.com/synthetic-biology-is-shaking-up-these-5-industries-some-of-them-might-surprise-you/. [Accessed: 27-Oct-2020].
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We, Virginia iGEM, are in the early stages of a paradigm shift towards a sustainable economy, and interest in green chemicals has never been as strong as it is now. Whether this continued push comes from companys’ own initiatives or from government subsidies, a move away from environmentally damaging catalysts and energy intensive reaction conditions is widely regarded as essential
[1]Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].
.
Capital intensity poses a threat to the manufacturing industry. Manufacturers have to analyze long term demand-trends to decide whether to expand or shut down large plants, which can often leave them vulnerable due to short term market volatility. The advantage of synthetic biology is that biosynthetic processes can be scaled up or down with unprecedented ease, allowing for more motility. Another advantage is that biochemical plants can be placed near feedstocks or end-markets, reducing transportation costs and turnaround times
[1]Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].
.
The synthetic biology industry’s rapid expansion has been forecasted by many established financial companies and economic institutions. McKinsey and Company, a global consulting firm, recently reported that biological approaches could end up producing 60% of physical inputs to the world economy
[3] Innovations transforming economies and O. Lives, “The Bio Revolution,” Mckinsey.com. [Online]. Available: https://www.mckinsey.com/~/media/McKinsey/Industries/Pharmaceuticals%20and%20Medical%20Products/Our%20Insights/The%20Bio%20Revolution%20Innovations%20transforming%20economies%20societies%20and%20our%20lives/May_2020_MGI_Bio_Revolution_Report.pdf. [Accessed: 27-Oct-2020].
. Boston Consulting Group predicted the synthetic biology industry to grow at an annual rate of 34% from $6 billion in 2018 to $20 billion in 2022 [4]M. Portincaso, A. Gourévitch, S. Gross-Selbeck, and T. Reichert, “How Deep Tech Can Help Shape the New Reality,” BCG Global, 21-Jul-2020. [Online]. Available: https://www.bcg.com/publications/2020/how-deep-tech-can-shape-post-covid-reality. [Accessed: 27-Oct-2020]
. A report published by the European Commission suggested that biotechnological approaches could replace 30% of petroleum derived products in the EU by 2030 [5]Nature News. [Online]. Available: https://www.nature.com/articles/d42473-020-00220-x. [Accessed: 27-Oct-2020].
. The Organization of Economic Development published a report in 2009, named “The Bioeconomy to 2030”, that estimated the bioeconomy market at $1.6 trillion by the end of the decade. The report also stated that 39% of the bioeconomy would consist of using smart cells for industrial production of sustainable biomaterials such as PET bottles, synthetic rubber, dietary supplements, cosmetics and others [6]M. Samejima and A. Attorney, “Efforts Towards Open Innovation,” Nedo.go.jp. [Online]. Available: https://www.nedo.go.jp/content/100889935.pdf. [Accessed: 27-Oct-2020].
.
Market Research
We then decided to narrow down the scope of our research to the market we would first be targeting. The market size for resveratrol was about $62 million in 2017, and is expected to grow to around $140 million by 2026 with a forecasted compound annual growth rate of 9.7%
[7]C. M. Insights, “Resveratrol Market to Surpass US$ 159.1 Million by 2026 – Coherent Market Insights,” GlobeNewswire News Room, 21-Nov-2018. [Online]. Available: https://www.globenewswire.com/news-release/2018/11/21/1655234/0/en/Resveratrol-Market-to-Surpass-US-159-1-Million-by-2026-Coherent-Market-Insights.html. [Accessed: 27-Oct-2020]
. China is the largest manufacturer of resveratrol, followed by Europe, while North America is the largest consumer. The majority of resveratrol production in Europe comes in the form of grape skin extract, while the Chinese market focuses on knotweed extraction. These extraction processes utilize many environmentally harmful chemicals, such as methanol, ethanol, hydrochloric acid and methyl tert butyl ether [8]A. I. Romero-Pérez, R. M. Lamuela-Raventós, C. Andrés-Lacueva, and M. C. de La Torre-Boronat, “Method for the quantitative extraction of resveratrol and piceid isomers in grape berry skins. Effect of powdery mildew on the stilbene content,” J. Agric. Food Chem., vol. 49, no. 1, pp. 210–215, 2001.
, [9]D.-G. Wang, W.-Y. Liu, and G.-T. Chen, “A simple method for the isolation and purification of resveratrol from Polygonum cuspidatum,” Journal of Pharmaceutical Analysis, 10-Dec-2012. [Online]. Available: https://www.sciencedirect.com/science/article/pii/S2095177912001426. [Accessed: 27-Oct-2020]
. The main companies comprising 80% of the resveratrol market are: DSM, Evolva, Sabinsa, InterHealth, Maypro, Laurus Labs, JF-NATURAL, Great Forest Biomedical, Shaanxi Ciyuan Biotech, Chengdu Yazhong, Changsha Huir Biological-tech, Xi'an Gaoyuan Bio-Chem and Xi'an [10]“Resveratrol Market size 2020 industry share, demand, top players, industry size, future growth by 2026,” MarketWatch, 19-Oct-2020. [Online]. Available: https://www.marketwatch.com/press-release/resveratrol-market-size-2020-industry-share-demand-top-players-industry-size-future-growth-by-2026-2020-10-18. [Accessed: 27-Oct-2020].
.
Our team reached out to each individual manufacturer listed above, however we were not able to identify a production cost for extracted resveratrol, due to exact numbers being guarded as trade secrets. According to Sigma Aldrich, the bulk price of p-coumaric acid— the main substrate in the resveratrol pathway— is $0.004 per mg, while that of trans-resveratrol— our product— is around $0.80 per mg. The 200-fold increase in price is a promising metric for understanding the economic viability of our product, because once our system is optimized it is expected to produce a 1:1 conversion between the two molecules.
In chapter 5 of ‘Peanuts: Processing Technology and Product Development’ (2016), published by the Institute of Food Science and Technology at the Chinese Academy of Agricultural Sciences in Beijing, the price for a kilogram of 95%+ pure resveratrol is stated as being between 8,000-10,000$US. If our system was able to reach near perfect yields and we simply purchased p-coumaric acid in bulk from Sigma-Aldrich, then it would be able to produce a kilogram of pure resveratrol for half the price - around $4,000. The chapter also indicated that global resveratrol production in 2016 was at 50-60 tonnes, while the demand for the same time period was over 100 tonnes, underlining the great future prospects for the resveratrol market and the possibility for new manufacturers to enter the market
[11]Q. Wang et al., “Peanut by-products utilization technology,” in Peanuts: Processing Technology and Product Development, Elsevier, 2016, pp. 211–325.
.
After having spoken to the CEO of RevGenetics, another prominent distributor in North America, the team was left with an understanding that there is still a slight stigma around synthetic resveratrol. However, the sentiment is slowly shifting after it has been found that herbicides, pesticides, heavy metals and emodin are present in many extracted resveratrol products, especially those coming from China. Evolva is currently using yeast fermentation to make its signature Veri-te™ resveratrol, touting high purity and consistent batch production. DSM has patented a chemical process that allows it to make its resVida™ resveratrol from 1-(3,5-diacetoxyphenyl)-bromoethane. Ultimately, the sustainable advantages presented by our biosynthetic solution to drug, specifically resveratrol, production evidences its utility as a more environmentally-friendly and cost-effective means of synthesis.
Future Routes
To further our vision, our team came up with an all-encompassing business plan to map out the steps required to establish a start-up. Everything hinges on verifiable lab results that can be used to establish a proof-of-concept and support claims on the Nonprovisional Patent.
- File Provisional Patent Application (PPA) through the USPTO (completed)
- Secure filing date for Provisional Patent (completed)
- Produce lab results for proof-of-concept
- Incorporate LLC in Delaware
- Shareholders Agreement
- Foreign Qualification to operate in VA
- Federal Tax Number
- Agreement for transfer of IP ownership to LLC
- Submit Project Proposal for NSF SBIR grant
- Find lab space
- Reach out to biotech companies in the Charlottesville area
- Negotiate with the University
- Submit NSF SBIR Full Grant Application
- Produce lab results for claims in Nonprovisional patent
- Submit Nonprovisional patent
- Find investors or look into an incubator
- Charlottesville Angel Network
- Y-Combinator
Once the team has a finished product, it would reach out to resveratrol suppliers to request information on their wholesale purchase costs. Manifold's business strategy would then vary based on responses. Either Manifold could become a chemical manufacturer itself and create its own distribution network, or it could license out the technology to the largest manufacturers. If the team were to move forward with the former route, then many up front costs would have to be taken care of. Permanent lab space, bioreactors, and purification machinery would all have to be purchased or leased. Transportation costs would also have to be taken into consideration.
Breaking into the resveratrol industry is, however, not the main goal of the project. Manufacturing resveratrol or licensing Manifold is primarily for generating initial revenues that can bolster investor confidence and allow for expansion of the company, in addition to providing the foundation for other high-demand drug production. We strongly believe that Manifold could become a plug-and-play system for biosynthetically manufacturing a cornucopia of different chemicals. All that would be required is to change the sequence relating to the enzyme attached to the DNA scaffolds and our modified BMCs could house a huge variety of different pathways. A limitation to be noted is that precursors for encapsulated pathways need to be small enough to enter through the BMC’s pores. Some biochemical pathways the team could work to integrate into the Manifold system are nootkatone, which is derived from acetyl-CoA, and vanillin, which is derived from p-coumaric acid and was extensively researched by the 2013 UBC team
[12]“Team:British Columbia/project/vanillin - 2013.Igem.Org,” Igem.org. [Online]. Available: https://2013.igem.org/Team:British_Columbia/Project/Vanillin. [Accessed: 27-Oct-2020].
. The pathway for squalene also seems to lend itself to the Manifold system. By selecting these chemicals, the team hopes to gain interest from synthetic biology companies such as Biossance, Evolva and Conagen. References
[1] Synbiobeta.com. [Online]. Available: https://synbiobeta.com/wp-content/uploads/2018/11/Synbiobeta_Report_8.22.18_Chemicals_v3.pdf. [Accessed: 27-Oct-2020].
[2] “Synthetic biology is shaking up these 5 industries-Some of them might surprise you - SynBioBeta,” Synbiobeta.com, 11-Feb-2020. [Online]. Available: https://synbiobeta.com/synthetic-biology-is-shaking-up-these-5-industries-some-of-them-might-surprise-you/. [Accessed: 27-Oct-2020].
[3] Innovations transforming economies and O. Lives, “The Bio Revolution,” Mckinsey.com. [Online]. Available: https://www.mckinsey.com/~/media/McKinsey/Industries/Pharmaceuticals%20and%20Medical%20Products/Our%20Insights/The%20Bio%20Revolution%20Innovations%20transforming%20economies%20societies%20and%20our%20lives/May_2020_MGI_Bio_Revolution_Report.pdf. [Accessed: 27-Oct-2020].
[4] M. Portincaso, A. Gourévitch, S. Gross-Selbeck, and T. Reichert, “How Deep Tech Can Help Shape the New Reality,” BCG Global, 21-Jul-2020. [Online]. Available: https://www.bcg.com/publications/2020/how-deep-tech-can-shape-post-covid-reality. [Accessed: 27-Oct-2020]
[5] Nature News. [Online]. Available: https://www.nature.com/articles/d42473-020-00220-x. [Accessed: 27-Oct-2020].
[6] M. Samejima and A. Attorney, “Efforts Towards Open Innovation,” Nedo.go.jp. [Online]. Available: https://www.nedo.go.jp/content/100889935.pdf. [Accessed: 27-Oct-2020].
[7] C. M. Insights, “Resveratrol Market to Surpass US$ 159.1 Million by 2026 – Coherent Market Insights,” GlobeNewswire News Room, 21-Nov-2018. [Online]. Available: https://www.globenewswire.com/news-release/2018/11/21/1655234/0/en/Resveratrol-Market-to-Surpass-US-159-1-Million-by-2026-Coherent-Market-Insights.html. [Accessed: 27-Oct-2020]
[8] A. I. Romero-Pérez, R. M. Lamuela-Raventós, C. Andrés-Lacueva, and M. C. de La Torre-Boronat, “Method for the quantitative extraction of resveratrol and piceid isomers in grape berry skins. Effect of powdery mildew on the stilbene content,” J. Agric. Food Chem., vol. 49, no. 1, pp. 210–215, 2001.
[9] D.-G. Wang, W.-Y. Liu, and G.-T. Chen, “A simple method for the isolation and purification of resveratrol from Polygonum cuspidatum,” Journal of Pharmaceutical Analysis, 10-Dec-2012. [Online]. Available: https://www.sciencedirect.com/science/article/pii/S2095177912001426. [Accessed: 27-Oct-2020]
[10] “Resveratrol Market size 2020 industry share, demand, top players, industry size, future growth by 2026,” MarketWatch, 19-Oct-2020. [Online]. Available: https://www.marketwatch.com/press-release/resveratrol-market-size-2020-industry-share-demand-top-players-industry-size-future-growth-by-2026-2020-10-18. [Accessed: 27-Oct-2020].
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