Team:Yale/Outreach
From 2014.igem.org
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- | <p align="center"><strong>"Many large companies suffer from, "Not Invented Here" bias, but as a small company, you need to put your ego to the side and lead the team to the best solution."</strong> | + | <p align="center" style = "padding:10px"><strong>"Many large companies suffer from, "Not Invented Here" bias, but as a small company, you need to put your ego to the side and lead the team to the best solution."</strong> |
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- | Startups are brutal. You can't spend all of your money on lawyers and attorneys. You really have to make yourself an expert. You need to know the science, and you can't afford to have consultants do all of the work for you, so you need to do most of the legwork. | + | <strong>CL: </strong>Startups are brutal. You can't spend all of your money on lawyers and attorneys. You really have to make yourself an expert. You need to know the science, and you can't afford to have consultants do all of the work for you, so you need to do most of the legwork. |
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- | When I was the Chief Technology Officer, I was doing all of the pitches as well as managing the Intellectual Property portfolio. </p> | + | <strong>CL: </strong>When I was the Chief Technology Officer, I was doing all of the pitches as well as managing the Intellectual Property portfolio. </p> |
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I spent a year understanding 500-1000 papers or patents in the field, and we had to identify key differences between their ideas and ours. The space is busy, but then again most valuable spaces are busy and it is the entrepreneurs responsibility to carve out their space. | I spent a year understanding 500-1000 papers or patents in the field, and we had to identify key differences between their ideas and ours. The space is busy, but then again most valuable spaces are busy and it is the entrepreneurs responsibility to carve out their space. | ||
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- | To start off, you should think about peptides or proteins that are bigger than what is chemically synthesizable. What would be cool to make a surface for? What could you want to do with a protein bound to a surface? But you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction. | + | <strong>CL: </strong>To start off, you should think about peptides or proteins that are bigger than what is chemically synthesizable. What would be cool to make a surface for? What could you want to do with a protein bound to a surface? But you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction. |
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- | <p align = "center"><strong>"...you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction."</strong></p> | + | <p align = "center" style = "padding:10px"><strong>"...you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction."</strong></p> |
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The first thing my cofounder did was drag me to the hospital and get me to start talking to the nurses. I had to become an investigative reporter, an engineer asking questions. But I had to do it, because often the unmet need is outside your area of expertise. | The first thing my cofounder did was drag me to the hospital and get me to start talking to the nurses. I had to become an investigative reporter, an engineer asking questions. But I had to do it, because often the unmet need is outside your area of expertise. |
Revision as of 19:34, 17 October 2014
Outreach |
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Exploring the Potential Impact of AMPs in the Shipping Industry | |||
Over the summer, Yale iGEM member Cathy Ren interviewed Mr. James S.C. Tai, Technical Director and General Manager of Fleet Management Department, Orion Overseas Container Line Limited (OOCL). We asked about the importance of biofouling in the shipping industry and the possible application of our antimicrobial coating.
CR: What is biofouling and why does it matter to OOCL?
CR: What are the anti-fouling methods that OOCL employs?
CR: What are some other methods for preventing biofouling that are currently being explored?
CR: Yale iGEM is currently trying to produce an anti-microbial protein that could be used in the field of anti-fouling. What are some things we should consider with our approach?
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Blending Research and Entrepreneurship in Medical Devices | |||
Yale iGEM Interviewed Dr. Christopher Loose, co-founder of Semprus Biosciences, on entrepreneurship and using research to address unmet needs in medicine. Dr. Loose co-founded Semprus BioSciences, a company focused on anti-fouling on medical devices, with MIT professor Robert Langer and David Lucchino in 2006. He served as CTO until the company was acquired by Teleflex Incorporated in 2012. He currently serves as Executive Director of the Yale Center for Biomedical and Interventional Technology (CBIT) and as Assistant Professor Adjunct, Urology and Lecturer, Biomedical Engineering and Lecturer School of Managment.
iGEM: As someone with extensive experience using anti-microbial peptides to target industry needs, what are some challenges with bringing an AMP-based solution to market? CL: First, a lot of work has been done in this area. This means there are many papers and patents on attaching AmPs to surfaces. Two additional challenges are costs and FDA regulations. Another issue is the stability of your material, both for shipping and application. We founded SteriCoat (now Semprus BioSciences) to explore the biomedical applications of AMPs. We were thinking we could coat devices covalently with AMPS, and reduce risk for catheter infections. However, we ended up turning to a totally different technological solution. The regulatory path drives a great deal of your timeline, risk, and funding requirements. Incorporating an agent that the FDA may consider an active agent would raise the burden for the company. Whether or not this decision is made by the FDA or whether or not this is the correct decision, this raises your risk. We pursued a totally synthetic chemistry that was less likely to be viewed as "active". We had overcome many challenges with the AMPs themselves along the way. My PhD project was AMP design and application. We initially were looking at creating in vitro translation systems to avoid killing cells. I worked in a metabolic engineering lab, and we did microbial screens too. Early in my PhD years, we had a computational tool for AMP design, and we wanted to screen a bunch of them. The problem is that it kills off your bugs. Can you grow it with an inactive form, or use an excretion tag? Can we use a bug that isn't targeted by the AMP? The cleverest thing we found was designing them to be expressed with an inducer. We used parallel stamps, one with an inducer, one without, and we looked at the zone of inhibition. Basically, we used replica plating to identify the most efficient producers of AMP. Then, chemical synthesis of AMPs became really inexpensive! You could look into proteins that are difficult to synthesize in-vitro, for example defensins, and there are databases of these. iGEM: How did you decide to become an entrepreneur? CL: I came into grad school wanting to do something entrepreneurial in the Langer lab and really make something happen. What really got me going was when we started to get good results, Langer put me in touch with David Lucchino at the Sloan school, and we created a business plan that won competitions at MIT, Harvard, Oxford, Cambridge, and other universities. We started gaining momentum, and things got very interesting. When you're an entrepreneur, you're also a fund raiser, a writer, and a team leader, regardless of the academic field or industry. Of course its risky, but everything's risky. In the end, you get the skills that will make you flexible and valuable regardless of what you achieve. We thought about applications as diverse as naval ships, water processing plants, orthopedics, and food safety. A lot of the decision making for our strategy came down to cost and timeline for development, market size and margin for the product, and the duration of stability and activity required in a given application. iGEM: How do you translate cool science into something viable? CL: You have to go from a vision to the unmet need. We eventually licensed a technology I didn't invent, and that's okay. Many large companies suffer from, "Not Invented Here" bias, but as a small company, you need to put your ego to the side and lead the team to the best solution. "Many large companies suffer from, "Not Invented Here" bias, but as a small company, you need to put your ego to the side and lead the team to the best solution." You also have to get technologists to think about the business issues. How does your technology address the business concerns and give you an advantage in the market? You say: This is how we're going to exploit this unmet need through business. Here's the unmet need, here's our solution, here's why we'll be the only ones to produce it, and here's how we're going to execute. As one of my fellow board members said: "I was a scientist and now I'm a businessman." I think academia is about branching out and looking forward, but business is about having a specific target and finding the shortest path. So it's a very different mindset, but the business mentality is a learnable skill. iGEM:Did you consult experts on the non-scientific aspects? CL: Startups are brutal. You can't spend all of your money on lawyers and attorneys. You really have to make yourself an expert. You need to know the science, and you can't afford to have consultants do all of the work for you, so you need to do most of the legwork. Once you generate specific questions, you can get a lot of value from an hour-long meeting with an expert: "here are the critical things I saw, and here's what I'm confused about." That's the best way to be efficient. I got to help do a license, manage IP strategy, and design a clinical trial. There is enormous potential to learn about a wide variety of fields in a new start-up. You don't have to be the expert in each area, but if you can ask the hard questions at the interfaces and can get the right advisers, then you can be a successful leader. iGEM: What about intellectual property issues? CL: When I was the Chief Technology Officer, I was doing all of the pitches as well as managing the Intellectual Property portfolio. I spent a year understanding 500-1000 papers or patents in the field, and we had to identify key differences between their ideas and ours. The space is busy, but then again most valuable spaces are busy and it is the entrepreneurs responsibility to carve out their space. iGEM: Are there other ways to use AMPS? What recommendations would you give to our team going forward? CL: To start off, you should think about peptides or proteins that are bigger than what is chemically synthesizable. What would be cool to make a surface for? What could you want to do with a protein bound to a surface? But you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction. "...you can't just keep brainstorming about the technology, you really need an unmet need to pull you in the right direction." The first thing my cofounder did was drag me to the hospital and get me to start talking to the nurses. I had to become an investigative reporter, an engineer asking questions. But I had to do it, because often the unmet need is outside your area of expertise. I'd also think hard about "why microbial production"? When would your peptides be cheaper? Are they super-complex peptides that you couldn't produce otherwise? Are there powerful ways to use the bacteria as a living system? From a commercial perspective, think really hard about the unmet need that only you can address. | |||
Educating New Generations of Scientists | |||
Yale iGEM member Ariel Hernandez-Leyva delivered a class for local high school students: |