Just a few weeks ago, we introduced you to our new quotes with line items. There has already been another exciting development for the site and we want to share that with you as well!
Lab-Initiated Quotes, or LIQs (“licks”) as we affectionately call them, are a way for any lab to begin their interaction with a researcher by sending a quote directly to them, whether they are already on Science Exchange or not. Some terrific applications for LIQs are in cases when you’ve been discussing the scope of work with a researcher over email or the phone and want to send them a quick quote so they can accept and get the ball rolling on the project as soon as possible. Read the rest of this entry »
Ben Woodard (right) Director of the Biotech Research and Education Program.
I recently spoke with Ben Woodard, Director of the Bioprocess Scale-Up Facility on Science Exchange. They help take research to the next level, literally. They scale up existing scientific procedures to make them ready for commercial production. Check out more on their interesting and unique niche below!
Q: What is your role with BREP?
Ben: I’m the Director of the Biotechnology Research and Education program (BREP) at the University of Maryland. The program encompasses two core facilities including the Bioprocess Scale-Up Facility that focuses on yeast and bacteria processes and the Biopharmaceuticals Advancement Facility that focuses on adherent or suspension-adapted cell lines such as HEK293, CHO, Sf9, NSO, and MSCs.
Q: How did the Program come into existence?
Ben: The program began with just the Scale-Up Facility. In 1985 the University and my department, then The Engineering Research Center, felt that there was a need for a laboratory that would enable collaborative research between academics and industry.
The faculty had great ideas, but they didn’t know how to commercialize them, they didn’t know how to take a product to market. The industry had challenges with their processes that needed the expertise of the academics. So the Facility was created to link these two groups together. When it began in ‘85 it was one of the only contract research facilities on the East Coast, it was pretty novel at the time.
We were created to spark economic development for the State while providing small start-ups, faculty researchers, and student researchers with a knowledge base that would help them create novel and new technologies. Ultimately trying foster growth in the Maryland biotech sector.
Q: What are the most popular experiments?
Ben: Cell culture and fermentation projects, protein expression and purification. We specialize in taking a cell line that’s been modified and scaling up its production for pre-clinical research. Additionally, we have fantastic training and workforce development program that has trained over 200 technicians and researchers for the biotech industry.
Q: What are some of the major projects you worked on?
Ben: A major success was a product called Synagis, a top selling biopharmaceutical. It’s used to treat respiratory syncytial virus, a virus that prevents proper lung development in premature babies.
A second major project was our work with Martek and their product LifesDHA. It’s a fatty acid that’s been linked to brain and eye development in children. DHA is naturally found in breast milk, but Martek, with the help of our facility, was able to optimize its production in algae. Just about every child in North America under the age of 14 has consumed their product.
Our service isn’t to identify proteins or antibodies such as these, it’s to provide research, optimization, scale-up, and the like, to support the efforts of the biotech community. We provide services that are crucial to the long term growth of a biotech product.
A parallel would be if you make a Duncan Heinz cake for your office. You get an egg, you mix it up with the mix and a little oil, bake it and you can feed 5 or 6 people. Now make that cake and feed the entire Northern hemisphere. Do you add 1 million times more eggs? Bake at a different temperature? You can’t just multiply the number of eggs by the anticipated number of servings. You have to change variables such as temperature, the size of the pan, and the ratio of oil to mix, in order for the cake to bake correctly.
Now for us, a researcher or clinician may have an idea that they’ve researched in small scale and found they can produce a small amount, a few milligrams of a protein or antibody, perhaps enough to treat a mouse. Now how do you scale-up that product to treat 4 or 5 million people? That’s where we come in.
Our mission is three-fold: do contract service work, help workforce development, and support education and research opportunities for undergraduate students.
Q: How did you end up working there?
Ben: I started as an undergraduate student in 1994 in the fermentation facility. I was working on workforce development project for MedImmune, training over 100 of their employees, and I really enjoyed the work in and the interaction with other. I’ve been involved with the BREP since.
Q: How has your experience been using Science Exchange?
Ben: It’s been great. It’s been a unique opportunity to expand our reach outside Maryland. Being a state university we don’t spend a lot of money on marketing, but with Science Exchange we can utilize equipment that’s normally stagnant. Science Exchange allows researchers from other institutions to access equipment that would’ve been idle. Working with Science Exchange has really been a great source of opportunities for us to make our equipment operate at a higher volume.
Check out more on the Bioprocess Scale-Up Facility at their Science Exchange storefront.
About the author
Tess Mayall builds Science Exchange’s online and offline community of scientists and providers. She is a geologist by training, but considers herself a friend of scientists near and far.
This has been an incredible year for Science Exchange. Our team has grown and our site is continually improving based on feedback we receive every day from researchers and lab admins alike.
Our newest feature was one of the most commonly requested from the lab admins on our site. It began as a discussion with the Lab Advisory Board – the LAB for short.
Previously, lab admins were able to submit text in a large description box, upload any pertinent files (like their institution quotes that included line items), and a price for the project. So in order to make the quoting process more flexible and intuitive, we’ve built line items into our existing quote system.
Labs are now able to generate their own line items within Science Exchange!
Read the rest of this entry »
BioSynthetic Artificial Cornea of Eyegenix LLC.
Derek Duan is a Principal Investigator at Eyegenix, a small biotech in Hawaii that is creating a unique way to cure corneal blindness.
How are they doing it? By creating a synthetic, transplantable cornea that promotes tissue regeneration.
I spoke with Derek about their novel approach to curing blindness, the biotech scene in Hawaii, and his experience using Science Exchange. Check out our conversation below.
Q: Tell me about Eyegenix.
Derek: We’re a biotech company located in Honolulu, Hawaii. We’re doing research and development on the most advanced artificial cornea in the world. This is a biosynthetic polymer based product.
We’re very excited to put our artificial corneas into the market as soon as possible, because there are millions of people globally that could be cured with this product.
Q: How did the company start?
Derek: Dr. Hank C.K. Wuh, who was born in Hawaii and educated in the mainland, founded the company in 2012. He wanted to come back and serve Hawaii. He’s making use of the island as an intersection of Asia, Australia and America to be a center for biotech research. That’s why he decided to come back and fund his company. Read the rest of this entry »
Zhiyong Wang in the lab at ADS Biosystems.
I recently talked with Zhiyong Wang Ph.D, CEO of ADS Biosystems Inc. ADS Biosystems specializes in cell-based assay development. In particular, Zhiyong applies his experience and expertise from the renowned Hunter Lab at the Salk Institute to develop assays with brown and white fat, routine human cell lines, human adult stem cells, and rodent cochlea.
Check out more on his background and inspiration below.
Q: What were you doing before you started ADS Biosystems?
Zhiyong: From 2002 – 2009, I was a research associate in the Hunter Lab at the Salk Institute. The lab is fantastic and everyone enjoys developing and working on their own projects. It’s a great environment with diverse expertise and collaborative spirits. Tony encourages people to be independent and explore what inspires them. Tony co-founded the Signal Pharmaceutical Inc., which is now part of Celgene Corp. Therefore, it is not surprising that a few people from his lab have started their own companies.
I was researching metabolism, obesity, and diabetics with mouse genetic models, and discovered crucial roles of transcriptional master regulators in obesity and glucose resistance. I was fascinated with fat cells (adipocytes) in particular.
That was the reason why I was recruited to a local stem cell company that planned to build a brown fat program from scratch. At that time, there were exciting discoveries that adult humans have brown fat, which burns energy and may be used to combat obesity and diabetes. I was really excited about the project and enjoyed building the brown fat program from the ground up. I discovered a family of small molecule compounds that induced brown fat formation from human adult stem cells. I also developed a platform to discover novels compounds, which induce brown fat formation in obese patients to burn extra energy.
Another project at my previous company started with a Department of Defense (DOD) grant. As you know, some of our soldiers at Afghanistan and Iraq experienced battlefield noises and lost their hearing. We wanted to restore their hearing by stimulating stem cells in cochlea to regenerate inner ear hair cells, which are responsible for sound wave sensing. As the lead scientist for the project, I developed cochlear organ culture-based assays to identify candidate compounds, which induce hair cell regeneration. Our hearing team was great in that we really enjoyed working together and we were very productive: we generated two patents for the compounds of hearing restoration and discovered a novel pathway critical for inner ear hair cell regeneration. Read the rest of this entry »
At Science Exchange, we believe that collaboration is the future of science. In fact, we created Science Exchange to help scientists access top equipment and expertise to simplify their collaborations.
We wanted to learn how scientists are currently working with their peers, so we surveyed over 1500 scientists about their collaborations. Check out our infographic below which summarizes the enlightening data on the state of collaboration.
Check out 2000+ experiments you can order on Science Exchange here.
Use the code below to embed this infographic:
Hannah Margolis prepping yeast cells for her project at Elko High School.
Recently I interviewed an extremely unique Science Exchange user, Hannah Margolis. Hannah is a high school student studying the effect of stress on Sirtuin 2 proteins, which play a role in aging. Hannah won first place at the Elko County Science Fair and competed at Intel International’s National Science and Engineering Fair!
When I talked to Hannah, I was absolutely awestruck by her intelligence, initiative, and passion for knowledge. Check out how she approached this research problem below.
Q: How did you get the idea to look into the effect of stress?
Hannah: Last year I did a physics project, which involved blowing stuff up with alpha particles. When that was over I was looking into cosmic rays, but I found out you can’t do anything cool with cosmic rays. However, while I was looking into it I learned that people who are exposed to more cosmic rays are reported to live longer. That led to this idea called radiation hormesis – the idea that low amounts of radiation are good for you. I thought that was really weird.
I kept looking into it, and I found that any type of stress is supposed to reduce your chance of getting cancer and getting sick. It sounds great, but nobody uses it because we don’t know how it works. It’s a little bit scary to tell people to go subject themselves to low amounts of radiation – people wouldn’t do that. I wanted to try to figure out why it works, so we can someday implement it in society, because it’s a great proactive treatment. Read the rest of this entry »
The Science Exchange team (May 2014).
Another few months, another exciting update on our ever-expanding team. As always, I’m thrilled to introduce you to our freshest and possibly most diverse new hires at Science Exchange.
Our new hires represent something we value deeply at Science Exchange – curiosity. They come from varied backgrounds and are in varied roles, but the commonality between them all is a drive to learn.
Meet the new members of our Science Exchange team below:
- Ana Ulin’s resume would knock anyone’s socks off – she’s an electrical engineer who spent the last 8 years developing products at Google. During her time, she brought products that we all use like Google Maps and Google+ to the public, but what’s perhaps most impressive is that she learned to program by turning in handwritten coding assignments to her father starting at 7 years old! She’s truly a lifelong learner. She hit the ground running in our development team by immediately streamlining business operations with code and was awarded our FORCE award within 90 days.
- Mennah Moustafa joins our Business Development team from Sigma-Aldrich where she lead their North American strategic sales over the course of ten years. It was love at first lunch when she interviewed, and she has quickly immersed herself in all things Science Exchange since joining. She is a unique blend of smiley, inquisitive, and strategic. These traits meant that she was digesting Science Exchange materials and creating new presentations during her first week and doing headstands to boot!
- Charlotte Arthun joined us a few months ago as our Operations Manager. In addition to the game-changing efficiency she has brought to the office, Charlotte has instilled a passion for nature and zoology into our office environment. After her undergrad in biology, she spent years working as a field ecologist around the world – studying large cats like jaguars and pumas. Even now she exercises her curiosity by surveying river otters in the North Bay on weekends!
- Michael Benzinou’s background is one-of-a-kind: academic, strategic, and entrepreneurial. In addition to his PhD in Molecular Biology, he lead business development at Crown Bioscience and recently took part in Lean Launchpad where he developed a way to match CRO’s with R&D projects. He is a key member of our Business Development team who has utilized his diverse background to create an exciting bench sharing initiative (more details soon) and work on our Reproducibility Project: Cancer Biology. He is also one of the tallest and wittiest French men you will ever meet.
I hope you all have enjoyed reading about our new additions as much as I enjoy working with them. We are still hiring for more jobs, check out our open positions here.
About the author
Dan Knox is a Co-Founder of Science Exchange. Dan helped create the initial version of Science Exchange and led the company’s successful seed and Series A fundraising efforts. Now, he looks after finance, legal, HR, and operations (and even commits the occasional line of code). Dan has MSc. in Economics from City University (London) and an MBA from the Massachusetts Institute of Technology Sloan School of Management.
Gordon Hardy in the lab at Hunt Imaging.
For this week’s story I spoke with Gordon Hardy who works on something most of us don’t think about very often – developing new inks and toners. More specifically, he is creating a new ink to print the small numbers on the bottom of checks. The problem is complex and interesting, check out his story below.
Q: What’s your role at Hunt Imaging?
Gordon: Mostly formulation and material analysis, but even customer support. It’s a small company, so you really have to do everything
Q: What did you use Science Exchange for?
Gordon: It’s an inkjet project. We have expertise in magnetic ink character recognition (MICR) ink here. It’s those funny looking characters that are printed on the bottom of checks. Those are read magnetically, so the ink itself has magnetic particles embedded in it. MICR toners are well established and with the current growth in high speed production inkjet printers there is a need for MICR inkjet, but it’s not an easy thing to create because you are trying to make iron float in water.
You can do it if you make the iron small enough, but if you make it too small it loses its magnetic strength. The problem is, you make it smaller and smaller and it gets less and less magnetic. So you have to make a different type of magnet, that’s not just iron, but something that’s a little stronger. You need to make them on the order of twenty nanometers; that’s what we’re working on now.
The particle size and even the particle shape is important. For our project on Science Exchange, the Nano Research Facility conducted TEM to look at the size and shape of the iron and other oxide particles we’ve generated. Read the rest of this entry »
I’m excited to announce that top scientific suppliers BioLegend, Charles River Laboratories, Corning Incorporated, DDC Medical, EMD Millipore, Harlan Laboratories, LI-COR Biosciences, Mirus Bio, Novus Biologicals, and Sigma-Aldrich will provide more than $500,000 worth of research reagents and models to support one of our validation projects, the Reproducibility Project: Cancer Biology. The donation of reagents and models will increase the number of replication experiments that can be conducted for the Reproducibility Project: Cancer Biology, a collaboration between Science Exchange and the Center for Open Science, supported by a $1.3 million grant from the Laura and John Arnold Foundation.
These companies chose to donate to the project, because they are committed to improving the quality of research and we are thrilled to have their support!
The Reproducibility Project: Cancer Biology is independently replicating 50 recent, high-impact cancer biology studies using the Science Exchange network of expert labs. The aim of the project is to use independent replication studies to identify best practices that maximize reproducibility and facilitate an accurate accumulation of knowledge, enabling potentially impactful novel findings to be built upon by the scientific community.
Studies from Amgen and Bayer report that the majority of published results cannot be independently reproduced, but there has been no open systematic review of replication in cancer biology. The Reproducibility Project: Cancer Biology will generate an open replication dataset made available on the Open Science Framework that can be used to examine the rate of reproducibility in this field and to study factors associated with the reproducibility of experimental results.
We continue to be amazed by the wide-ranging support for this project from the scientific community – thank you so much!
Of course, the more scientific supplies that are donated the more we can get done, so if you are involved with a company that is interested in donating please email me here.
About the author
Elizabeth Iorns is the CEO of Science Exchange and Director of the Reproducibility Initiative. Elizabeth conceived the idea for Science Exchange while an Assistant Professor at the University of Miami and as CEO she drives the company’s vision, strategy and growth. She is passionate about creating a new way to foster scientific collaboration that will break down existing silos, democratize access to scientific expertise and accelerate the speed of scientific discovery. Elizabeth has a Ph.D. in Cancer Biology from the Institute of Cancer Research in London, and conducted postdoctoral research in Cancer Biology from the University of Miami’s Miller School of Medicine where her research focused on identifying mechanisms of breast cancer development and progression.