Quick Summary
- Molecular Prototyping and BioInnovation Laboratory provides "makerspace" for biology students
- Lab space for original student projects and innovative teaching
- Three startup companies launched in three years
A “makerspace” for biologists and engineers is helping University of California, Davis, students get hands-on experience in developing and prototyping their ideas. In just a short time, the Molecular Prototyping and BioInnovation Laboratory (MPBIL), or biomaker lab, has generated three student-run startup companies and is providing a new model for education in biology and bioengineering.
“We wanted to create a new type of multiuse space on campus for students interested in hands-on exploration and creative expression in biotechnology, bioengineering and biodesign,” said Marc Facciotti, an associate professor in the Department of Biomedical Engineering and the °ϲĻϢ Davis Genome Center. “We aspire to be a hub for creative expression in biotechnology, a place to host new hands-on courses, a home for student clubs and design teams. We also want to be a nurturing environment for budding entrepreneurs.”
Activities at the lab start with a project goal — a product that must be delivered or question that needs to be answered, Facciotti said.
Fabric From Fermented Tea
The biomaker lab isn’t just for scientists and engineers. Christina Cogdell, associate professor and chair of the °ϲĻϢ Davis Department of Design, partnered with the lab for her biodesign class. Her students worked with a symbiotic mix of bacteria and yeast that produces the fermented tea drink kombucha and which as a byproduct makes a biological film that is being explored for use as a fabric in clothing and design.
Cogdell also plans to partner with the biomaker lab to host a student team’s entry in the Biodesign Challenge, a competition that pairs art and design students with science and engineering students to envision future applications of biotechnology. Top teams are invited to New York City to showcase their designs at the Museum of Modern Art. True to the cross-disciplinary nature of MPBIL, the team will draw students from the colleges of Letters and Science, Engineering and Biological Sciences.
Cogdell and two of her design students previously worked with Facciotti and Yao to explore how to tune the color of bioluminescent light by engineering E. coli bacteria to express different forms a light-producing protein.
Another student, in Cogdell’s “BioDesign Theory and Practice” seminar, used the lab to explore the idea of using the bioluminescent bacteria in bicycle lights.
“Although neither project materialized into marketable deliverables, the thought and research process would be impossible without student-focused labs such as this,” Cogdell said.
"While the project goals must be clear, the specific outcomes are often unknown at the start. Rather, students are encouraged to innovate and use design thinking to create and explore their own solutions.”
The lab, part of the Department of Biomedical Engineering’s TEAM (Translating Engineering Advances to Medicine) prototyping facilities, extends the concept of rapid prototyping made popular by “makerspaces” into the broad domain of biotechnology. Researchers, students and entrepreneurs edit bacterial genomes. They design, build and test DNA-encoded devices. They express and study diverse proteins. They study the effect of genes on organismal behavior. They build new kinds of electrical devices that interface with biology.
“We’re building a unique place to engage students in practical problem solving in biology,” Facciotti said.
A place to make stuff
In engineering, designing and creating solutions to practical problems is a traditional part of education. All engineering students cap their undergraduate careers with and many of the students also take part in various , building everything from race cars and aircraft to software. More recently, the “maker” culture has also established itself firmly in engineering schools and most engineering programs have integrated new rapid prototyping technologies like 3D printing into their formal or informal curriculums. But the “making” culture is less established in the biological sciences, despite strong interest from students in this area in working on meaningful and practical problems.
Facciotti and research associate Andrew Yao set out to capitalize on this opportunity. They equipped a teaching space with a mixture of equipment seed-funded by the Department of Biomedical Engineering’s TEAM lab, scavenged items and donated devices to open the MBPIL in 2014 .
Since opening, the lab has hosted teams competing in the annual competition, an international undergraduate biotechnology competition. It has facilitated various student design projects ranging from new chemical face peels to biobased glues to novel blood separation devices, and catalyzed the formation of two new project-based courses, one in synthetic biology and one in protein engineering. The Synthetic Biology Club will start to host activities this fall.
Success Stories
Ravata Solutions, founded by Arshia Firouzi and Gurkern Sufi, is developing technology that would make it much easier to introduce DNA into animal cells for biotechnology applications. In October 2016, Ravata was accepted into the IndieBio accelerator program in San Francisco and has built partnerships with the Lawrence Berkeley National Laboratory, VIB Life Sciences and the °ϲĻϢ Davis Mouse Biology Program to create a prototype.
“Our experiences at °ϲĻϢ Davis working in the TEAM space emboldened us to take a risk and start the company we dreamed of,” Firouzi said.
The Ambercycle story began in 2012 with a °ϲĻϢ Davis student team competing in iGEM. That team won a gold medal in the international phase of the competition for their work with bacteria that were engineered to process polyethylene terephthalate (PET) plastic and break it down into raw materials for reuse.
Following the competition, Akshay Sethi founded Ambercycle to continue pursuing this idea, winning second place and $5,000 in the the °ϲĻϢ Davis Graduate School of Management’s 2014 Big Bang! Business Competition. Akshay worked in MPBIL to refine the science until he graduated. Ambercycle has since gone on to raise more than $2 million dollars and develop numerous valuable business partnerships.
Earlier this year, Chromatiscope, a team of °ϲĻϢ Davis students and alumni, won second prize in Big Bang! with their invention of the same name. The Chromatiscope, developed in the TEAM and biomaker labs, leverages the imaging and computing power of smartphones to combine four laboratory devices into one to produce a low-cost tool that teachers can use in the classroom.
Recently, a collaboration with the °ϲĻϢ Davis First-Year Seminar program enabled a pilot course in which students designed, built and tested some novel genetic “parts” that could one day go into an educational kit for high school biology classes. Hands-on freshman seminars on yeast, worms and protein engineering followed and a course on microbial genomics will be added this fall.
“These are not cookie-cutter teaching labs, in which there is a known outcome; students in these classes are generating new data and have the experience of creating something new. The research that students are doing in these classes contributes to the scientific community and students enjoy ownership of their class’s project,” said Ashley Vater, curriculum coordinator for the First-Year Seminar program.
Fostering startup companies
In between classes, the lab is open for students to get creative, including trying out ideas that could lead to commercial products and the lab has spawned three student-led startup companies so far. They are , and (see box).
Arshia Firouzi, majoring in electrical engineering, and Gurkern Sufi, majoring in biotechnology, used the biomaker lab to design and build their prototype product, a device for rapidly introducing DNA into embryonic cells. Through the lab they were also able to take advantage of a grant awarded to Facciotti from , a nonprofit organization that promotes entrepreneurship on university campuses, and to create their company, Ravata Solutions.
In 2016, Ambercycle, a startup run by °ϲĻϢ Davis alumni Akshay Sethi and Mubasher Ahmed, won a Global Change Award from the H&M Conscious Foundation to commercialize a polyester digester, technology that “digests” polyester textiles and converts them into raw materials that can be made into new textiles. The technology was refined in the biomaker lab.
“Prototyping ideas in the hard sciences usually requires specialized infrastructure. The TEAM biomaker facility is special because it allows for innovations to be prototyped in a constructive, entrepreneurial environment,” said Sethi.
Earning national attention
Successes like these have made the °ϲĻϢ Davis biomaker lab a pioneer in biotechnology education and design. When David Kong, director of the Community Biotechnology Initiative at MIT Media Lab, wanted to start a biomaker lab at MIT, he studied the °ϲĻϢ Davis model.
“I have worked with Professor Marc Facciotti in the past on a synthetic biology curriculum in the Davis space and have been enormously impressed by the facility, its capabilities, its programs, and its positive impact on students,” Kong said.
Biomaker spaces are an essential component of the larger ecosystem for biotechnology innovation, Kong added. “The biomaker space at °ϲĻϢ Davis is a tremendous example of what is possible in academia,” he said.
Media Resources
Marc Facciotti, Biomedical Engineering, 530-752-3781, mtfacciotti@ucdavis.edu
Andy Fell, News and Media Relations, 530-752-4533, ahfell@ucdavis.edu