Chemical engineering

Lita Nelsen BS ’64, MS ’66, MBA ’79 writes for The Boston Herald about the Bayh-Dole Act, a landmark piece of legislation that allows universities to keep the patents to their own inventions. “As the head of MIT’s Technology Licensing Office for almost three decades, I helped license thousands of technologies to the innovative companies that sprung up around campus,” writes Nelsen. “The Bayh-Dole Act has indisputably helped the U.S. life sciences sector become the envy of the world.”

Nature reporter Neil Savage spotlights Prof. Michael Strano’s work developing a new technique to use nanoparticles to alter the biology of living plants. Savage writes that the new technique can allow for "the design of nanoparticles that carry gene-editing machinery to targeted areas to rewrite the plant’s genome and imbue it with properties such as pest and disease resistance,” writes Savage.

Prof. Yoel Fink speaks with Washington Post reporter Pranshu Verma about the growing field of smart textiles and his work creating fabrics embedded with computational power. Fink and his colleagues “have created fibers with hundreds of silicon microchips to transmit digital signals — essential if clothes are to automatically track things like heart rate or foot swelling. These fibers are small enough to pass through a needle that can be sown into fabric and washed at least 10 times.”

Scientists at MIT are developing a self-boosting vaccine that can provide multiple doses of a vaccine via a single injection, reports Darko Manevski for Newsweek. The technology “could be particularly useful for administering childhood vaccinations in regions where people do not have regular access to medical care,” writes Manevski.

MIT scientists are developing self-boosting vaccine technology that could allow people to receive all of their vaccine doses in one shot, reports The Economist. This technology “would be a game-changer, not only for future pandemics but also for vaccination programs in remote regions where it is harder to deliver boosters,” The Economist notes.

Siblings Gia Schneider ‘99 and Abe Schneider SM ‘03 co-founded Natel, a company dedicated to developing sustainable, climate-resilient hydropower, reports Amy Gunia for TIME. “The siblings hope that what they’re doing can help demonstrate a more sustainable approach to renewable energy – proving that companies shouldn’t have to choose between what’s good for the environment and what works economically,” writes Gunia.

Professor Kristala Prather speaks with Radio Boston host Tiziana Dearing about her work using synthetic biology to develop new materials that function like plastic, but don’t rely on fossil fuels and biodegrade when no longer in use. Prather also explores how the Kendall Square innovation ecosystem has helped fuel her work. “Our end goal is to try to still give us those materials, those plastics that are plasticy when we need them, but to pre design them such that at their end of life they are much more environmentally responsible,” explains Prather.

Science reporter Jocelyn Kaiser spotlights Prof. Kristala Prather’s work as a scout for a new funding program that will provide her the opportunity to identify “colleagues with an intriguing research idea so embryonic it has no chance of surviving traditional peer review—and, on her own, decide to provide some funding.” Says Prather: “I’m looking forward to giving it a try. I’m a people person, and I like learning new things.”

TechCrunch reporter Devin Coldewey spotlights how MIT researchers have developed a machine learning technique for proposing new molecules for drug discovery that ensures suggested molecules can be synthesized in a lab. Coldewey also features how MIT scientists created a new method aimed at teaching robots how to interact with everyday objects.

MIT researchers have developed a new technique that uses deep learning to improve the process of drug discovery, reports Jonathan Vanian for Fortune. “The technique addresses a common problem that researchers face when using A.I. to develop novel molecular structures: life sciences experts can often face challenges synthesizing A.I.-created molecular structures,” writes Vanian. 

The Conversation spotlights Institute Prof. Robert Langer ‘74 who spoke at the 2022 Imagine Solutions Conference about his academic career and work applying his chemical engineering background to his research in health sciences. “I learned that if you’re not your own champion, nobody else will be,” says Langer. “So, I got involved in patenting things, and my students were very interested in seeing their work make a difference… My story is sort of one person’s example of how you can try to use science to help relieve suffering and prolong life.”

Researchers from MIT have developed a new fabric that can hear and interpret what’s happening on and inside our bodies, reports Elana Spivack for Inverse. Beyond applications for physical health the researchers envision that the fabric could eventually be integrated with “spacecraft skin to listen to [accumulating] space dust, or embedded into buildings to detect cracks or strains,” explains Wei Yan, who helped develop the fabric as an MIT postdoc. “It can even be woven into a smart net to monitor fish in the ocean. It can also facilitate the communications between people who are hard of [hearing].”

Prof. Yoel Fink speaks with WHDH about his team’s work developing an acoustic fabric that can listen to and record sound, a development inspired by the human ear. "The fabric can be inserted into clothes to monitor heart rate and respiration. It can even help with monitoring unborn babies during pregnancy."

Bloomberg News spotlights how MIT researchers have developed a new material that works like a microphone, converting sounds into vibrations and then electrical signals. “The development means the possibility of clothes that act as hearing aids, clothes that answer phone calls, and garments that track heart and breathing rates,” writes Bloomberg News.

Researchers from MIT and the Rhode Island School of Design have developed a wearable fabric microphone that can detect and transmit soundwaves and convert them into electrical signals, reports Shi En Kim for Popular Science. “Computers are going to really become fabrics," says Prof. Yoel Fink. "We’re getting very close.”