Popular Science reporter Sarah Chodosh writes that MIT researchers have developed a strategy to deliver beneficial bacteria to the GI tract. The researchers used layers of different sugars "to coat individual cells of Bacillus coagulans, which is used to treat irritable bowel syndrome."
Angus Chen reports for NPR that MIT and Harvard researchers have captured footage showing bacteria invading antibiotics and transforming into superbugs. Postdoc Tami Lieberman explains that she hopes the visualization will help illustrate that “drug resistance is not some abstract threat. It's real."
MIT spinoff Sample6 has raised $12.7 million to create a better system for detecting bacteria in food, writes Luke Timmerman for Forbes. “The company has developed a technology that can target specific bioparticles, light them up and do it without enriching the sample,” explains Timmerman.
Boston Magazine reporter Dana Guth writes that MIT researchers are programming harmless strains of E. coli bacteria to destroy tumor cells. Guth explains that the programmed bacteria could be ingested or injected and “could offer a new way to stave off liver cancer.”
MIT researchers have developed a portable system that could produce biotech drugs on demand, reports Lisa Rapaport for Reuters. “The table-top machine has the potential to one day produce proteins to treat any number of a wide range of conditions like cancer, diabetes, heart attacks, and hemophilia,” writes Rapaport.
A portable device developed by MIT researchers uses programmable yeast to create drugs on demand, reports Jamie Ducharme for Boston Magazine. The device “could be a lifesaver for doctors working in vulnerable conditions, such as the battlefield, a remote village, or even an ambulance,” writes Ducharme.
Popular Science reporter Samantha Cole writes that MIT researchers have developed a laptop-sized, portable device that can produce biopharmaceuticals for doctors in remote locations. Cole explains that the device can “produce a single dose of treatment with a series of steps, using genetically engineered yeast cells as a mini 'factory' for a variety of customizable drugs.”
Boston Herald reporter Lindsay Kalter writes that MIT researchers have developed a portable pharmacy that can manufacture biopharmaceuticals and modify treatments. “Instead of relying on a cocktail that already exists, you can reprogram the reactor on demand to customize the treatment,” says Prof. Timothy Lu.
A new study co-authored by researchers at the Broad Institute examines how exposure to microbes during childhood can impact the development of immune systems, reports Elissa Strauss for Slate. The researchers found that “while our individual habits are a factor in autoimmune disorders, they’re hardly the only cause.”
Huffington Post reporter Carolyn Gregoire writes that MIT spinoff Synlogic is working on reprogramming gut bacteria to act as a living therapeutic. “It’s become really clear that the bacteria living in us and on us affect our bodies in a variety of different ways — in ways that we never imagined,” explains Prof. Timothy Lu.
MIT researchers have developed a programming language that allows users to design DNA circuits for living cells, writes Andy Coghlan for New Scientist. “We take the same approach as for designing an electronic chip,” says Prof. Christopher Voigt. “Every step in the process is the same – it’s just that instead of mapping the circuit to silicon, it’s mapped to DNA.”
MIT researchers have developed a programming language for living cells, reports Erika Check Hayden for Nature. “What we’re finding over time is that biology isn’t this kind of mysterious unpredictable substrate; it just felt that way because we didn’t really have the tools to see what was going on,” Prof. Christopher Voigt says.
Researchers at the MIT Media Lab have developed a new material, called bioLogic, that alters its shape with changes in humidity and opens ventilation ducts when the wearer starts sweating, writes Olga Kharif for Bloomberg Business.
MIT researchers have demonstrated that power plant emissions can be turned into liquid fuels using engineered microbes, reports Damian Carrington for The Guardian. Carrington explains that the process “uses bacteria to convert the waste gases into acetic acid - vinegar - then an engineered yeast to produce an oil.”
Jane Wakefield reports for BBC News on a system developed by postdoctoral fellow Tal Danino in which bacteria are programmed to detect cancers in the liver. "It is a fascinating universe in our body and we can now program bacteria like we program computers,” Danino says.