In this Reuters video, Ben Gruber examines how MIT researchers are working on developing new treatments for diabetes. "What we developed is basically a new material that acts like an invisibility cloak,” explains Prof. Daniel Anderson. “It coats the cells but allows them to function and live but protects them from the immune system.”
MIT researchers are developing a smart bandage that could monitor and help heal wounds, according to Reuters. Prof. Xuanhe Zhao explains that if sensors in the bandage detected “an abnormal increase in temperature, for example, it will send out a command. Then the controlled drug delivery system can deliver a specific drug to that specific location.”
In an interview with the BBC, Prof. Heidi Williams argues that there should be more incentives for developing cancer prevention techniques and treatments for early-stage cancers. "If you look at drugs that get approved by the FDA, they all tend to be for very late stage cancer patients,” says Williams.
STAT reporter Andrew Joseph writes that MIT scientists have developed a potential new treatment for diabetes. Joseph explains that the new technique could allow healthy insulin-producing cells to be successfully transplanted into patients.
Prof. Ioannis Yannas was inducted into the National Inventor’s Hall of Fame for his work with Dr. John Burke on regenerating human skin as a treatment for burn victims, writes Robby Berman for Slate. In a video accompanying the story, Yannas explains that his work was focused on “speeding up the rate of closing up these wounds.”
MIT researchers have found that few incentives exist to encourage research on disease prevention, reports Austin Frakt for The New York Times. “R & D on cancer prevention and treatment of early-stage cancer is very socially valuable,” Profs. Heidi Williams and Ben Roin explain, “yet our work shows that society provides private firms…surprisingly few incentives.”
Dana Guth reports for Boston Magazine on a new bandage developed by Prof. Xuanhe Zhao that can deliver medication directly to a wound. “The bandage is filled with tiny pathways, so that drugs can flow through its gel-like material, providing relief for burns and other minor skin conditions,” writes Guth.
MIT researchers have developed a new bandage that can detect infection and automatically release medication, reports Jordan Graham for The Boston Herald. “We are trying to design long-term, high-efficiency interfaces between the body and electronics,” explains Prof. Xunahe Zhao.
NBC News reporter Maggie Fox writes that MIT researchers have developed a stretchy, wet bandage that can deliver medications. The device could “carry a thermometer to continuously measure skin temperature, or tiny devices to keep an eye on blood sugar levels for someone with diabetes.”
Popular Science reporter Alexandra Ossola writes that MIT researchers are examining how drops of fluid from a sneeze travel. Ossola explains that gaining a “better understanding of these drops form and spread could help researchers and engineers stop the spread of disease, especially in enclosed spaces."
MIT researchers have examined how droplets are formed in high-propulsion sneeze clouds, according to CBS Boston. “Droplets are not all already formed and neatly distributed in size at the exit of the mouth, as previously assumed in the literature,” explains Prof. Lydia Bourouiba.
Prof. Lydia Bourouiba has modeled how droplets are formed after a person sneezes, reports Jonathan Webb for BBC News. “The process is important to understand because it determines the various sizes of the final droplets - a critical factor in how a sneeze spreads germs,” writes Webb.
MIT researchers have found that the high-velocity cloud created by the average human sneeze can contaminate a room in minutes, writes Robert Preidt for U.S. News & World Report. Sneeze droplets "undergo a complex cascading breakup that continues after they leave the lungs, pass over the lips and churn through the air," explains Prof. Lydia Bourouiba.
Lincoln Lab researcher Albert Swiston speaks on NPR’s All Things Considered about the new sensor developed by MIT researchers that monitors vital signs through the gastrointestinal tract. “There are some bits of information from the body—namely the temperature of the body—that can only be monitored from inside the body,” explains Swiston.
Researchers at MIT and Massachusetts General Hospital have developed an ingestible device that monitors vital signs, reports Dialynn Dwyer of Boston.com. Dwyer explains that the device is a “pill-sized stethoscope with a microphone that, once swallowed, transmits data from inside the body.”