MIT researchers have found evidence that there may be windows of opportunity during which drugs are more effective at treating cancer, reports Ariana Eunjung Cha for The Washington Post. "If we know the route to resistance," explains Prof. Michael Hemann, "we can ambush tumor cells."
Prof. Jeremiah Johnson has been named one of STAT's people to watch in Kendall Square in 2016. "The focus in Kendall square tends to be on commercializing discoveries, but Johnson is one of many scientists whose work shows basic research still has a home in the neighborhood," writes reporter Andrew Joseph.
MIT researchers have developed a new method of delivering drugs to the gastrointestinal tract via ultrasound waves, reports Alexandra Ossola of Popular Science. The new drug-delivery method could prove effective in treating diseases like Crohn’s and ulcerative colitis.
Robert Preidt writes for U.S. News & World Report that MIT researchers have found that ultrasound waves can be used to deliver drugs to the digestive system. Preidt explains that the new approach, “might potentially benefit people with inflammatory bowel disease (IBD), such as Crohn's disease and ulcerative colitis.”
MIT researchers have developed an ultrasound device that can deliver medication to the digestive system, reports Leah Samuel for The Boston Globe. The researchers “found that using ultrasound enhanced absorption of the drugs they tested up to tenfold,” writes Samuel.
An article in The Economist highlights how a number of researchers at MIT are developing new devices to regulate the delivery of drugs within the body. Prof Michael Cima is working on a drug-delivery technology that could be used to treat ovarian cancer.
Jamie Ducharme of Boston Magazine writes about a polymer gel being developed by researchers from MIT and Massachusetts General Hospital that could allow for swallowable medical devices. “Improving slow-release safety could open the door for devices that control hunger in obese patients, diagnose gastrointestinal issues, extend the effects of drugs, and more,” Ducharme explains.
MIT researchers have “developed a new ring-like device made of a polymer that can deliver drugs to the stomach over the course of a week,” writes Alexandra Ossola for Popular Science. The team anticipates that the technology could be used for a variety of medical applications.
NPR’s Jessica Harris speaks with Prof. Robert Langer about his pioneering work with drug delivery and tissue engineering. “My goals were to do things that I someday thought might improve people’s lives,” says Langer.
In a piece for The Atlantic, Sarah Laskow writes about how MIT researchers have developed a new drug-delivery capsule that could serve as an alternative to injections. The new drug capsule would make it possible to “deliver drugs that would otherwise break down in the digestive tract.”
Atlantic reporter Cari Romm reports on how MIT researchers have devised an alternative drug-delivery method: A pill covered with tiny needles. The researchers plan to improve their current design by creating a “fully biodegradable version of the pill.”
WCVB reports that researchers from MIT and Massachusetts General Hospital have developed a pill coated with tiny needles that can deliver drugs directly into the digestive tract. The pill was found to deliver insulin more efficiently than current methods, WCVB reports.
“Researchers at the Massachusetts Institute of Technology have developed a pill-like capsule that injects medication into the stomach lining after being swallowed,” reports Sky News. The new capsule could allow for oral delivery of drugs that currently must be injected.
MIT scientists have developed a pill coated in tiny needles that allows medicine to be absorbed through the lining of the stomach, writes Brooks Hays of UPI. Initial trials showed that the pill delivered insulin more efficiently than an injection.
David Pogue of the PBS show NOVA examines Professor Paula Hammond’s work developing a new type of vaccine that delivers a DNA patch via tiny microscopic needles. Using DNA as the vaccine is a “very unique but also very powerful” approach, Hammond explains.