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Researchers at MIT have developed a slow-release drug capsule that can last two weeks in a person’s stomach, writes Jamie Ducharme for Boston Magazine. “The capsule was tested for use in malaria prevention, but the researchers behind it say it could be used for virtually any condition that requires regular oral medication,” Ducharme explains.
Reuters reporter Kate Kelland writes that MIT researchers have created a new drug-delivery capsule that can stay in the stomach for up to two weeks after being swallowed. The star-shaped device could be “a powerful weapon in fighting malaria, HIV and other diseases where successful treatment depends on repeated doses of medicine.”
MIT researchers have developed a star-shaped, drug-delivery device that can stay in the stomach for up to two weeks, gradually releasing medication, reports Melissa Healy for The Los Angeles Times. The researchers believe the device could be useful in “delivering a wide range of medications for diseases in which patient non-adherence is a problem.”
A paper-based test that can detect the Zika virus, developed by Prof. James Collins and his research team, is featured in a list of the year’s most important health innovations compiled Alyssa Favreau and Claire Maldarelli for Popular Science. Unlike conventional lab tests, the paper-based test can provide results within three hours.
Guardian reporter Amy Fleming spotlights Prof. Robert Langer’s work revolutionizing medicine. Fleming notes that “Langer’s trailblazing research in nanotechnology, which ranges from haircare to cancer treatments, has already improved the lives of at least 2 billion people.”
MIT researchers have developed a new technique for making vaccines using freeze-dried cells, reports Ed Yong for The Atlantic. Yong explains that in addition to producing medicines, the technique provides a new way of “detecting important diseases, like Zika and Ebola, without relying on laboratories or sequencing machines.”
MIT researchers have developed a new technique to stop the spread of cancer cells through the body by delivering microRNAs to the site of the primary tumor, reports Hallie Smith for Boston Magazine. The technique “may correct gene disruptions that put a patient at risk of metastatic cancer,” Smith explains.
STAT reporter Sharon Begley writes that MIT will share the One Brave Idea research award, which is focused on supporting research aimed at fighting heart disease. The award recipients plan “to hunt down so-far unrecognized signals marking the transition from a healthy heart to one on the road to disease.”
Eric Boodman writes for STAT that MIT researchers have developed a technique to produce biopharmaceuticals in remote locations. “Instead of making the drugs and then trying to keep them refrigerated over thousands of miles,” Boodman writes, the researchers, “want to give people the ingredients. These components don’t require refrigeration, and the instructions are as simple as they come: Just add water.”
Prof. Robert Langer talks to Jessica Harris from NPR about his research on tissue engineering and drug delivery, the commercialization of his discoveries, and the many companies he has started. Langer says he started his lab based off his desire to improve people’s lives by conducting research “at the interface of chemical engineering and medicine.”
MIT researchers have developed a new way to record the activities of human cells, reports Kevin Hartnett for The Boston Globe. “Most of the studies we do to understand diseases like cancer and Alzheimer’s involve studying cells in a dish. We’re interested in understanding how cells function in their natural environments,” explains Prof. Timothy Lu.
ABC News reporter Gillian Mohney writes that Prof. Lydia Bourouiba has captured footage of a person sneezing, showing how far sneeze droplets can travel. Bourouiba found that “large droplets tended to land within 1 to 2 meters (about 3 to 6 feet) and that small droplets could get as far as 6 to 8 meters away (19 to 26 feet).”
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 programmable vaccine that could be used to respond to disease outbreaks, reports Ben Gruber for Reuters. The vaccine harnesses “messenger RNA, a genetic material that can be programmed to fight any viral, bacterial or parasitic disease by provoking an amplified immune response.”
Space.com reporter Samantha Mathewson writes that MIT researchers have developed a vibrating boot to help astronauts avoid obstacles. Prof. Leia Stirling explains that she hopes the boot will make astronauts “more confident and efficient during extravehicular activities and may decrease their injury risk due to trips and falls.”