Lindsay Holmes writes for The Huffington Post about Koko, an application developed by MIT researchers to help users fight stress by crowdsourcing their questions and worries. “We want to take the same principles that keep our eyes glued to Facebook and Instagram 24 hours a day and redirect them to promote well-being,” explains founder Robert Morris.
Kelly Servick writes for Science about Prof. Rosalind Picard’s work developing wearable technology that monitors and manages a user’s stress levels. “It’s one thing to study all this,” says Picard. “It’s another to build it into a form that people can start changing their lives around.”
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.”
Nidhi Subbaraman reports for BetaBoston that MIT researchers have devised an ingestible microphone that allows doctors to monitor a patient’s vital signs. “A key innovation was developing algorithms that would distinguish important signals…from the noisy gurgling of the gut, and then translate them into numbers a physician can read and understand,” writes Subbaraman.
Researchers at MIT have developed an ingestible sensor that can measure vital signs without any external contact, reports Emily Reynolds for Wired. “The sensor works by using microphones—like ones found in mobile phones—that are able to pick up sound waves from the heart and lungs,” writes Reynolds.
Alexandra Ossola of Popular Science reports on an ingestible sensor that allows doctors to monitor vital signs by listening to the body’s gastrointestinal tract. The device could help treat “chronic illnesses, monitor soldiers in battle, or even help athletes train more effectively,” writes Ossola.
MIT researchers have developed an ingestible sensor that can monitor vital signs, reports Rae Ellen Bichell for NPR. "Trauma patients are a really clear winner here, because we can do vital sign monitoring without touching the skin," says Albert Swiston of Lincoln Laboratory.
In this BBC News segment, Prof. Robert Langer, winner of the Queen Elizabeth Prize for Engineering, discusses his work exploring how to get the human body to respond to vital drugs. Langer explains that his approach to medicine is to “come up with engineering solutions to different medical problems.”
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.
CNBC’s Robert Ferris reports that researchers at MIT and Boston Children’s Hospital have devised a new method to create 3-D heart models. The new technique allows doctors to 3-D print replicas of a patient’s heart within 24 hours, making it practical for hospital use, Ferris explains.
Researchers at MIT and Boston Children’s Hospital are developing a new technique to convert images from MRI scans into physical models of the human heart, writes Lindsay Kalter for The Boston Herald. “This can definitely impact clinical practice in terms of helping surgeons plan more efficiently,” explains graduate student Danielle Pace.
“Researchers from MIT and Boston Children’s Hospital say they’ve come up with a better, faster way to build heart models,” writes Barb Darrow for Fortune. The team has devised a method for 3-D printing model hearts from MRI scans that takes three to four hours compared to the 10 hours typically required using current methods.