HealthDay News reporter E.J. Mundell writes that MIT researchers have developed an ingestible capsule that can be used to monitor health a patient’s health. “The capsule could deliver drugs as well as sense the condition of its surroundings in the gut, including infections or allergic reactions,” Mundell explains.
MIT researchers have developed a new injectable material that can deliver medication through cartilage and could one day be used to help reverse osteoarthritis, reports Katie Camero for The Boston Globe. Camero explains that the new material “can penetrate deep into the tissue, delivering drugs that can potentially help the chondrocytes heal cartilage.”
MIT startup Lyndra has found that an ingestible device originally developed by researchers from MIT and Brigham and Women’s Hospital can help tackle the problem of medication adherence, reports Kate Sheridan for STAT. The new technology could make it possible for patients to take “one pill a week for conditions as varied as Alzheimer’s, addiction, allergies, malaria, schizophrenia, high cholesterol, and HIV.”
Edd Gent highlights MIT’s ingestible origami robot in this NBC Mach article on the ways origami is impacting science and engineering. “[T]he intricate folding patterns can be used to make complex mechanical systems,” like the MIT robot, which is “designed to unfurl and steer its way through the gut with help from external magnets,” writes Gent.
NBC Mach reporter Tom Metcalfe writes that MIT researchers have developed a technique to 3-D print soft objects that change shape in response to magnetic fields. “You can imagine this technology being used in minimally invasive surgeries,” explains Prof. Xuanhe Zhao. “A self-steering catheter inside a blood vessel, for example — now you can use external magnetic fields to accurately steer the catheter.”
MIT researchers have developed a new technique to 3-D print magnetic robots that could one day be used as biomedical devices, reports Erik Olsen for Quartz. “The engineers have enabled the bots to roll, crawl, jump, and even snap together like a Venus flytrap to grasp a pill and then roll away with it,” explains Olsen.
MIT researchers have created a new fabrication technique to create intricate, 3-D printed magnetic options that react to magnetic fields hitting them at different angles, reports Mark Wilson for Co.Design. In the future the structures, “could be placed in the human body, manipulated via wireless, harmless magnetism, and carry out intricate tasks like on-site drug delivery.”
Prof. Xuanhe Zhao and his colleagues have designed a 3D printer that can create shape-shifting soft materials. The group purposefully created the “materials and the method to be user friendly to enable a wide range of applications,” reports Fiona McMillan for Forbes.
Prof. Xuanhe Zhao speaks with WBUR about how he and his colleagues have developed a new technique to create soft, pliable structures that could carry out medical procedures within the human body. “Since the human body is soft, it's beneficial to develop a device that has a similar rigidity as soft tissues in the human body,” explains Zhao.
In this video, Mashable highlights a new method developed by MIT researchers to 3-D print soft robots that can crawl, fold and carry a pill. The team hopes the structures, which can be controlled with a magnet, could eventually be used as a medical device to take tissue samples or deliver treatments.
Lara Lewington reports for BBC Click on how MIT researchers have developed a technique to create 3-D printed soft structures that can be controlled with a magnet. Lewington explains that the structures could eventually be used in biomedical devices to “take images, extract samples, deliver drugs or even surround a blood vessel to control the pumping of blood.”
MIT researchers have developed 3-D printed magnetic robots that could potentially be used inside the body to deliver medical treatments or take tissue samples. “Their ultimate goal is to design a robot that's just as soft and flexible as a human or animal, so that it can have a wide range of potential applications,” explains Sarah Gibbens for National Geographic.
Using magnetic nanoparticles that have been mixed into rubber, Associate Prof. Xuanhe Zhao has created “3D printed shapes that fold, morph, and move in the presence of a magnetic field,” reports Leah Crane for New Scientist. In the future, Zhao believes this work could have medical applications, “like assisting minimally invasive surgeries,” notes Crane.
Boston Herald reporter Lindsay Kalter writes that MIT researchers have developed a wireless ingestible sensor that could one day be used to diagnose and treat disease. “The most exciting thing is that we can wirelessly control tiny implants even though they have no batteries at all,” says Prof. Fadel Adib.
Researchers at MIT have developed a device “that can receive power and communicate wirelessly from inside the body,” which could eventually be used for drug delivery, to treat disease or to monitor overall health, reports Allen Cone for UPI. "Having the capacity to communicate with these systems without the need for a battery would be a significant advance," said research affiliate Gio Traverso.