Imaging

Profs. Canan Dagdeviren and Hugh Herr speak with CNN discuss their work aimed at empowering patients and doctors. Inspired by her aunt’s experience with breast cancer, Dagdeviren and her students are developing new wearable devices that could help detect cancer at an earlier stage. Says Herr of his work developing prosthetics that can be controlled by the human nervous system: “There will be a point where technology is so sophisticated that we can actually rebuild limbs after amputation that will be as good and, ultimately, they will be better than intact biological limbs.” Herr adds that in the future he hopes “the conversation will not be about human limitation anymore. It will be about human ability and human expression.”

CNN visits the lab of Prof. Canan Dagdeviren to learn more about her work developing wearable ultrasound devices that could help screen for early-stage breast cancer, monitor kidney health, and detect other cancers deep within the body. “Wearable technology will grow rapidly in the near future,” says Dagdeviren. “But in the far future, they will be one of the most powerful tools that we will be seeing in our daily life.” 

Prof. Xuanhe Zhao speaks with Amerigo Allegretto of AuntMinnie.com about his work developing a new ultrasound sticker that can measure the stiffness of internal organs and could one day be used for early detection and diagnosis of disease. “Due to the huge potential of measuring the rigidity of deep internal organs, we believe we can use this to monitor organ health,” Zhao explains.

Forbes contributor William Haseltine spotlights how MIT researchers have developed a flexible ultrasound patch that can be used to help estimate bladder volume. “The applications for long-term therapeutic and regenerative medicine for the ultrasound patch are innumerable, only to be limited by the imagination of those implementing their use,” writes Haseltine. “Among the most forthcoming are situations where someone may be unable to visit their physician for a medically-administered ultrasound.”

MIT researchers have developed a new cell imaging technique that offers “the ability to observe up to seven different molecules simultaneously,” writes Amal Jos Chacko for Interesting Engineering. “This could open the door to a deeper understanding of cellular functions, aging, and diseases.”

MIT researchers have developed a new machine-learning technique that can identify which pixels in an image represent the same material, which could help with robotic scene understanding, reports Kyle Wiggers for TechCrunch. “Since an object can be multiple materials as well as colors and other visual aspects, this is a pretty subtle distinction but also an intuitive one,” writes Wiggers.

MIT researchers have developed “a programmable wireless device that can control light orders of magnitude more quickly than commercial devices,” reports Susannah Sudborough for Boston.com. “The device, which is called a spatial light modulator (SLM), will have impactful practical uses beyond creating holograms,” writes Sudborough.

A stamp-sized reusable ultrasound sticker developed by researchers in Prof. Xuanhe Zhao’s research group has been named one of the best inventions of 2022 by TIME. “Unlike stretchy existing ultrasound wearables, which sometimes produce distorted images, the new device’s stiff transducer array can record high-resolution video of deep internal organs (e.g. heart, lungs) over a two-day period,” writes Alison Van Houten.

Prof. Fadel Adib speaks with CBC Radio about his lab’s work developing a wireless, battery-free underwater camera that runs on sound waves. "We want to be able to use them to monitor, for example, underwater currents, because these are highly related to what impacts the climate," says Adib. "Or even underwater corals, seeing how they are being impacted by climate change and how potentially intervention to mitigate climate change is helping them recover."

STAT reporter Edward Chen spotlights how MIT researchers developed a new ultrasound adhesive that can stick to skin for up to 48 hours, allowing for continuous monitoring of internal organs. “It’s a very impressive new frontier about how we can use ultrasound imaging continuously to assess multiple organs, organ systems,” said Eric Topol, the founder and director of the Scripps Research Translational Institute. “48 hours of continuous imaging, you’d have to lock somebody up in a hospital, put transducers on them. This is amazing, from that respect.”

MIT researchers have developed an adhesive ultrasound patch that can continuously image the inner workings of the body for up to 48 hours, reports Sarah Kuta for Smithsonian Magazine. ““We believe we’ve opened a new era of wearable imaging,” says Prof. Xuanhe Zhao. “With a few patches on your body, you could see your internal organs.”

MIT engineers have created a bioadhesive ultrasound device that can be adhered to a patient’s skin and record high-res videos of internal organs for up to two days, reports Sophie Bushwick for Scientific American. “The beauty of this is, suddenly, you can adhere this ultrasound probe, this thin ultrasound speaker, to the body over 48 hours,” says Zhao. “This can potentially change the paradigm of medical imaging by empowering long-term continuous imaging, and it can change the paradigm of the field of wearable devices.”

Researchers at MIT, led by Prof. Xuanhe Zhao, have created a wearable ultrasound medical device, reports Jeremy Hsu for New Scientist. “The ultrasound stickers may provide a more flexible imaging option for hospitals to monitor patients without requiring human technicians to hold ultrasound probes, and they could be useful in situations where technicians are in short supply,” writes Hsu.

Prof. Xuanhe Zhao and his research team have developed a stick-on ultrasound patch that can scan a person’s insides as they go about their daily life, reports Ian Sample for The Guardian. “The wearable patch, which is the size of a postage stamp, can image blood vessels, the digestive system and internal organs for up to 48 hours, giving doctors a more detailed picture of a patient’s health than the snapshots provided by routine scans,” explains Sample.

Researchers from MIT have produced a miniature ultrasound device that sticks to the body, reports Maggie Chen for Wired. “By sticking the patch on different parts of the subject’s body, the researchers could get images of the stomach, muscles, blood vessels, lungs, and heart,” explains Chen.