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Defense Advanced Research Projects Agency (DARPA)

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The Economist

MIT researchers devised a new way to arrange LED pixels to create screens with a much higher resolution than is currently possible, reports The Economist. The new technique, which involves stacking micro LEDS, could also be used to make “VR images that appear far more lifelike than today’s.”

National Geographic

National Geographic reporter Maya Wei-Haas explores how the ancient art of origami is being applied to fields such a robotics, medicine and space exploration. Wei-Haas notes that Prof. Daniela Rus and her team developed a robot that can fold to fit inside a pill capsule, while Prof. Erik Demaine has designed complex, curving fold patterns. “You get these really impressive 3D forms with very simple creasing,” says Demaine.

Time

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.

The Economist

The Economist highlights a paper by researchers from MIT and Stanford that finds new ideas are becoming harder to find in areas ranging from crop yields to microchip density. The Economist also spotlights how Prof. Danielle Li and Prof. Pierre Azoulay examined the Defense Advanced Research Project Agency (DARPA) model of funding and found that it “does best when its program directors have a clear understanding of the sort of breakthroughs that are needed.”

STAT

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.”

Smithsonian Magazine

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.”

Scientific American

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.”

New Scientist

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.

The Guardian

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.

Wired

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.

The Boston Globe

MIT engineers have developed a medical ultrasound system that uses a patch the size of a postage stamp, reports Hiawatha Bray for The Boston Globe. “The new MIT system would allow a doctor or technician to attach a patch directly over the area to be scanned,” explains Bray. “The patch is plugged into a device that captures the ultrasound signal, converts it to a viewable image and records it for future reference.”

TechCrunch

TechCrunch reporter Devin Coldewey spotlights how MIT researchers have developed a machine learning technique for proposing new molecules for drug discovery that ensures suggested molecules can be synthesized in a lab. Coldewey also features how MIT scientists created a new method aimed at teaching robots how to interact with everyday objects.

TechCrunch

CSAIL researchers have developed a new technique that could enable robots to handle squishy objects like pizza dough, reports Brian Heater for TechCrunch.  “The system is separated into a two-step process, in which the robot must first determine the task and then execute it using a tool like a rolling pin,” writes Heater. “The system, DiffSkill, involves teaching robots complex tasks in simulations.”

Popular Science

Popular Science reporter Rahul Rao writes that researchers from MIT and Harvard have whipped up quantum tornadoes, “the latest demonstration of quantum mechanics—the strange code of laws that governs the universe at its finest, subatomic scales.”

Smithsonian Magazine

Researchers from MIT and Harvard have directly observed a quantum tornado, reports Elizabeth Gamillo for Smithsonian. “Scientists observed the tornado-like behavior after trapping and spinning a cloud of one million sodium atoms using lasers and electromagnets at 100 rotations per second,” writes Gamillo.