Popular Science reporter Kelsey Atherton writes that a new 3-D printing process developed by MIT researchers incorporates both solid and liquid materials at the same time. Atherton explains that the prototype robot developed using the process walks “with hydraulic bellows, fluid pumping in and out to turn a crankshaft that moves the legs back and forth.”
Researchers from MIT CSAIL have developed a new 3-D printing process that produces robots with no assembly required, reports Brian Mastroianni for CBS News. “MIT's new process is significant in that the production period is streamlined, with the robot's solid and liquid hydraulic parts being created in one step,” Mastroianni explains.
Boston Magazine reporter Jamie Ducharme writes that MIT researchers have developed a way to simultaneously 3-D print liquid and solid materials, “allowing them to create functional, nearly assembly-free robots.”
Jonathan Webb reports for BBC News that MIT researchers have developed a “molten glass sewing machine.” "It does exactly what a sewing machine does," explains applied mathematics instructor Pierre-Thomas Brun. "You go from a thread, to patterns which are tied to each other like stitching patterns - but this time they're made out of glass."
In this video, the BBC’s LJ Rich reports on the 3-D printed, soft robotic hand developed by researchers at the MIT Computer Science and Artificial Intelligence Lab. Rich explains that the robotic hand can “handle objects as delicate as an egg and as thin as a compact disk.”
Washington Post reporter Rachel Feltman writes that MIT researchers have designed a new robotic hand with soft, 3-D printed fingers that can identify and lift a variety of objects. Prof. Daniela Rus explains that her group’s robotic hand operates in a way that is “much more analogous to what we do as humans."
Writing for Popular Science, Mary Beth Griggs reports on the soft robotic gripper developed by researchers at MIT CSAIL. “The silicone fingers are equipped with sensors that analyze the object they are touching and compare it to other items in its database,” Griggs writes.
CNBC reporter Robert Ferris writes about how MIT researchers have developed a soft robotic hand that can identify and safely grasp delicate objects. Ferris explains that the researchers designed a “soft silicone ‘hand’ with embedded sensors that they can train to recognize different things.”
MIT CSAIL researchers have developed a silicon gripper that allows robots to grasp a wide variety of items, reports Nidhi Subbaraman for BetaBoston. Subbaraman explains that the hand expands “to accommodate a shape, and grasps radially – surrounding an object instead of picking it up with pincers.”
MIT researchers have developed a new material that mimics the cuttlefish’s ability to change texture, reports Gian Volpicelli for Wired. "We used ordinary plastic," explains graduate student Mark Guttag. "The important thing was figuring out the right difference in stiffness between the matrix and particles."
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.
Jon Christian reports for The Boston Globe on FitSocket, a device created by researchers in MIT’s Biomechatronics group that gathers data used to create personalized prosthetic sockets. “We’re treating the body as a mechanical thing, because it is,” explains graduate student Arthur Petron.
In an article for Wired, Liz Stinson writes about how the new technique MIT researchers developed for 3-D printing glass could be used in building design. Stinson writes that Prof. Neri Oxman believes, “3-D printed glass eventually will make building facades far more dynamic.”