George K. Lewis, a biomedical engineering graduate student at Cornell University, and his colleagues have created a miniaturized ultrasound device that would allow patients to apply ultrasound therapy to inflamed joints at home, work or even while going about their day. Find out more in this news release.
Credit: Zina Deretsky, National Science Foundation
Jose Contreras-Vidal, an associate professor of kinesiology at the University of Maryland, and his team have created a non-invasive, sensor-lined cap that forms a "brain-computer interface" that one day could control computers, robotic prosthetic limbs, motorized wheelchairs and even digital avatars. Learn more in this Discovery.
Credit: J. Contreras-Vidal/University of Maryland
Powered by mere vibrations or the movement of magnets, novel sensors and transmitters developed by MicroStrain, a small company in Vermont, are changing the way engineers are looking at fatigue. By monitoring strain levels and tracking the cumulative effects of fatigue, the researchers' ultimate goal is to supplant the nearly universal system of "replace by this date" with a smarter approach of replacing components based upon the actual operating loads components experience. Learn more in this Discovery.
Credit: Scripps Clinic Center for Orthopaedic Research and Education
The Division of Information and Intelligent Systems (IIS) of the Computer and Information Science and Engineering Directorate studies the inter-related roles of people, computers and information. IIS supports research and education activities that develop new knowledge about the role of people in the design and use of information technology; increase the capability to create, manage, and understand data and information in circumstances ranging from personal computers to globally-distributed systems and advance an understanding of how computational systems can exhibit the hallmarks of intelligence.
Self-assembling sheets of mesenchymal stem cells permeated with tiny beads filled with growth factor formed thicker, stiffer cartilage than previous tissue engineering methods, researchers at Case Western Reserve University have found.
Humans, other great apes and bears are among the few animals that step first on the heel when walking, and then roll onto the ball of the foot and toes. A University of Utah study found an advantage to this method in comparison to heel-first walking.
When patients have hip, knee or dental replacement surgery, they run the risk of having their bodies reject the implant. Researchers at North Carolina State University have developed a "smart coating" that helps surgical implants bond more closely with bone and ward off infection.
June 4, 2012
"Movement Retraining" Can Reduce Knee Pain
Sensors, custom software and real-time feedback help people change their walk and possibly delay, eliminate knee surgery
Aches and pains got you down? The way you walk could be wearing out parts of your body.
"All of a sudden, I developed pain in my knee and it progressively got worse. I didn't want to walk anymore," recalls Lloyd Manson, a retired contractor and developer who has osteoarthritis in his knee. Manson's pain became so severe he was seriously considering knee surgery, but just before he was about to set a date for the operation, he learned about a study at Stanford University. And, Stanford mechanical engineer Mark Cutkosky and his team were looking for test subjects.
With support from the National Science Foundation's (NSF) Human-Centered Computing Program (HCC), the research, known as Movement Retraining, focuses on alleviating pain by analyzing and possibly changing a person's stride. One of the major problems at the root of knee pain is uneven wear and tear on the knee cartilage, which leads to arthritis. "We're trying to slow the rate at which arthritis progresses, and thereby delay the time that you would need a much more expensive, invasive procedure like surgery," says Cutkosky.
Sounded too good to be true, but Manson decided to give it try. "I didn't know what to think, but I said, 'You know, what the heck.'"
Suzanne Dancer also agreed to participate in the study. "I've had knee pain on and off for a couple of years. I'm not getting younger and it was becoming more and more noticeable."
Suzanne and Lloyd are not alone. "Roughly 50 percent of people as they get older start to show some evidence of osteoarthritis of the knee," notes Cutkosky.
The research team first outfitted test subjects with sensors and then directed them to walk on a treadmill. When Manson took a step, custom software precisely calculated the forces on his joints. That data helped the team determine if a gait change might help reduce his pain.
"We use a biomechanics model and say, 'Aha! If you were, for example, to turn your toes in just a little bit or maybe your knees out, you could reduce the peak loads, the adverse loads on the knee joint,'" explains Cutkosky. The idea is to shift weight away from the more worn-out area to the more cushioned area of the knee cartilage.
So, instead of Dancer walking with one foot slightly pointed out, the researchers suggested that she turn her foot in slightly. "It was a very strange feeling," she says. "You feel like you're walking pigeon-toed, but you're not. What I couldn't argue with was the fact I did not have as much knee pain. Just recently I walked four miles. It took me 60 minutes and I had no knee pain when I was done!"
Researchers recommended a similar fix for Manson. "I had to work at it to retrain myself. It took weeks, but then it just progressively kept getting better and better. The pain is almost nonexistent. It's amazing. It's truly amazing!" says Lloyd.
But, Cutkosky cautions not to try changing your stride on your own. You could do more harm than good. To help test subjects learn their new gaits, Cutkosky and his team developed a biofeedback device for treadmill walking. One misstep and the device vibrates. They're working on a portable version to reinforce the modified gait outside the lab.
"We've seen amazing changes in the lab. People are able to change the way they walk and they have less pain and greater function," says Pete Shull, a doctoral candidate in mechanical engineering and a key member of Cutkosky's research team.
Movement retraining isn't just for people in pain. Cutkosky says athletes could improve their moves with this biofeedback technique--everything from golf swings to jump shots. "The next step is a wearable, wireless system that measures peoples' movements, provides haptic feedback, and then transmits the results to a cell phone so that people can use haptic movement training anywhere they go, at home or outdoors," he says.
This research was funded by NSF's Division of Information and Intelligent Systems (IIS) under the NSF's Directorate for Computer & Information Science & Engineering (CISE).
Any opinions, findings, conclusions or recommendations presented in this material are only those of the presenter grantee/researcher, author, or agency employee; and do not necessarily reflect the views of the National Science Foundation.