A soft, wearable device that mimics the muscles, tendons and ligaments of the lower leg could aid in the rehabilitation of patients with ankle-foot disorders.
This is the claim of Yong-Lae Park, an assistant professor of robotics at Carnegie Mellon University. He worked with collaborators at Harvard University, the University of Southern California, MIT and Massachusetts-based BioSensics to develop an active orthotic (artificial support or brace) device using soft plastics and composite materials instead of a rigid exoskeleton.
The soft materials - combined with pneumatic artificial muscles (PAMs), lightweight sensors, and advanced control software - made it possible for the robotic device to achieve natural motions in the ankle.
The researchers reported on the development in the journal Bioinspiration & Biomimetics. In a statement, Park said the same approach could be used to create rehabilitative devices for other joints of the body or create soft exoskeletons that increase the strength of the wearer.
The robotic device would be suitable for aiding people with neuromuscular disorders of the foot and ankle associated with cerebral palsy, amyotrophic lateral sclerosis, multiple sclerosis or stroke. These gait disorders include drop foot, in which the forefoot drops because of weakness or paralysis, and equinus, in which the upward bending motion of the ankle is limited. Conventional passive ankle braces can improve gait, but long-term use can lead to muscle atrophy because of disuse. Active, powered devices can improve function and also help re-educate the neuromuscular system.
‘The limitation of a traditional exoskeleton is that it limits the natural degrees of freedom of the body,’ said Park. The ankle is naturally capable of a complicated three-dimensional motion, but most rigid exoskeletons allow only a single pivot point. The soft orthotic device enabled the researchers to mimic the biological structure of the lower leg. The device’s artificial tendons were attached to four PAMs, which correspond with three muscles in the foreleg and one in the back that control ankle motion. The prototype was capable of generating an ankle range of sagittal motion of 27 degrees, which is sufficient for a normal walking gait.
The soft device, however, is more difficult to control than a rigid exoskeleton. Park said it required more sophisticated sensing to track the position of the ankle and foot, and a more intelligent scheme for controlling foot motion. The device contains sensors made of a touch-sensitive artificial skin, and thin rubber sheets that contain long microchannels filled with a liquid metal alloy. When these rubber sheets are stretched or pressed, the shapes of the microchannels change, which cause changes in the electrical resistance of the alloy. These sensors were positioned on the top and at the side of the ankle.
Park said additional work will be necessary to improve the wearability of the device. This includes artificial muscles that are less bulky than the commercially produced PAMs used in this project.
This is the claim of Yong-Lae Park, an assistant professor of robotics at Carnegie Mellon University. He worked with collaborators at Harvard University, the University of Southern California, MIT and Massachusetts-based BioSensics to develop an active orthotic (artificial support or brace) device using soft plastics and composite materials instead of a rigid exoskeleton.
The soft materials - combined with pneumatic artificial muscles (PAMs), lightweight sensors, and advanced control software - made it possible for the robotic device to achieve natural motions in the ankle.
The researchers reported on the development in the journal Bioinspiration & Biomimetics. In a statement, Park said the same approach could be used to create rehabilitative devices for other joints of the body or create soft exoskeletons that increase the strength of the wearer.
The robotic device would be suitable for aiding people with neuromuscular disorders of the foot and ankle associated with cerebral palsy, amyotrophic lateral sclerosis, multiple sclerosis or stroke. These gait disorders include drop foot, in which the forefoot drops because of weakness or paralysis, and equinus, in which the upward bending motion of the ankle is limited. Conventional passive ankle braces can improve gait, but long-term use can lead to muscle atrophy because of disuse. Active, powered devices can improve function and also help re-educate the neuromuscular system.
‘The limitation of a traditional exoskeleton is that it limits the natural degrees of freedom of the body,’ said Park. The ankle is naturally capable of a complicated three-dimensional motion, but most rigid exoskeletons allow only a single pivot point. The soft orthotic device enabled the researchers to mimic the biological structure of the lower leg. The device’s artificial tendons were attached to four PAMs, which correspond with three muscles in the foreleg and one in the back that control ankle motion. The prototype was capable of generating an ankle range of sagittal motion of 27 degrees, which is sufficient for a normal walking gait.
The soft device, however, is more difficult to control than a rigid exoskeleton. Park said it required more sophisticated sensing to track the position of the ankle and foot, and a more intelligent scheme for controlling foot motion. The device contains sensors made of a touch-sensitive artificial skin, and thin rubber sheets that contain long microchannels filled with a liquid metal alloy. When these rubber sheets are stretched or pressed, the shapes of the microchannels change, which cause changes in the electrical resistance of the alloy. These sensors were positioned on the top and at the side of the ankle.
Park said additional work will be necessary to improve the wearability of the device. This includes artificial muscles that are less bulky than the commercially produced PAMs used in this project.