VANDERBILT (US) — A wearable robot offers people with severe spinal cord injuries an unprecedented degree of independence, allowing them to stand, walk, sit, and climb stairs.
A team of engineers at Vanderbilt University’s Center for Intelligent Mechatronics developed the powered exoskeleton that is both light weight and compact.
Until recently powered exoskeletons were the stuff of science fiction, but in the last 10 years, advances in robotics, microelectronics, and battery and electric motor technologies have advanced to the point where it has become practical to develop exoskeletons to aid people with disabilities. In fact, two companies—Argo Medical Technologies Ltd. in Israel and Ekso Bionics in Berkeley, Calif.—have developed products of this type and are marketing them in the US.
The devices, that act like an external skeleton, strap in tightly around the torso. Rigid supports are strapped to the legs and extend from the hip to the knee and from the knee to the foot. The hip and knee joints are driven by computer-controlled electric motors powered by advanced batteries. Patients use the powered apparatus with walkers or forearm crutches to maintain their balance.
“You can think of our exoskeleton as a Segway with legs,” says Michael Goldfarb, the H. Fort Flowers chair in mechanical engineering and professor of physical medicine and rehabilitation at Vanderbilt University.
“If the person wearing it leans forward, he moves forward. If he leans back and holds that position for a few seconds, he sits down. When he is sitting down, if he leans forward and holds that position for a few seconds, then he stands up.”
“My kids have started calling me ‘Ironman,'” says Brian Shaffer, who was completely paralyzed from the waist down in an automobile accident on Christmas night 2010.
Shaffer has been testing the Vanderbilt apparatus at the Nashville-area satellite facility of the Shepherd Center, one the leading hospitals for spinal cord and brain injury rehabilitation in the United States. The center has provided the Vanderbilt engineers with the clinical feedback they need to develop the device.
“It’s unbelievable to stand up again. It takes concentration to use it at first but, once you catch on, it’s not that hard: The device does all the work, Shaffer says. “I don’t expect that it will completely replace the wheelchair, but there are some situations, like walking your daughter down the aisle at her wedding or sitting in the bleachers watching your son play football, where it will be priceless.”
“This is an extremely exciting new technology,” says Clare Hartigan, a physical therapist at Shepherd Center who has worked with the Argo, Ekso, and Vanderbilt devices. “All three models get people up and walking, which is fantastic.”
Just getting people out of their wheelchairs and getting their bodies upright regularly can pay major health dividends, Hartigan says.
According to the National Spinal Cord Injury Statistical Center, somewhere between 236,000 to 327,000 people in the US are living with serious spinal cord injuries. About 155,000 have paraplegia. The average age at injury is 41 and the estimated lifetime cost when it happens to a person of 50 ranges from $1.1 million to $2.5 million.
People who rely on a wheelchair to move around can develop serious problems with their urinary, respiratory, cardiovascular, and digestive systems, as well as getting osteoporosis, pressure sores, blood clots and other afflictions associated with lack of mobility.
The risk for developing these conditions can be reduced considerably by regularly standing, moving, and exercising their lower limbs.
Weighs only 27 pounds
None of the exoskeletons have been approved yet for home use, but the Vanderbilt design has some intrinsic advantages. It has a modular design and is lighter and slimmer than the competition. As a result, it can provide its users with an unprecedented degree of independence.
Users will be able to transport the compact device on the back of their wheelchair. When they reach a location where they want to walk, they will be able to put on the exoskeleton by themselves without getting out of the wheelchair. When they are done walking, they can sit back down in the same chair and take the device off or keep it on and propel the wheelchair to their next destination.
The Vanderbilt exoskeleton weighs about 27 pounds, nearly half the weight of the other models that weigh around 45 pounds. The other models are also bulkier so most users wearing them cannot fit into a standard-sized wheelchair.
From a rehabilitation perspective the Vanderbilt design also has two potential advantages:
- The amount of robotic assistance adjusts automatically for users who have some muscle control in their legs. This allows them to use their own muscles while walking. When a user is totally paralyzed, the device does all the work. The other designs provide all the power all of the time.
- It incorporates a proven rehabilitation technology called functional electrical stimulation. FES applies small electrical pulses to paralyzed muscles, causing them to contract and relax. FES can improve strength in the legs of people with incomplete paraplegia. For complete paraplegics, FES can improve circulation, change bone density and reduce muscle atrophy.
There is also the matter of cost. The price tags of other rehabilitation model exoskeletons have been reported to be as high as $140,000 each, plus a hefty annual service fee.
Parker Hannifin hasn’t set a price for the Vanderbilt exoskeleton, but Goldfarb is hopeful that its minimalist design will translate into a more affordable product. “It would be wonderful if we could get the price down to a level where individuals could afford them and insurance companies would cover them,” he says.
“These new devices for walking are here and they are getting better and better. However, a person has to be physically fit to use them,” Hartigan says. “They have to keep their weight below 220 pounds, develop adequate upper body strength to use a walker or forearm crutches, and maintain flexibility in their shoulder, hip, knee, and ankle joints . . . which is not that easy when a person has relied on a wheelchair for months or even years.”
Goldfarb developed the system with funding from the National Institutes of Health and with the assistance of research engineer Don Truex, graduate students Hugo Quintero, Spencer Murray and Kevin Ha, and Ryan Farris, a former student who now works for Parker Hannifin Corporation.
Vanderbilt currently has several patents pending on the design and Parker Hannifin has signed an exclusive licensing agreement to develop a commercial version of the device, which it plans to introduce in 2014.
Source: Vanderbilt University