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Spokane Standard

Thursday, November 21, 2024

University team tests robotic arm exoskeleton at St. Luke’s for stroke recovery

A robotic arm exoskeleton being tested in Spokane is reaching to advance recovery for stroke patients. 

Developed at University of Idaho, a two-joint device is in trial use  for one arm  at Providence St. Luke’s Rehabilitation Medical Center. It  is designed to mimic the movement and

abilities of the human elbow and  forearm and  help stroke survivors regain mobility.

But the UI team is working up to a bilateral device, with multijoint  robotic exoskeletons extending from shoulder through fingertips for both  arms – offering tools to assess

impairments, help a patient move a weak  limb and support therapy motions with a game interface.

“We’re building it up in phases – starting with a two-joint robot –  and we’re expanding now to a five-joint robot that we’re still  perfecting the controllers on,” said Joel Perry, UI

associate professor  in mechanical engineering. He’s also co-director of UI’s assistive  robotics lab.

“Then we’ll be building up toward a nine-, 13- and hopefully up to a  15-joint robot per arm. The big part of this project is it’s bilateral  and will allow us to do assessments on both

arms. That is really  important, because there is such a variety of effects after a stroke.

“It makes it harder to compare anyone to normal, so the ability to  assess a left arm and a right arm on the same patient can give you a  little closer to normal for that person.”

A National Science Foundation  grant funded the UI’s project.   Starting summer 2015, the project was dubbed BLUE SABINO, for BiLateral  Upper-Limb Exoskeleton for

Simultaneous Assessment of Biomechanics and  Neuromuscular Output.

UI faculty and about two dozen engineering students have assisted the  project, along with a Whitworth University professor and two of his  students.

“The ultimate hope is that we get all 15 joints of the bilateral  system together so it’s able to support full reaching grasp assessment,  and along the way, learn new things about how

impairment plays out in  different people, so we can start gathering a database that better  supports targeted therapy,” Perry said.

“The ultimate aim is to improve the quality of life for people with  neurological deficits and maximize the quality of recovery outcomes in a  minimum amount of time.”

Doug Weeks, St. Luke’s clinical research senior manager, said the   robotic bilateral device has wide potential. From birth to end of life,  the brain has the capability to change and

regain prior function with  practice, he added.

“The most common type of stroke, about nine in every 10 strokes, is  an ischemic stroke that typically affects one hemisphere of the brain  that is responsible for controlling arm

activities on the opposite  side,” Weeks said.

“What the bilateral robotic device will allow is for each person to  act as their own control. We can provide tests to see what the ranges of  motion are, the amount of strength, the

precision of movement in the  unaffected limb after an ischemic stroke, and then be able to compare  that to the affected side.

“It has a level of precision that’s going to be higher than what  could be generated if we have, for example, a therapist who is  performing tests on both limbs to find out the degree of

deficits.”

Additionally, occupational therapists routinely set up repeated tasks  for stroke patients in rehabilitation. But the number of targeted tasks  can increase in less time with assistance

from the robotic arms, Weeks  said. An option to use a connected computer game for a patient to  practice a pattern also provides an incentive, he said.

“Intentional practice is something that we are wanting the patient  after a stroke to engage in, so those neurons that were damaged because  of the stroke can begin to regenerate,

create new pathways – so that arm  function, hand function and finger function are something that can be  brought back,” Weeks added.

“This robotic device is really a game changer in terms of being able  to offer not only evaluation in a stroke patient to see what their  capabilities are, and where they might have

deficits, but also the  ability to provide (patient) practice.”

COVID restrictions delayed testing the early model, but three  patients have tried the two-joint device mainly for feedback to UI  developers.

“Right now, it’s for one arm, and it just happens to be the left arm,” Weeks said.

Perry said the device with motorized joints can provide motion  assistance, but with enough rotation and degrees of freedom that a  patient can move. It also measures motion.

“We’re trying to make the device feel like it’s not there,” Perry said. 

“The device moves out of your way as you move, so it can record  mobility and record function, but because it has the motors, it has the  ability to provide assistance, or resistance,

or gravity support to the  arm. It can put you in a different state to be able to do an assessment  specific to a given user.”

It also has sensors and the ability to record signals from muscles and brain activity, Perry said.

Rene Maura, a UI mechanical engineering doctoral student, supported  developing advanced control systems, safety systems, electrical design  and some game software. Chris

Bitikofer, UI mechanical engineer graduate  research assistant, also did recent technology work.

Richard Stevens, Whitworth robotics engineering and physics  professor, spent a sabbatical year working with the UI team and supports  the project in Spokane. He said recent

Whitworth students Ryan Grady  and Laura Stricker helped develop the game, which allows a patient to  move and match a hand-held object to what’s seen on a screen.

Overall, Weeks said the device can potentially support many patients, including after traumatic brain injuries.

“This device will be unique,” Weeks said. “A few others are  FDA-approved and on the market but they only collect data from one limb  at a time.”

He said most devices also don’t record signals from the muscles and  brain as the patient is moving for assessments. “We at Providence St.  Luke’s are happy to be part of this

collaboration. We are invested  because we know what the great potential is for our patients.”

Original source can be found here.

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