Abstract
We present the design and validation of a low-cost, customizable and 3D-printed anthropomorphic soft robotic hand exoskeleton for rehabilitation of hand injuries using remotely administered physical therapy regimens. The design builds upon previous work done on cable actuated exoskeleton designs by implementing the same kinematic functionality, but with the focus shifted to ease of assembly and cost effectiveness as to allow patients and physicians to manufacture and assemble the hardware necessary to implement treatment. The exoskeleton was constructed solely from 3D-printed and widely available off-the-shelf components. Control of the actuators was realized using an Arduino microcontroller, with a custom-designed shield to facilitate ease of wiring. Tests were conducted to verify that the range of motion of the digits and the forces exerted at the fingertip coincided with those of a healthy human hand.
Funder
Joseph P. Healey Research Grant program at the University of Massachusetts Boston
Subject
Fluid Flow and Transfer Processes,Computer Science Applications,Process Chemistry and Technology,General Engineering,Instrumentation,General Materials Science
Reference37 articles.
1. Heart Disease and Stroke Statistics—2019 Update: A Report from the American Heart Association;Mozaffarian;Circulation,2017
2. Hospitalization for stroke in US hospitals, 1989–2009;Hall;Diabetes,2012
3. Epidemiology and the Global Burden of Stroke
4. Upper body pain and functional disorders in patients with breast cancer;Stubblefield;PM&R,2014
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