The Development of a Novel Lightweight Transradial Prosthetic: A Proof-of-Concept Study

Globally, there is a limb amputation every 30 seconds. In the U.S., 185,000 people undergo amputation annually, leading to two million existing amputees in the country. There is a current need for the development of a customizable prosthetic with high compressive strength that utilizes interstitial...

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Veröffentlicht in:	Technology and innovation 2018-11, Vol.20 (1), p.47-53
Hauptverfasser:	McBryan, Sarah, Malkoc, Aldin, La Belle, Jeffrey T.
Format:	Artikel
Sprache:	eng
Schlagworte:	Amputation Assistive Technology Blindness Composite materials Compression tests Compressive strength Critical components Customization Design Forearm Lightweight Manufacturing Particle board Patients People with disabilities Preliminary designs Prostheses Rapid prototyping Sensory Substitution Social Interaction Strength testing Torsion Visual Impairment Weight reduction
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creator	McBryan, Sarah Malkoc, Aldin La Belle, Jeffrey T.
description	Globally, there is a limb amputation every 30 seconds. In the U.S., 185,000 people undergo amputation annually, leading to two million existing amputees in the country. There is a current need for the development of a customizable prosthetic with high compressive strength that utilizes interstitial free space to house potential critical components. The study aimed to develop a proof-of-concept press-fit design of the forearm and hand. Prototypical designs for a transradial (below the elbow) prosthetic forearm were constructed to increase characteristic strengths while retaining high percentages of interstitial free space for customization. The scope of this research will pertain to preliminary strength testing analyses, including compression, torsional, and three-point bending tests, and retention of free space for patient point-of-care customization. Chipboard, an inexpensive composite material, was used for all experimental prototypical models due to its fast manufacturing and processing speed with rapid prototyping machines. The results show chipboard press-fit preliminary design of the 4-fin device with torsional support for the transdermal prosthetic was cabable of withstanding 348.73 lbf and had 86% free space to house potential critical components. This research proposes proof-of-concept press-fit framework designs for lightweight transradial prosthetics. The designs retained characteristic compressive and torsional strengths while yielding up to 90% free space to house various components and increase customization via weight distribution within the device, thus further allowing individuals with disabilities to adjust to their environments.
doi_str_mv	10.21300/20.1-2.2018.47
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subjects	Amputation Assistive Technology Blindness Composite materials Compression tests Compressive strength Critical components Customization Design Forearm Lightweight Manufacturing Particle board Patients People with disabilities Preliminary designs Prostheses Rapid prototyping Sensory Substitution Social Interaction Strength testing Torsion Visual Impairment Weight reduction
title	The Development of a Novel Lightweight Transradial Prosthetic: A Proof-of-Concept Study
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