Human-Centered Design Trade-Offs for Semi-Powered Knee Prostheses: A Review

IF 3.4 Q2 ENGINEERING, BIOMEDICAL

IEEE transactions on medical robotics and bionics Pub Date : 2025-03-12 DOI:10.1109/TMRB.2025.3550655

Andrea Berettoni;Josephus J. M. Driessen;Marco Puliti;Giacinto Barresi;Carlo De Benedictis;Carlo Ferraresi;Matteo Laffranchi

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Abstract

For many decades, developments of knee prostheses have shown a dichotomy regarding fundamental working principles. The industry has mainly emphasized on quasi-passive hydraulic solutions, whereas most research works have focused on powered devices, employing electric actuation. The former have an energetically passive effect at the knee joint, for which they often lack in providing versatility and movement robustness for the wearer. Powered prostheses can address these deficiencies, but are often rejected as they struggle to fulfill other user needs (e.g., weight and acoustic noise). Correspondingly, recent studies have emerged that attempt to significantly attenuate the deficiencies of fully powered prosthesis knees, partially sacrificing on device versatility. Recognizing the state-of-the art difficulties in balancing active assistance and user needs fulfilment, this work analyses human-centered design perspectives and their prospects for prosthetic development, in light of the often diverging user needs. We conclude that various types of both explored and yet unexplored semi-powered solutions may have the potential to provide the better trade-off between quasi-passive and fully powered prosthetic devices.

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半动力膝关节假体以人为本设计的权衡：综述

几十年来，膝关节假体的发展显示出基本工作原理的二分法。业界主要强调准被动液压解决方案，而大多数研究工作都集中在采用电动驱动的动力装置上。前者在膝关节处具有能量被动作用，因此它们通常缺乏为佩戴者提供多功能性和运动稳健性。动力假肢可以解决这些缺陷，但往往被拒绝，因为它们难以满足其他用户需求（例如，重量和噪音）。相应地，最近的研究已经出现，试图显著减轻全动力假膝的缺陷，部分牺牲了设备的多功能性。认识到在平衡主动辅助和用户需求满足方面的最先进的困难，本工作分析了以人为中心的设计观点及其假肢发展的前景，考虑到经常出现的用户需求分歧。我们得出的结论是，各种类型的探索和尚未探索的半动力解决方案可能有潜力在准被动和全动力假肢装置之间提供更好的权衡。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE transactions on medical robotics and bionics

CiteScore

6.80

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0.00%

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