Design, modeling, and preliminary evaluation of a 3D-printed wrist-hand grasping orthosis for stroke survivors.

IF 3.4 Q2 ENGINEERING, BIOMEDICAL
Wearable technologies Pub Date : 2024-11-08 eCollection Date: 2024-01-01 DOI:10.1017/wtc.2024.18
Elissa D Ledoux, Eric J Barth
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引用次数: 0

Abstract

Stroke causes neurological and physical impairment in millions of people around the world every year. To better comprehend the upper-limb needs and challenges stroke survivors face and the issues associated with existing technology and formulate ideas for a technological solution, the authors conversed with 153 members of the ecosystem (60 neuro patients, 30 caregivers, and 63 medical providers). Patients fell into two populations depending on their upper-limb impairment: spastic (stiff, clenched hands) and flaccid (limp hands). For this work, the authors chose to focus on the second category and developed a set of design constraints based on the information collected through customer discovery. With these in mind, they designed and prototyped a 3D-printed powered wrist-hand grasping orthosis (exoskeleton) to aid in recovery. The orthosis is easily custom-sized based on two parameters and derived anatomical relationships. The researchers tested the prototype on a survivor of stroke and modeled the kinematic behavior of the orthosis with and without load. The prototype neared or exceeded the target design constraints and was able to grasp objects consistently and stably, as well as exercise the patients' hands. In particular, donning time was only 42 s, as compared to the next fastest time of 3 min reported in literature. This device has the potential for effective neurorehabilitation in a home setting, and it lays the foundation for clinical trials and further device development.

为中风幸存者设计三维打印腕手抓握矫形器,并对其进行建模和初步评估。
全世界每年有数百万人因中风而导致神经和肢体损伤。为了更好地了解中风幸存者的上肢需求和面临的挑战,以及与现有技术相关的问题,并为技术解决方案出谋划策,作者与生态系统中的 153 名成员(60 名神经病患者、30 名护理人员和 63 名医疗服务提供者)进行了交谈。根据上肢功能障碍的不同,患者可分为两类:痉挛型(手部僵硬、紧握)和松弛型(手部瘫软)。在这项工作中,作者选择将重点放在第二类患者身上,并根据通过客户发现收集到的信息制定了一套设计约束条件。有鉴于此,他们设计并制作了一个 3D 打印的动力腕手抓握矫形器(外骨骼)原型,以帮助康复。该矫形器可根据两个参数和衍生的解剖关系轻松定制尺寸。研究人员在一名中风幸存者身上测试了原型,并模拟了矫形器在有负载和无负载情况下的运动行为。原型接近或超过了目标设计限制,能够持续稳定地抓取物体,并锻炼了患者的双手。特别是,穿戴时间仅为 42 秒,而文献报道的次快时间为 3 分钟。该设备有望在家庭环境中实现有效的神经康复,并为临床试验和进一步的设备开发奠定了基础。
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
CiteScore
5.80
自引率
0.00%
发文量
0
审稿时长
11 weeks
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