Hybrid Soft-Rigid Active Prosthetics Laboratory Exercise for Hands-On Biomechanical and Biomedical Engineering Education.

IF 1.7 4区 医学 Q4 BIOPHYSICS
Run Ze Gao, Peter S Lee, Aravind Ravi, Carolyn L Ren, Clark R Dickerson, James Y Tung
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引用次数: 0

Abstract

This paper introduces a hands-on laboratory exercise focused on assembling and testing a hybrid soft-rigid active finger prosthetic for biomechanical and biomedical engineering (BME) education. This hands-on laboratory activity focuses on the design of a myoelectric finger prosthesis, integrating mechanical, electrical, sensor (i.e., inertial measurement units (IMUs), electromyography (EMG)), pneumatics, and embedded software concepts. We expose students to a hybrid soft-rigid robotic system, offering a flexible, modifiable lab activity that can be tailored to instructors' needs and curriculum requirements. All necessary files are made available in an open-access format for implementation. Off-the-shelf components are all purchasable through global vendors (e.g., DigiKey Electronics, McMaster-Carr, Amazon), costing approximately USD 100 per kit, largely with reusable elements. We piloted this lab with 40 undergraduate engineering students in a neural and rehabilitation engineering upper year elective course, receiving excellent positive feedback. Rooted in real-world applications, the lab is an engaging pedagogical platform, as students are eager to learn about systems with tangible impacts. Extensions to the lab, such as follow-up clinical (e.g., prosthetist) and/or technical (e.g., user-device interface design) discussion, are a natural means to deepen and promote interdisciplinary hands-on learning experiences. In conclusion, the lab session provides an engaging journey through the lifecycle of the prosthetic finger research and design process, spanning conceptualization and creation to the final assembly and testing phases.

用于生物力学和生物医学工程教育的混合软硬活动假肢实验练习。
本文介绍了一个动手实验活动,重点是为生物力学和生物医学工程教育组装和测试一个软硬混合主动假指。该动手实验活动的重点是设计一个肌电手指假肢,将机械、电气、传感器(即惯性测量单元、肌电图)、气动和嵌入式软件概念融为一体。我们让学生接触软硬混合机器人系统,提供灵活、可修改的实验活动,可根据教师的需求和课程要求进行定制。所有必要的文件都以开放获取的格式提供,以供实施。现成的组件均可通过全球供应商(如 DigiKey Electronics、McMaster-Carr、Amazon)购买,每个套件的成本约为 100 美元,其中大部分组件可重复使用。我们在神经与康复工程高年级选修课上与 40 名工程学本科生试用了该实验室,收到了极好的积极反馈。该实验室植根于现实世界的应用,是一个引人入胜的教学平台,因为学生们渴望了解具有实际影响的系统。实验室的延伸,如后续临床(如假肢)和/或技术(如用户设备界面设计)讨论,是深化和促进跨学科实践学习体验的自然手段。总之,该实验课程提供了一个充满吸引力的假肢手指研究和设计过程的生命周期之旅,从概念化、创造到最终组装和测试阶段。
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
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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