计算机化袖带压力测算法在可穿戴软机器人应用中的圆周组织压缩引导：系统评价。

Computerized Cuff Pressure Algometry as Guidance for Circumferential Tissue Compression for Wearable Soft Robotic Applications: A Systematic Review.

机构信息

School of Design and Health Research Institute, University of Limerick , Limerick, Ireland .

出版信息

Soft Robot. 2018 Feb;5(1):1-16. doi: 10.1089/soro.2017.0046. Epub 2017 Oct 13.

DOI:10.1089/soro.2017.0046

PMID:29412078

Abstract

In this article, we review the literature on quantitative sensory testing of deep somatic pain by means of computerized cuff pressure algometry (CPA) in search of pressure-related safety guidelines for wearable soft exoskeleton and robotics design. Most pressure-related safety thresholds to date are based on interface pressures and skin perfusion, although clinical research suggests the deep somatic tissues to be the most sensitive to excessive loading. With CPA, pain is induced in deeper layers of soft tissue at the limbs. The results indicate that circumferential compression leads to discomfort at ∼16-34 kPa, becomes painful at ∼20-27 kPa, and can become unbearable even below 40 kPa.

摘要

本文回顾了通过计算机化袖带压力测痛法（CPA）对深部躯体痛进行定量感觉测试的文献，以期为可穿戴式软外骨骼和机器人设计寻找与压力相关的安全指南。迄今为止，大多数与压力相关的安全阈值都是基于界面压力和皮肤灌注，尽管临床研究表明深部躯体组织对过度负荷最为敏感。通过 CPA，可在四肢的深部软组织层诱发疼痛。结果表明，圆周压缩在约 16-34kPa 时会引起不适，在约 20-27kPa 时会引起疼痛，甚至在低于 40kPa 时也会难以忍受。

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计算机化袖带压力测算法在可穿戴软机器人应用中的圆周组织压缩引导：系统评价。

Computerized Cuff Pressure Algometry as Guidance for Circumferential Tissue Compression for Wearable Soft Robotic Applications: A Systematic Review.

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