Finite element simulation of intra-carpal tunnel pressure: the effects of individual finger flexion and histological changes

International journal of experimental and computational biomechanics Pub Date : 2015-12-31 DOI:10.1504/ijecb.2015.073929

Kyrin Liong, A. Lahiri, Shujin Lee, D. Chia, A. Biswas, H. Lee

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引用次数: 1

Abstract

Carpal tunnel syndrome (CTS) is a common neuropathy, yet its etiology is unknown. While repetitive finger flexion and interstitial subsynovial connective tissue (SSCT) thickening are commonly associated with idiopathic CTS development, the stress that the nerve experiences remain unexamined. In this study, a patient-specific computational model of the carpal tunnel was developed. Tendon displacements corresponding to thumb, index finger (IF) and middle finger (MF) flexion were prescribed. To replicate a CTS candidate, the most common physiological finding - fibrosis of the SSCT - was modelled. Heightened nerve coefficients were also prescribed to simulate nerve stiffening. This revealed that volarly-moving tendons, as in IF and thumb flexion, elicit greater nerve stresses than those dorsally-moving tendons, as in MF flexion. The stress encountered in CTS candidates significantly exceeded those in normal candidates, demonstrating that tendon path, and the in-vivo conditions of an individual's SSCT and median nerve stiffness predominantly affect nerve stress.

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腕管内压力的有限元模拟:个体手指屈曲和组织学变化的影响

腕管综合征(CTS)是一种常见的神经病变，其病因尚不清楚。虽然重复性手指屈曲和间质滑膜下结缔组织(SSCT)增厚通常与特发性CTS的发展有关，但神经所经历的压力尚未得到研究。在这项研究中，开发了一个针对患者的腕管计算模型。规定拇指、食指(IF)和中指(MF)屈曲对应的肌腱移位。为了复制CTS候选者，最常见的生理发现- SSCT纤维化-被建模。提高神经系数也规定，以模拟神经僵硬。这表明，掌侧运动的肌腱，如中枢性屈曲和拇指屈曲，比背侧运动的肌腱，如中枢性屈曲，引起更大的神经压力。CTS患者所遇到的应力明显超过正常患者，表明肌腱路径、个体SSCT的体内条件和正中神经僵硬度主要影响神经应力。

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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International journal of experimental and computational biomechanics

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