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腕骨负荷下腕横弓的生物力学

Biomechanics of the transverse carpal arch under carpal bone loading.

作者信息

Xiu Kai-Hua, Kim Joo-Han, Li Zong-Ming

机构信息

Hand Research Laboratory, Department of Orthopaedic Surgery, University of Pittsburgh, Pittsburgh, PA 15213, USA.

出版信息

Clin Biomech (Bristol). 2010 Oct;25(8):776-80. doi: 10.1016/j.clinbiomech.2010.05.011. Epub 2010 Jun 26.

DOI:10.1016/j.clinbiomech.2010.05.011
PMID:20579787
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2919606/
Abstract

BACKGROUND

Carpal tunnel release and conservative interventions are widely used in clinical therapies of carpal tunnel syndrome. The efficacy of these treatment and interventions mainly lies in the exploitation of the mechanical properties of carpal tunnel. This study investigated the structural mechanics of the transverse carpal arch using cadaveric hands.

METHODS

Paired force was applied to the insertion sites of the transverse carpal ligament at both the distal (hamate-trapezium) and proximal (pisiform-scaphoid) levels of the carpal tunnel. The two pairs of forces were simultaneously applied in an inward or outward direction when the transverse carpal ligament was intact and transected. Transverse carpal arch and carpal tunnel compliance in response to the forces were analyzed. Three-way repeated measures ANOVA were used to examine the effect of the transverse carpal ligament status (intact/transected), the level of the carpal tunnel (distal/proximal) and the force application direction (inward/outward) on the biomechanics of the transverse carpal arch.

FINDINGS

Transverse carpal ligament plays a stabilizing role in resisting outward deformation of the carpal tunnel. The carpal tunnel at the proximal level is more flexible than the carpal tunnel at the distal level. The carpal tunnel is more compliant under the inward force application than under the outward force application.

INTERPRETATION

The understanding of carpal tunnel mechanics potentially helps to improve the existing strategies and to develop alternatives for the treatment of carpal tunnel syndrome.

摘要

背景

腕管松解术和保守干预措施在腕管综合征的临床治疗中被广泛应用。这些治疗和干预措施的疗效主要在于利用腕管的力学特性。本研究使用尸体手研究了腕横弓的结构力学。

方法

在腕管的远端(钩骨 - 大多角骨)和近端(豌豆骨 - 舟骨)水平,向腕横韧带的附着部位施加成对的力。当腕横韧带完整和横断时,两对力同时向内或向外施加。分析腕横弓和腕管对力的顺应性。采用三因素重复测量方差分析来检验腕横韧带状态(完整/横断)、腕管水平(远端/近端)和力的施加方向(向内/向外)对腕横弓生物力学的影响。

结果

腕横韧带在抵抗腕管向外变形方面起稳定作用。近端水平的腕管比远端水平的腕管更灵活。腕管在向内施加力时比向外施加力时更具顺应性。

解读

对腕管力学的理解可能有助于改进现有治疗策略并开发腕管综合征的替代治疗方法。

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