Biomechanical risk factors and flexor tendon frictional work in the cadaveric carpal tunnel

Abstract Pathological changes in carpal tunnel syndrome patients include fibrosis and thickening of the subsynovial connective tissue (SSCT) adjacent to the flexor tendons in the carpal tunnel. These clinical findings suggest an etiology of excessive shear-strain force between the tendon and SSCT, u...

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Bibliographic Details
Published in:Journal of biomechanics 2015-02, Vol.48 (3), p.449-455
Main Authors: Kociolek, Aaron M, Tat, Jimmy, Keir, Peter J
Format: Article
Language:English
Subjects:
Adult
Aged
Biomechanics
Cadaver
Carpal tunnel
Carpal tunnel syndrome
Carpal Tunnel Syndrome - physiopathology
Connective Tissue - physiopathology
Displacement
Ergonomics
Fibrosis
Fingers
Flexors
Friction
Gliding
Gliding resistance
Humans
Middle Aged
Physical Medicine and Rehabilitation
Range of Motion, Articular
Risk
Risk Factors
Subsynovial connective tissue
Tendon
Tendons
Tendons - physiopathology
Viscoelastic
Wrist
Wrist Joint - physiopathology
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Summary:Abstract Pathological changes in carpal tunnel syndrome patients include fibrosis and thickening of the subsynovial connective tissue (SSCT) adjacent to the flexor tendons in the carpal tunnel. These clinical findings suggest an etiology of excessive shear-strain force between the tendon and SSCT, underscoring the need to assess tendon gliding characteristics representative of repetitive and forceful work. A mechanical actuator moved the middle finger flexor digitorum superficialis tendon proximally and distally in eight fresh frozen cadaver arms. Eighteen experimental conditions tested the effects of three well-established biomechanical predictors of injury, including a combination of two wrist postures (0° and 30° flexion), three tendon velocities (50, 100, 150 mm/sec), and three forces (10, 20, 40 N). Tendon gliding resistance was determined with two light-weight load cells, and integrated over tendon displacement to represent tendon frictional work. During proximal tendon displacement, frictional work increased with tendon velocity (58.0% from 50–150 mm/sec). There was a significant interaction between wrist posture and tendon force. In wrist flexion, frictional work increased 93.0% between tendon forces of 10 and 40 N. In the neutral wrist posture, frictional work only increased 33.5% (from 10–40 N). During distal tendon displacement, there was a similar multiplicative interaction on tendon frictional work. Concurrent exposure to multiple biomechanical work factors markedly increased tendon frictional work, thus providing a plausible link to the pathogenesis of work-related carpal tunnel syndrome. Additionally, our study provides the conceptual basis to evaluate injury risk, including the multiplicative repercussions of combined physical exposures.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2014.12.029