Abstract

Our purpose was to compare the contributions of these two systems to assess PIP joint extension in fresh cadaver models. Nine middle fingers of fresh cadavers were used. The PIP joint angle was measured while an extension load was applied on the extensor tendons. Specimens on which extension load was applied on the extrinsic extensors were classified as the extrinsic group, and those on which extension load was applied on the intrinsic extensors were classified as the intrinsic group. Linear regression analyses were performed to obtain regression equation and the extension load-PIP joint angle curve. The mean of slope of the curve was compared between the two groups using paired t-test. The same experiments were done for the metacarpophalangeal (MP) joint in 0° and 60° flexion to evaluate the effect of MP joint flexion on PIP joint extension. The mean slope of the extension load-PIP joint angle curve of the extrinsic group was significantly greater than that of the intrinsic group. With the MP joint in 0° flexion, the mean slope of the extrinsic and intrinsic groups was -0.148 and -0.117, respectively (greater absolute value means greater slope, p = 0.01). With the MP joint in 60° flexion, the mean slopes were -0.147 and -0.104, respectively (p = 0.015). The contribution of the intrinsic extensor for PIP joint extension shows decreasing trends with MP joint flexion. The extrinsic extensors have greater contribution for PIP joint extension compared with the intrinsic extensors.

Highlights

  • The extensor mechanism of the finger is very delicate and is composed of two extensor systems, the extrinsic and intrinsic extensors [1, 2]

  • The extrinsic group showed significantly greater mean slope compared with the intrinsic group (-0.148 vs. -0.117, p < 0:001)

  • The results revealed that the extrinsic extensor system has significantly greater role for proximal interphalangeal (PIP) joint extension compared with the intrinsic extensor system

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Summary

Introduction

The extensor mechanism of the finger is very delicate and is composed of two extensor systems, the extrinsic and intrinsic extensors [1, 2]. Extension of the proximal interphalangeal (PIP) joint of the finger is performed by a combination of the extrinsic and intrinsic extensors [4]. The deformity is caused by the central slip and triangular ligament disruption [6, 7]. The disruption of these structures causes lateral band subluxation below the axis of rotation. Full recovery of PIP joint extension may be lacking Further knowledge on both extrinsic and intrinsic extensor systems on the PIP joint may provide useful information for successful reconstruction of the PIP joint extension mechanism

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Results

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