食指的多方向力量与力范围

Multi-directional strength and force envelope of the index finger.

作者信息

Li Zong-Ming, Pfaeffle H Jamie, Sotereanos Dean G, Goitz Robert J, Woo Savio L-Y

机构信息

Musculoskeletal Research Center, Department of Orthopaedic Surgery, University of Pittsburgh, E1641 Biomedical Science Tower, 210 Lothrop Street, Pittsburgh, PA 15213, USA.

出版信息

Clin Biomech (Bristol). 2003 Dec;18(10):908-15. doi: 10.1016/s0268-0033(03)00178-5.

DOI:10.1016/s0268-0033(03)00178-5

PMID:14580834

Abstract

OBJECTIVE

The purpose of this study was to biomechanically evaluate the motor function of the index finger based on multi-directional strengths.

DESIGN

An experimental apparatus was developed to measure force production of a digit at various points of force application along the digit and in any direction of force application within the transverse plane of the longitudinal axis of the digit.

BACKGROUND

Most existing tests of hand motor function are subjective, semiquantitative, and/or non-specific.

METHODS

Eight normal subjects with asymptomatic hands were tested. Maximum voluntary isometric contraction forces were measured at the middle of the proximal phalanx of the index finger in 16 directions that were evenly distributed within 360 degrees.

RESULTS

The highest force, 110.7 (SD 9.0) N, was generated in flexion, while the lowest force was generated in extension. The forces in extension, abduction and adduction were 37.6%, 97.9% and 79.3% of the flexion force, respectively. The area of the force envelope was 25739 (SD 3688) N-N. The average percentage quadrant areas, relative to the total force envelope area, for extension-adduction, extension-abduction, flexion-abduction, and flexion-adduction were 12.9%, 20.4%, 36.0%, and 30.8%, respectively. The average percentage quadrant areas for extension, abduction, flexion, and adduction were 9.1%, 33.3%, 35.6%, and 22.1%, respectively.

CONCLUSION

The current study provides an advanced level of quantification of hand motor function.

RELEVANCE

The methods may be used as a basis to detect changes in the motor function resulting from pathological conditions, disease progression, as well as rehabilitation and treatment of these disorders.

摘要

目的

本研究旨在基于多方向力量对示指的运动功能进行生物力学评估。

设计

开发了一种实验装置，用于测量手指在沿手指的不同力作用点以及在手指纵轴横向平面内的任何力作用方向上的力产生情况。

背景

大多数现有的手部运动功能测试是主观的、半定量的和/或非特异性的。

方法

对8名手部无症状的正常受试者进行测试。在示指近节指骨中部，于360度内均匀分布的16个方向上测量最大自主等长收缩力。

结果

屈曲时产生的力最高，为110.7（标准差9.0）N，而伸展时产生的力最低。伸展、外展和内收时的力分别为屈曲力的37.6%、97.9%和79.3%。力包络面积为25739（标准差3688）N·N。相对于总力包络面积，伸展 - 内收、伸展 - 外展、屈曲 - 外展和屈曲 - 内收的平均象限面积百分比分别为12.9%、20.4%、36.0%和30.8%。伸展、外展、屈曲和内收的平均象限面积百分比分别为9.1%、33.3%、35.6%和22.1%。

结论

本研究提供了手部运动功能的高级量化水平。

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Multi-directional strength and force envelope of the index finger.食指的多方向力量与力范围

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食指的多方向力量与力范围

Multi-directional strength and force envelope of the index finger.

作者信息

机构信息

出版信息

OBJECTIVE

DESIGN

BACKGROUND

METHODS

RESULTS

CONCLUSION

RELEVANCE

目的

设计

背景

方法

结果

结论

相关性

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