单侧股骨截肢患者终末摆动期的运动学：微处理器控制与摆动期控制假肢膝关节。

Kinematics in the terminal swing phase of unilateral transfemoral amputees: microprocessor-controlled versus swing-phase control prosthetic knees.

机构信息

Regional Institute of Physical Medicine and Rehabilitation, Nancy, France.

出版信息

Arch Phys Med Rehabil. 2010 Jun;91(6):919-25. doi: 10.1016/j.apmr.2010.01.025.

DOI:10.1016/j.apmr.2010.01.025

PMID:20510984

Abstract

OBJECTIVES

To analyze the spatiotemporal parameters in the terminal swing phase of the prosthetic limb in unilateral transfemoral amputees (TFAs) compared with a group of asymptomatic subjects, and to identify a latency period (LP) in the TFA between the full extension of the prosthetic knee and the initial ground contact of the ipsilateral foot. To study the correlation between the LP and the duration of the swing phase. To evaluate the influence of the type of knee, the time since amputation, and the amputation level on the latency period.

DESIGN

Three-dimensional gait analysis with an optoelectronic device.

SETTING

Gait analysis laboratory of a re-education and functional rehabilitation service.

PARTICIPANTS

TFA (n=29) and able-bodied (n=15) subjects.

INTERVENTIONS

Not applicable.

MAIN OUTCOME MEASURES

Spatiotemporal and kinematics gait parameters.

RESULTS

The swing phase and the LP of the prosthetic limb, associated with a consequently longer single-limb stance phase in the intact limb, were significantly longer than those measured in the intact limbs of these subjects, as well as those measured on both lower limbs of the able-bodied subjects (P<.05). There is a positive correlation (P<.05; r(2)=.58 between the LP and the swing phase on the TFA's prosthetic side. The LP measured in the prosthetic limb of TFA with a swing-phase control prosthetic knee is significantly greater than in those using the microprocessor-controlled prosthetic knee (P<.05).

CONCLUSIONS

Of negligible duration in able-bodied subjects and in the intact limb of TFA, the LP is significantly greater in the prosthetic limb. It can explain the lengthened swing phase on the prosthetic side of those subjects. The use of a microprocessor-controlled prosthetic knee allows the LP to be reduced. This LP appears to be necessary to insure the stability of the prosthetic knee. We suggest calling this time "confidence time."

摘要

目的

分析单侧股骨截肢（TFA）患者假肢在终末摆动期的时空参数，并与一组无症状受试者进行比较，确定 TFA 假肢膝关节完全伸展与同侧足部初始触地之间的潜伏期（LP）。研究 LP 与摆动相持续时间之间的相关性。评估膝关节类型、截肢时间和截肢水平对潜伏期的影响。

设计

使用光电设备进行三维步态分析。

地点

康复和功能康复服务的步态分析实验室。

参与者

TFA（n=29）和健全（n=15）受试者。

干预措施

不适用。

主要观察指标

时空和运动学步态参数。

结果

假肢的摆动相和 LP，以及相应的完整肢体单腿支撑期延长，明显长于这些受试者完整肢体和健全受试者双腿的测量值（P<.05）。LP 与 TFA 假肢侧摆动相之间存在正相关（P<.05；r²=.58）。使用摆动相控制假肢膝关节的 TFA 假肢 LP 测量值明显大于使用微处理器控制假肢膝关节的 LP 测量值（P<.05）。

结论

在健全受试者和 TFA 的完整肢体中，LP 的持续时间极短，但在假肢中却明显延长。它可以解释这些受试者假肢侧摆动相延长的原因。使用微处理器控制的假肢膝关节可以减少 LP。这个 LP 似乎是保证假肢膝关节稳定性所必需的。我们建议将这段时间称为“信心时间”。

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单侧股骨截肢患者终末摆动期的运动学：微处理器控制与摆动期控制假肢膝关节。

Kinematics in the terminal swing phase of unilateral transfemoral amputees: microprocessor-controlled versus swing-phase control prosthetic knees.

机构信息

出版信息

OBJECTIVES

DESIGN

SETTING

PARTICIPANTS

INTERVENTIONS

MAIN OUTCOME MEASURES

RESULTS

CONCLUSIONS

目的

设计

地点

参与者

干预措施

主要观察指标

结果

结论

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