一种用于确定静态假肢对线的新生物力学方法。

A new biomechanical method for determination of static prosthetic alignment.

作者信息

Blumentritt S

机构信息

Department of Research, Otto Bock Orthopaedic Industry, Duderstadt, Germany.

出版信息

Prosthet Orthot Int. 1997 Aug;21(2):107-13. doi: 10.3109/03093649709164538.

DOI:10.3109/03093649709164538

PMID:9285954

Abstract

A new static alignment method for trans-tibial prostheses is suggested using the individual load line as a reference. Standing posture and static alignment of 18 experienced trans-tibial prosthetic users with good walking ability were determined and compared with 20 healthy persons. The individual load line was defined by means of the new Otto Bock alignment system "L.A.S.A.R. Posture". The sagittal standing posture of trans-tibial amputees and non-amputees differs. Normally only a prosthesis worn by the trans-tibial amputee and dynamically aligned over an extended period of time satisfies biomechanical rules of alignment. In contrast, prostheses aligned during one session in the traditional subjective manner seem to lack any recognizable biomechanical systematics. Initial results suggest the knee centre should be 10 to 30mm behind the load line, depending on patient's weight. This knee position is independent on the type of prosthetic foot.

摘要

提出了一种以个体负荷线为参考的经胫假肢静态对线新方法。测定了18名行走能力良好的经验丰富的经胫假肢使用者的站立姿势和静态对线情况，并与20名健康人进行了比较。个体负荷线通过新的奥托博克对线系统“L.A.S.A.R. 姿势”来定义。经胫截肢者和非截肢者的矢状面站立姿势不同。通常，只有经胫截肢者佩戴的、经过长时间动态对线的假肢才能满足对线的生物力学规则。相比之下，以传统主观方式在一次会话中对线的假肢似乎缺乏任何可识别的生物力学系统性。初步结果表明，根据患者体重，膝关节中心应位于负荷线后方10至30毫米处。该膝关节位置与假肢足部类型无关。

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一种用于确定静态假肢对线的新生物力学方法。

A new biomechanical method for determination of static prosthetic alignment.

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