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Abstract

BACKGROUND:

Prosthetists conventionally evaluate alignment based on visual interpretation of patients’ gait, which is convenient, but largely subjective and depends on prosthetists’ experience.

OBJECTIVE:

In this paper, we explore the feasibility of using a support vector machine (SVM) approach to automatically detect misalignment of trans-tibial prostheses through ground reaction force (GRF).

METHODS:

Alternate classification algorithms with varying kernels and feature sets were compared to assess the suitability for detection of a representative misalignment (six degrees of ankle plantar flexion) from normal alignment. A classical feature selection algorithm, Fisher Score, was further introduced to identify valuable features and reduce the dimension of feature sets.

RESULTS:

The SVMs achieved a detection accuracy of 96.67% at best within the same subject and 88.89%, respectively, for inter-subject. Combined horizontal and vertical components of GRF features provided the maximum detection accuracies. Propulsion peak force was identified as key variable of gait for misalignment prediction.

CONCLUSIONS:

As a proof of concept, the results demonstrate potential in applying this approach to detect prosthetic misalignment based on gait patterns, and is a step towards future developments of tools for early prevention of misalignment in clinical.

Keywords

Gait analysis prosthetic alignment ground reaction forces machine learning lower limb amputee

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