Contribution of each leg to the control of unperturbed bipedal stance in lower limb amputees: new insights using entropy

Abstract

The present study was designed to assess the relative contribution of each leg to unperturbed bipedal posture in lower limb amputees. To achieve this goal, eight unilateral traumatic trans-femoral amputees (TFA) were asked to stand as still as possible on a plantar pressure data acquisition system with their eyes closed. Four dependent variables were computed to describe the subject's postural behavior: (1) body weight distribution, (2) amplitude, (3) velocity and (4) regularity of centre of foot pressure (CoP) trajectories under the amputated (A) leg and the non-amputated (NA) leg. Results showed a larger body weight distribution applied to the NA leg than to the A leg and a more regular CoP profiles (lower sample entropy values) with greater amplitude and velocity under the NA leg than under the A leg. Taken together, these findings suggest that the NA leg and the A leg do not equally contribute to the control of unperturbed bipedal posture in TFA. The observation that TFA do actively control unperturbed bipedal posture with their NA leg could be viewed as an adaptive process to the loss of the lower leg afferents and efferents because of the unilateral lower-limb amputation. From a methodological point of view, these results demonstrate the suitability of computing bilateral CoP trajectories regularity for the assessment of lateralized postural control under pathological conditions.

Figure 1. Mean and standard error of the mean body weight distribution (BW distribution) (panel A), the amplitude () (panel B), the velocity () (panel C), and the regularity () (panel D) of centre of foot pressure (CoP) trajectories under the non-amputated (NA) leg (white bars) and the amputated (A) leg (black bars).

The P-values for comparisons between postural parameters computed from the NA leg and those computed from the A leg are reported ().