Symmetry Function in Gait Pattern Analysis in Patients After Unilateral Transfemoral Amputation Using a Mechanical or Microprocessor Prosthetic Knee

Overview

Journal J Neuroeng Rehabil

Publisher Biomed Central

Specialties Biomedical Engineering
Neurology
Rehabilitation Medicine

Date 2021 Jan 20

PMID 33468184

Citations 2

Authors

Mateusz Kowal

Slawomir Winiarski

Ewa Gieysztor

Anna Kolcz

Karolina Walewicz

Wojciech Borowicz

Alicja Rutkowska-Kucharska

Malgorzata Paprocka-Borowicz

Affiliations

Soon will be listed here.

Abstract

Background: Above-knee amputations (AKAs) contribute to gait asymmetry. The level of asymmetry is affected by the type of knee prosthetic module. There is limited evidence suggesting that more technically advanced solutions (microprocessor modules; MicPK) are superior to less advanced ones (mechanical modules; MechPK). The study aimed to evaluate the variable range of hip and pelvic joint movements during gait and look for differentiating areas with an increased level of asymmetry of the gait cycle in individuals who underwent an AKA and are equipped with MicPK or MechPK.

Methods: Twenty-eight individuals participated in the study; 14 were assigned to a study group of individuals who underwent a unilateral AKA, and the other 14 were healthy participants as a control group. The movement task was recorded using the optoelectronic SMART-E system following the standard Davis protocol (the Newington model). A new method of quantifying gait symmetry using the symmetry function (SF) is proposed. SF is an integral measure of absolute differences in time-standardized signals between sides throughout the whole cycle of motion variability.

Results: In the frontal plane, there were significant differences between groups in the asymmetry of the range of movement in the hip joint of the intact limb. In the middle of the support phase, the intact limb was more adducted in individuals with MicPK and less abducted in people with MechPK (differences in mean 180%, p < 0.000; max 63%, p < 0.000; min 65%, p < 0.000). In the sagittal plane, the range of asymmetry of the flexion and thigh extension of the intact limb was similar to and only slightly different from the physiological gait. In the transverse plane, higher asymmetry values were noted for individuals with MicPK. In the final stage of the swing phase, the thigh was more rotated both externally and internally. The size of the asymmetry, when compared to gait of healthy individuals, reached 50% (differences in mean 115%, p < 0.232; max 62% p < 0.26; min 50, p < 0.154).

Conclusions: In the study group, the assessed ranges of pelvic and thigh movement in the hip joint differed only in the frontal plane. Individuals who underwent a unilateral above-knee amputation may gain less from using MicPK than anticipated.

Citing Articles

Is Socket Flexion Alignment Associated With Changes in Gait Parameters in Individuals With an Above-knee Amputation and a Hip Flexion Contracture?.

Arribart K, Peryoitte V, Kaniewski A, Bonnet X, Pillet H Clin Orthop Relat Res. 2024; 483(3):535-546.

PMID: 39499774 PMC: 11828000. DOI: 10.1097/CORR.0000000000003288.

An enhancement of the Genium™ microprocessor-controlled knee improves safety and different aspects of the perceived prosthetic experience for unilateral and bilateral users.

Klenow T, Lundstrom R, Morris A, Patterson S, Simpson C, Trejo E Front Rehabil Sci. 2024; 5:1342370.

PMID: 38798750 PMC: 11122470. DOI: 10.3389/fresc.2024.1342370.

Symmetry Function: The Differences between Active and Non-Active Above-the-Knee Amputees.

Kowal M, Winiarski S, Gieysztor E, Kolcz A, Dumas I, Paprocka-Borowicz M Sensors (Basel). 2022; 22(16).

PMID: 36015694 PMC: 9413346. DOI: 10.3390/s22165933.

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