3D Motion Analysis for the Assessment of Dynamic Coupling in Transtibial Prosthetics: A Proof of Concept

3D Motion Analysis for the Assessment of Dynamic Coupling in Transtibial Prosthetics: A Proof of Concept

Assessment of coupling between transtibial sockets and users is historically based on clinicians' observations and experience, but can be inaccurate and unreliable. Therefore, we present a proof of concept, for five out of six possible degrees of freedom coupling metric system for a socket, usi...

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Veröffentlicht in:IEEE open journal of engineering in medicine and biology 2023-01, Vol.4, p.141-147
Hauptverfasser: Cullen, Sean, Mackay, Ruth, Mohagheghi, Amir, Du, Xinli
Format: Artikel
Sprache:eng
Schlagworte:
Axes of rotation
Calibration
Clinical trials
Control data (computers)
Coupling
Couplings
Dynamic coupling
Dynamic tests
Measurement
Metric system
motion analysis
pistoning
Prostheses
Prosthetics
Quality of life
quantitative methods
Sockets
Thigh
Three dimensional motion
Three dimensional printing
Three-dimensional displays
transtibial prosthetics
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Zusammenfassung:Assessment of coupling between transtibial sockets and users is historically based on clinicians' observations and experience, but can be inaccurate and unreliable. Therefore, we present a proof of concept, for five out of six possible degrees of freedom coupling metric system for a socket, using motion analysis calibrated on a 3D printed limb substitute. The method is compatible with any socket suspension method and does not require prior modifications to the socket. Calibration trials were used to locate the axis of rotation of the knee joint referenced against a marker cluster on the thigh; this allowed for the identification of the limb during test trials despite the entire residuum being obscured from view by the socket. The error in the technique was found to be within 0.7 mm in displacement and 0.7 degrees in rotation, based on the control data. Dynamic testing showed the Inter Quartile Range (IQR) of inter time step variance was
ISSN:2644-1276
2644-1276
DOI:10.1109/OJEMB.2023.3296978