Effects of hip joint centre mislocation on gait analysis results

Stagni, Rita<sup>1,2</sup>; Leardini, Alberto<sup>2</sup>; Cappozzo, Aurelio<sup>3</sup>; Grazia Benedetti, Maria<sup>2</sup>; Cappello, Angelo<sup>1</sup>

Affiliations

¹Dipartimento di Elettronica, Informatica e Sistemistica, Università degli Studi di Bologna, Viale Risorgimento, 2-40136 Bologna, Italy

²Movement Analysis Laboratory, Istituti Ortopedici Rizzoli, Bologna, Italy

³Dipartimento di Scienze Biomediche, Universita% degli Studi di Sassari, Italy

Abstract

Methods to determine the hip joint centre (HJC) location are necessary in gait analysis. It has been demonstrated that the methods proposed in the literature involve large mislocation errors. The choice should be made according to the extent by which HJC location errors distort the estimates of angles and resultant moments at the hip and knee joints. This study aimed at quantifying how mislocation errors propagate to these gait analysis results. Angles and moments at the hip and knee joint were calculated for five able-bodied subjects during level walking. The nominal position of the HJC was determined as the position of the pivot point of a 3D movement of the thigh relative to the pelvis. Angles and moments were then re-calculated after having added to HJC co-ordinates errors in the range of ±30 mm. Angles and moments at both hip and knee joints were affected by HJC mislocation. The hip moments showed the largest propagation error: a 30 mm HJC anterior mislocation resulted in a propagated error into flexion/extension component of about −22%. The hip abduction/adduction moment was found the second largest affected quantity: a 30 mm lateral HJC mislocation produced a propagated error of about −15%. Finally, a 30 mm posterior HJC mislocation produced a delay of the flexion-to-extension timing in the order of 25% of the stride duration. HJC estimation methods with minimum antero-posterior error should therefore be preferred.

Links

DOI: 10.1016/S0021-9290(00)00093-2

PubMed: 10940407

WoS: 000089948900016

History

Accepted: 2000-04-6

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2005	Reinbolt JA, Schutte JF, Fregly BJ, Koh BI, Haftka RT, George AD, Mitchell KH. Determination of patient-specific multi-joint kinematic models through two-level optimization. J Biomech. March 2005;38(3):621-626.
2007	Harrington ME, Zavatsky AB, Lawson SEM, Yuan Z, Theologis TN. Prediction of the hip joint centre in adults, children, and patients with cerebral palsy based on magnetic resonance imaging. J Biomech. 2007;40(3):595-602.
2009	Lenaerts G, Bartels W, Gelaude F, Mulier M, Spaepen A, Van der Perre G, Jonkers I. Subject-specific hip geometry and hip joint centre location affects calculated contact forces at the hip during gait. J Biomech. June 19, 2009;42(9):1246-1251.
2020	Derrick TR, van den Bogert AJ, Cereatti A, Dumas R, Fantozzi S, Leardini A. ISB recommendations on the reporting of intersegmental forces and moments during human motion analysis. J Biomech. January 23, 2020;99:109533.
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2023	Henry A, Benner C, Easwaran A, Veerapalli L, Gaddy D, Suva LJ, Robbins AB. Predictive estimation of ovine hip joint centers: a regression approach. J Biomech. December 2023;161:111861.
2024	Sado N, Edagawa T, Fujimori T, Hashimoto S, Okamoto Y, Nakajima T. Hip and lumbosacral joint centre locations in asian population: biases produced by existing regression equations and development of new equations. J Biomech. January 2024;162:111866.
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2007	Landry CNS. Biomechanical and Neuromuscular Differences Exist Between Genders for Unanticipated Running and Cutting Maneuvers in Adolescent Soccer Players: Relevance to the ACL [PhD thesis]. Halifax, NS: Dalhousie University; March 2007.
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2010	Stroud NJ. Advancements of a Servohydraulic Human Hip Joint Motion Simulator for Experimental Investigation of Hip Joint Impingement/dislocation [Master's thesis]. University of Iowa; July 2010.
2018	Atkins PR. Characterization of Cam Femoroacetabular Impingement Using Subject-Specific Biomechanics and Population-Based Morphological Measurements [PhD thesis]. University of Utah; August 2018.