The Effect of Abductor Muscle and Anterior-posterior Hip Contact Load Simulation on the In-vitro Primary Stability of a Cementless Hip Stem

Overview

Journal J Orthop Surg Res

Publisher Biomed Central

Specialty Orthopedics

Date 2010 Jun 26

PMID 20576151

Citations 1

Authors

Youngbae Park

Carolyne Albert

Yong-San Yoon

Goran Fernlund

Hanspeter Frei

Thomas R Oxland

Affiliations

Soon will be listed here.

Abstract

Background: In-vitro mechanical tests are commonly performed to assess pre-clinically the effect of implant design on the stability of hip endoprostheses. There is no standard protocol for these tests, and the forces applied vary between studies. This study examines the effect of the abductor force with and without application of the anterior-posterior hip contact force in the in-vitro assessment of cementless hip implant stability.

Methods: Cementless stems (VerSys Fiber Metal) were implanted in twelve composite femurs which were divided into two groups: group 1 (N = 6) was loaded with the hip contact force only, whereas group 2 (N = 6) was additionally subjected to an abductor force. Both groups were subjected to the same cranial-caudal hip contact force component, 2.3 times body weight (BW) and each specimen was subjected to three levels of anterior-posterior hip contact load: 0, -0.1 to 0.3 BW (walking), and -0.1 to 0.6 BW (stair climbing). The implant migration and micromotion relative to the femur was measured using a custom-built system comprised of 6 LVDT sensors.

Results: Substantially higher implant motion was observed when the anterior-posterior force was 0.6BW compared to the lower anterior-posterior load levels, particularly distally and in retroversion. The abductor load had little effect on implant motion when simulating walking, but resulted in significantly less motion than the hip contact force alone when simulating stair climbing.

Conclusions: The anterior-posterior component of the hip contact load has a significant effect on the axial motion of the stem relative to the bone. Inclusion of the abductor force had a stabilizing effect on the implant motion when simulating stair climbing.

Citing Articles

Stiffness optimization and reliable design of a hip implant by using the potential of additive manufacturing processes.

Risse L, Woodcock S, Bruggemann J, Kullmer G, Richard H Biomed Eng Online. 2022; 21(1):23.

PMID: 35366884 PMC: 8976951. DOI: 10.1186/s12938-022-00990-z.

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