Yan Bourgeois scite author profile

Yan Bourgeois

4Publications

15Citation Statements Received

81Citation Statements Given

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Affiliations

École de Technologie Supérieure, Hôpital du Sacré-Cœur de Montréal

Publications

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Effect of force tightening on cable tension and displacement in greater trochanter reattachment

Canet

Duke

Bourgeois

et al. 2011

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The purpose of this study was to evaluate cable tension during installation, and during loading similar to walking in a cable grip type greater trochanter (GT), reattachment system. A 4th generation Sawbones composite femur with osteotomised GT was reattached with four Cable-Ready® systems (Zimmer, Warsaw, IN). Cables were tightened at 3 different target installation forces (178, 356 and 534 N) and retightened once as recommended by the manufacturer. Cables tension was continuously monitored using in-situ load cells. To simulate walking, a custom frame was used to apply quasi static load on the head of a femoral stem implant (2340 N) and abductor pull (667 N) on the GT. GT displacement (gap and sliding) relative to the femur was measured using a 3D camera system. During installation, a drop in cable tension was observed when tightening subsequent cables: an average 40+12.2% and 11 ± 5.9% tension loss was measured in the first and second cable. Therefore, retightening the cables, as recommended by the manufacturer, is important. During simulated walking, the second cable additionally lost up to 12.2+3.6% of tension. No difference was observed between the GT-femur gaps measured with cables tightened at different installation forces (p=0.32). The GT sliding however was significantly greater (0.9 ± 0.3 mm) when target installation force was set to only 178 N compared to 356 N (0.2 ± 0.1 mm); p<0.001. There were no significant changes when initial tightening force was increased to 534 N (0.3 ± 0.1 mm); p=0.11. In conclusion, the cable tightening force should be as close as possible to that recommended by the manufacturer, because reducing it compromises the stability of the GT fragment, whereas increasing it does not improve this stability, but could lead to cable breakage.

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Improving greater trochanteric reattachment with a novel cable plate system

Baril

Bourgeois

Braïlovski

et al. 2013

Medical Engineering & Physics

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Testing System for the Comparative Evaluation of Greater Trochanter Re-attachment Devices

Baril

Bourgeois

Brailovski

et al. 2011

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The scope of this study was to propose and validate a specialized test bench that applies biaxial forces on an orthopedic model of Greater Trochanter (GT) re‐attachment with integrated cable tension measurement. Stability of the GT fragment is evaluated using a custom triplanar video movement‐analysis system with the first camera's field of view (FOV) corresponding to the GT osteotomy plane and the second and third camera's FOVs corresponding to the median plane of the femur in frontal and posterior views, respectively. A typical experimentation and its critical analysis conclude the paper.

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Finite element model of a greater trochanteric reattachment system

Bourgeois

Petit

G-Laflamme

2010

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Detachment of greater trochanter (GT) is generally associated with hip arthroplasty complications and needs for repositioning and fixation. A new GT reattachment system (Y3) was proposed to reduce GT displacements in anterior-posterior direction to decrease non-union issues. The goal of this study is to develop and validate a FEM of the Y3 GTR system. FEM validation suggests a good concordance between numerical and experimental GT displacements. Sensitivity study show that the transition between proximal and distal branches of Y3 design is the most influent part on all GT displacements. The anterior branch affects more anterior-posterior displacements and rotation while the posterior branch affects more proximal displacements and rotation. This study provides an improved understanding of the influence of Y3 geometry on GT displacements.

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Yan Bourgeois

Effect of force tightening on cable tension and displacement in greater trochanter reattachment

Improving greater trochanteric reattachment with a novel cable plate system

Testing System for the Comparative Evaluation of Greater Trochanter Re-attachment Devices

Finite element model of a greater trochanteric reattachment system

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