Imaging of joint prostheses

Botchu, Rajesh; James, Steven

doi:10.1533/9780857098474.3.443

Cited by 2 publications

(1 citation statement)

References 28 publications

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“…Other teams have studied the occurrence of periprosthetic femoral fractures (PFF) [11,12]. The risk of PFF increases with osteoporosis, falls, fatigue and ageing [13][14][15], which demonstrates the need for more studies in the orthopaedic field and the search for new and suitable composite materials. With the mastering of composite materials in the orthopaedic field and in different dental, femoral, tibial prostheses this new technology is experiencing a great demand and progress.…”

Section: Introductionmentioning

confidence: 99%

Contribution to the Microstructural Study of a Composite Material Based on Carbon Fibers for Use in Orthopedic Prostheses

Menail

Alimi

Boudiaf³

et al. 2022

JBBBE

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The use of a carbon fiber composite material to make external prostheses in the form of a femoral socket was the subject of this laboratory study. According to the prior bibliographical studies, this material adapts well to this type of prosthesis. The objective of this research is to study its microscopic structure, in order to verify the good wetting of the fibers by the resin, the good cohesion and molding by infusion. The morphological study of the facies of the parallelepiped-shaped specimens was carried out after cuts perpendicular to the axis of the fiber strands, parallel according to the width and thickness of the specimen. This study was carried out using a scanning electron microscope (SEM), in order to determine, thanks to the typical microstructure of the composite, the various degradations, which appear as a result of the effect of static tension. The laminate used is based on three layers of carbon taffeta fabric and an orthocrylic resin. Tensile tests have been carried out at a speed of 1mm/min with a Zwick/Roell machine with a load cell of 50 kN. This speed was chosen to allow a comparative study with glass fiber specimens, which have been used previously for the production of prostheses, before those made of carbon. The microscopic study allowed to identify the four types of degradation; Matrix fracture, which manifested itself as fault lines, in preferred directions of different sizes. This contributed to interlaminar delamination. The decohesion that contributes to delamination in a different way from that of matrix breakage is visible at different levels. Interlaminar delamination results from the combined effect of matrix breakdown and decohesion and manifests itself as uneven strata. Fiber breakage was manifested by shearing. This study allowed to observing a degradation of the material imposed by static traction. As for the material used in orthopaedics, it has retained good cohesion and meets the requirements of prostheses, despite the defects detected by the microscopic study.

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Section: Introductionmentioning

confidence: 99%