Article | REF: MED7100 V1

Ceramic biomaterials for orthopaedic prostheses

Authors: Laurent GREMILLARD, Jérôme CHEVALIER

Publication date: January 10, 2016

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


Overview

Français

ABSTRACT

Ceramic biomaterials have been used for orthopedic prostheses since 1965. Alumina, and later zirconia and zirconia-alumina composites were successively introduced, mainly for wear couples (head-cup) in total hip arthroplasty. This article examines these materials, their history, advantages and drawbacks. It concludes with an overview of the developments to come in materials and devices.

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHORS

  • Laurent GREMILLARD: CNRS Research Director - MATEIS Laboratory, University of Lyon, INSA-Lyon/Université Lyon1/CNRS, Villeurbanne, France

  • Jérôme CHEVALIER: Professor - University of Lyon, MATEIS Laboratory, INSA-Lyon/Université Lyon1/CNRS, Villeurbanne, France - Member of the Institut Universitaire de France

 INTRODUCTION

This article presents "bio-inert" ceramics for orthopedic implants (devices implanted in the human body to restore joint function). Other inorganic materials used for prosthesis coatings or bone substitutes ("bio-active" ceramics such as calcium phosphates, glasses or cements) are the subject of specific articles in Techniques de l'Ingénieur, and will deliberately not be discussed here.

While the use of ceramics of natural origin as biomaterials (i.e. bioceramics) dates back several millennia (use of mother-of-pearl as a dental substitute by the Mayans, for example), the controlled use of technical ceramics in contact with the human body came much later (porcelain for the manufacture of dental crowns in the 18th century, plaster of Paris for bone filling in the 19th). It was only in the mid-twentieth century that technical ceramics specifically dedicated to orthopedics appeared: in 1965, alumina (aluminum oxide) was patented for use as a head and cup for hip prostheses. This was the first use of a so-called structural bioceramic (with high mechanical properties). Zirconia and alumina-zirconia composites, with even better mechanical properties, followed for the same applications.

Alumina, zirconia and their composites are considered "bio-inert" ceramics, as they do not bond directly with bone. Indeed, after implantation of a bio-inert ceramic, a fibrous capsule forms, isolating the implant from the bone and limiting its integration. For this reason, these materials are not used for bone filling and rarely come into direct contact with bone (except in the case of zirconia dental implants, which require special surface treatments).

The creation of friction surfaces is therefore the most important application for inert bioceramics in orthopaedics. The use of bioceramics reduces wear on prostheses. Their main use is in the manufacture of components for hip prostheses (heads and cups), but they have also recently been used in certain knee prostheses and mobile cervical prostheses... The clinical successes associated with the use of ceramics have led to the implantation of over 600,000 zirconia hip replacement heads, over 3.5 million alumina heads and almost 2 million alumina-zirconia composite heads since the beginning of their use. The major drawback of ceramics is their intrinsic brittleness (in the mechanical sense of the word: they break before plastic deformation). As a result, the early days were sometimes chaotic (up to 13% fracture rate for certain series of heads in the late 1960s). The rupture rate of alumina heads is now very low (less than 0.01%), and that of alumina-zirconia heads even lower. This failure rate is therefore negligible compared to the overall failure rate of hip prostheses (around 15% at 25 years), which is generally...

You do not have access to this resource.

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


The Ultimate Scientific and Technical Reference

A Comprehensive Knowledge Base, with over 1,200 authors and 100 scientific advisors
+ More than 10,000 articles and 1,000 how-to sheets, over 800 new or updated articles every year
From design to prototyping, right through to industrialization, the reference for securing the development of your industrial projects

KEYWORDS

durability   |   biocompatibility


This article is included in

Healthcare technologies

This offer includes:

Knowledge Base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

Practical Path

Operational and didactic, to guarantee the acquisition of transversal skills

Doc & Quiz

Interactive articles with quizzes, for constructive reading

Subscribe now!

Ongoing reading
Ceramic materials for orthopedic prostheses