Bioinspired approaches to toughen calcium phosphate-based ceramics for bone repair

TL;DR

This review explores bioinspired microstructural design strategies for calcium phosphate ceramics to enhance their toughness and fatigue resistance for load-bearing bone repair applications.

Contribution

It provides a comprehensive overview of processing methods to create hierarchical, biomimetic CPC microstructures and discusses their potential to improve mechanical performance.

Findings

Bioinspired microstructures improve toughness

Hierarchical structures enable load-bearing capabilities

Current methods face limitations in replicating natural bone properties

Abstract

To respond to the increasing need for bone repair strategies, various types of biomaterials have been developed. Among those, calcium phosphate ceramics (CPCs) are promising since they possess a chemical composition similar to that of bones. To be suitable for implants, CPCs need to fulfill a number of biological and mechanical requirements. Fatigue resistance and toughness are two key mechanical properties that are still challenging to obtain in CPCs. This paper thus reviews and discusses current progress in the processing of CPCs with bioinspired microstructures for load-bearing applications. First, methods to obtain CPCs with bioinspired structure at individual lengthscales, namely nano-, micro-, and macroscale are discussed. Then, approaches to attain synergetic contribution of all lengthscales through a complex and biomimetic hierarchical structure are reviewed. The processing methods and their design capabilities are presented and the mechanical properties of the materials they can produce are analysed. Their limitations and challenges are finally discussed to suggest new directions for the fabrication of biomimetic bone implants with satisfactory properties. The paper could help biomedical researchers, materials scientists and engineers to join forces to create the next generation of bone implants.