Biomaterials as Scaffold for Bone Tissue Engineering

Abstract

Almost 20 years after the invention of tissue engineering, autogenous bone grafting has remained the favored strategy for the treatment of bone defects. As an alternative, a vast variety of bone substitutes has been developed and is available for clinical use. The ongoing search for bone substitutes, however, reflects the limitations imposed to both autogenous and allogenous bone grafts as well as to bone substitute materials. The concept of tissue engineering holds great promise for the future treatment of osseous defects. Research in this interdisciplinary field is carried out to find a way of producing biologic substitutes as functional tissue replacement. For this, functionally active cells are applied on supporting scaffolds under controlled stimulation with growth factors. Scaffolds are temporary matrices for bone growth and provide a specific environment and architecture for tissue development. Ideally, scaffolds favor cellular attachment, growth and differentiation in vitro and in vivo. Especially ceramics and biodegradable polymers are widely used and have been tested in various animal studies. Yet, to allow for precise production of specific custom-made scaffolds, rapid prototyping (RP) techniques have recently drawn a lot of attention. Using these methods scaffolds with a predefined, well-controlled internal and external architecture mimicking the structure of natural bone can be generated. Although biocompatibility of the materials used in the process and the structural resolution that can be technically achieved so far limit the range of use, rapid manufacturing techniques do offer great opportunities to generate suitable scaffolds for bone tissue engineering in the near future.