Abstract
Biomineralization processes such as formation of bones and teeth require controlled mineral deposition and self-assembly into hierarchical biocomposites with unique mechanical properties. Ideal biomaterials for regeneration and repair of hard tissues must be biocompatible, possess micro and macroporosity for vascular invasion, provide surface chemistry and texture that facilitate cell attachment, proliferation, differentiation of lineage specific progenitor cells, and induce deposition of calcium phosphate mineral. To expect in-vivo like cellular response several investigators have used extracellular matrix proteins as templates to recreate in-vivo microenvironment for regeneration of hard tissues. Recently, several novel methods of designing tissue repair and restoration materials using bioinspired strategies are currently being formulated. Nanoscale structured materials can be fabricated via the spontaneous organization of self-assembling proteins to construct hierarchically organized nanomaterials. The advantage of such a method is that polypeptides can be specifically designed as building blocks incorporated with molecular recognition features and spatially distributed bioactive ligands that would provide a physiological environment for cells in-vitro and in-vivo. This is a rapidly evolving area and provides a promising platform for future development of nanostructured templates for hard tissue engineering. In this review we try to highlight the importance of proteins as templates for regeneration and repair of hard tissues as well as the potential of peptide based nanomaterials for regenerative therapies.
Highlights
Tissue engineering is the ability to engineer biological activity into synthetic or natural materials in order to repair damaged tissues or regenerate tissues de-novo
Natural bone and dentin is a 2 phase porous composite material composed of a mineral phase of hydroxyapatite and a soft hydrogel reinforcing phase made of mainly type I collagen [8] (Fig. 1A&B)
Some of the common extracellular matrix (ECM) proteins used in hard tissue engineering are highlighted below
Summary
Tissue engineering is the ability to engineer biological activity into synthetic or natural materials in order to repair damaged tissues or regenerate tissues de-novo. It is a multidisciplinary field involving biology, medicine and engineering and this combined consortium aims to improve the health and quality of life for millions of people. In Greek mythology the regrowth of Prometheus liver has become a classical paradigm to researchers for the possible renewal of damaged human organs
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