Biochemical Society Transactions

Publication date: 2009-01
Volume: 37 Pages: 687 - 691
ISSN: 0300-5127, 1470-8752 PMID: 19614576
DOI: 10.1042/BST0370687
Publisher: Portland Press

Author:

Perry, Carole C
Patwardhan, Siddharth V ; Deschaume, Olivier

Keywords:

biomaterial, biomineral, biomolecule, inorganic material, mineral, Science & Technology, Life Sciences & Biomedicine, Biochemistry & Molecular Biology, AMINO-ACIDS, THALASSIOSIRA-PSEUDONANA, NANOMATERIAL SYNTHESIS, BINDING POLYPEPTIDES, PROTEIN ADSORPTION, BARIUM SULFATES, PEPTIDES, SURFACE, SILICA, INTERFACE, Biocompatible Materials, Minerals, Surface Properties, 0601 Biochemistry and Cell Biology, 1101 Medical Biochemistry and Metabolomics

Abstract:

Interactions between inorganic materials and biomolecules at the molecular level, although complex, are commonplace. Examples include biominerals, which are, in most cases, facilitated by and in contact with biomolecules; implantable biomaterials; and food and drug handling. The effectiveness of these functional materials is dependent on the interfacial properties, i.e. the extent of molecular level 'association' with biomolecules. The present article gives information on biomolecule-inorganic material interactions and illustrates our current understanding using selected examples. The examples include (i) mechanism of biointegration: the role of surface chemistry and protein adsorption, (ii) towards improved aluminium-containing materials, and (iii) understanding the bioinorganic interface: experiment and modelling. A wide range of experimental techniques (microscopic, spectroscopic, particle sizing, thermal methods and solution methods) are used by the research group to study interactions between (bio)molecules and molecular and colloidal species that are coupled with computational simulation studies to gain as much information as possible on the molecular-scale interactions. Our goal is to uncover the mechanisms underpinning any interactions and to identify 'rules' or 'guiding principles' that could be used to explain and hence predict behaviour for a wide range of (bio)molecule-mineral systems.