We have set forth a design strategy for creating biomimetic materials that direct the formation of tissue surrounding implants or regeneration within porous scaffolds. Our studies have established that heterogeneous mimetic peptide surfaces (MPS) containing both the -RGD- (cell-binding) and-FHRRIKA- (putative heparin-binding) peptides, unique to BSP, in the ratio of 75:25 (MPS II) or 50:50 (MPS III) proved to be more biologically relevant and specific for RCO cell function. The initial response of human osteoblast-like cells to these surfaces was mediated by the collagen (alpha 2 beta 1) and vitronectin receptors (alpha v beta 3), whereas the vitronectin receptor alone dominated longer-term events (> 30 min). MPS II and III surfaces enhanced cell spreading and long-term events such as mineralization of the extracellular matrix compared to homogenous peptide surfaces and controls. Furthermore, extensive mineralization of the ECM deposited by RCOs occurred when the peptide was coupled to an interfacial interpenetrating polymer network (IPN) that resisted protein deposition (i.e., non-specific adsorption) and fouling. Work on thermo-reversible P(NIPAAm-co-AAc) hydrogels demonstrated the ability to create materials that can be delivered to the body in a minimally invasive manner and support tissue regeneration. These hydrogels can be modified to incorporate biofunctional components such as the biomimetic peptides, theoretically enhancing their ability to foster tissue regeneration. These results suggest that biomaterials can be engineered to mimic ECM components of bone (e.g., various organs) by grafting peptides in the appropriate ratios of the cell and heparin-binding domains, and ultimately modulate the expression of the osteoblast cell phenotype. Approaches similar to the one presented in this work can be used to design materials for hybrid artificial organs and other tissues.