A widely accepted tenet of biomaterials research is that the initial step following contact of a synthetic material with blood is the rapid adsorption of plasma proteins. The composition of this adsorbed protein layer is dependent on a variety of factors, including the surface properties of the implant material and the nature of the adsorbing proteins, and the composition and function of this protein layer is important in the subsequent biological response and ultimately the success or failure of the implanted material. While a great amount of effort has gone into developing structure/function responses for implanted biomaterials, there is still much about the molecular level interactions to be determined. We utilized atomic force microscopy (AFM) to investigate the molecular-level interactions of proteins with model biomaterial substrates. The AFM is unique in that it offers the opportunity to characterize interfacial environments, determine material properties, measure protein/surface interaction forces, and visualize the tertiary structure of adsorbed proteins.
Atomic Force Microscopy of the Structure of Red Blood Cell Membranes in Acute Blood Loss and Reinfusion
