Abstract
Conventionally, complement activation by biomedical polymers has been evaluated by determining the C3a concentration in the fluid phase only. According to this criterion, biomaterials such as hemodialysis membranes made from cellulosic or various synthetic polymers were classified as activators or nonactivators of complement. Since certain membranes bind large quantities of C3a from the fluid phase, classification based on fluid- phase C3a concentration has in some instances been inaccurate. As follows from the comparison of complement activation by cuprophane and polyacrylonitrile membranes, the capacity of a biomedical polymer to activate complement is not determined by the number of potential covalent binding sites on its surface. Biomaterial itself may lack hydroxyl and/or amino groups, and yet it may activate C3 in human serum very efficiently. Some of the biomaterials may also bind unactivated/unfragmented C3 whether in the absence or presence of other serum proteins. In addition, binding of factor B (a promotor of C3 activation) and binding of factor H (an inhibitor of C3 activation) to certain biomaterials have been found to be independent of complement activation and unaffected by the presence or absence of C3. Thus, it is becoming apparent that the requirements for the formation and stability of the C3 convertase on artificial surfaces differ from those on biological membranes, and that the relative magnitude of binding of factor B and factor H to the surface per se cannot be used as a reliable indicator of the capacity of the biomaterial to activate complement. Further studies are necessary to elucidate the molecular mechanisms of C3 and C5 activation on the surfaces of biomedical polymers. Its understanding should lead to the development of new or modification of existing artificial membranes which would cause less adverse effects for patients during extracorporeal procedures.