Combating medical device fouling

•Biofouling as a result of thrombus and bacterial biofilms leads to device rejection. •Ideal devices treat the ailment, minimize adverse effects, and aid in regeneration. •Chemical and surface properties of device materials dictates the biological response. •Material design with passive and active approaches can be used to minimize biofouling. •Material integration with tissues and fluids will lead to device incorporation. When interfaced with the biological environment, biomedical devices are prone to surface biofouling due to adhesion of microbial or thrombotic agents as a result of the foreign body response. Surface biofouling of medical devices occurs as a result of nonspecific adhesion of noxious substrates to the surface. Approaches for biofouling-resistant surfaces can be categorized as either the manipulation of surface chemical functionalities or through the incorporation of regulatory biomolecules. This review summarizes current strategies for creating biofouling-resistant surfaces based on surface hydrophilicity and charge, biomolecule functionalization, and drug elution. Reducing the foreign body response and restoring the function of cells around the device minimizes the risk of device rejection and potentially integrates devices with surrounding tissues and fluids. In addition, we discuss the use of peptides and NO as biomolecules that not only inhibit surface fouling, but also promote the integration of medical devices with the biological environment. When interfaced with the biological environment, biomedical devices are prone to surface biofouling due to adhesion of microbial or thrombotic agents as a result of the foreign body response. Surface biofouling of medical devices occurs as a result of nonspecific adhesion of noxious substrates to the surface. Approaches for biofouling-resistant surfaces can be categorized as either the manipulation of surface chemical functionalities or through the incorporation of regulatory biomolecules. This review summarizes current strategies for creating biofouling-resistant surfaces based on surface hydrophilicity and charge, biomolecule functionalization, and drug elution. Reducing the foreign body response and restoring the function of cells around the device minimizes the risk of device rejection and potentially integrates devices with surrounding tissues and fluids. In addition, we discuss the use of peptides and NO as biomolecules that not only inhibit surface fouling, but also promote the integration of medical devices with the biological environment. denotes a material that does not illicit an adverse response when interfaced with a host environment. a complex assembly of microorganisms and proteins that are attached to the surfaces of medical devices, which interfaces with the biological environment. chronic formation of a biofilm on a medical device surface, causing the function of the device to be impaired. a material form, intended to serve a mechanical and physiological function, which is interfaced in a biological system. aggregation of proteins and platelets on a surface that results in the formation of a blood clot. a neutral molecule that contains both positive and negative charges.