Facile fabrication of robust superhydrophobic multilayered film based on bioinspired poly(dopamine)-modified carbon nanotubes.

Thin organic films containing carbon nanotubes (CNTs) have received increasing attention in many fields. In this study, a robust thin superhydrophobic film has been created by using layer-by-layer assembly of the carbon nanotubes wrapped by poly(dopamine) (CNT@PDA) and poly(ethyleneimine) (PEI). UV-vis spectroscopy, ellipsometry, and quartz crystal microbalance with dissipation (QCM-D) measurements confirmed that the sequential deposition of PEI and CNT@PDA resulted in a linear growth of the (PEI-CNT@PDA) film. This thin film contained as much as 77 wt% CNTs. Moreover, a very stable and flexible free-standing (PEI-CNT@PDA) film could be obtained by employing cellulose acetate (CA) as a sacrificial layer. The film could even withstand ultrasonication in saturated SDS aqueous solution for 30 min. SEM observations indicated that the ultrathin film consisted of nanoscale interpenetrating networks of entangled CNTs and exhibited a very rough surface morphology. The (PEI-CNT@PDA) film turned superhydrophobic after being coated with a low-surface-energy compound. The superhydrophobic films showed excellent resistance against the adhesion of both platelets and Escherichia coli (E. coli). The (PEI-CNT@PDA) films and the proposed methodology may find applications in the area of medical devices to reduce device-associated thrombosis and infection.

Electropolymerization of dopamine for surface modification of complex-shaped cardiovascular stents.

Inspired by the adhesion strategy of marine mussels, self-polymerization of dopamine under alkaline condition has been proven to be a simple and effective method for surface modification of biomaterials. However, this method still has many drawbacks, such as the use of alkaline aqueous medium, low poly(dopamine) deposition rate, and inefficient utilization of dopamine, which greatly hinder its practical application. In the present study, we demonstrate that electropolymerization of dopamine is a facile and versatile approach to surface tailoring of metallic cardiovascular stents, such as small and complex-shaped coronary stent. Electropolymerization of dopamine leads to the formation of a continuous and smooth electropolymerized poly(dopamine) (ePDA) coating on the substrate surface. This electrochemical method exhibits a higher deposition rate and is more efficient in dopamine utilization compared with the typical self-polymerization method. The ePDA coating facilitates the immobilization of biomolecules onto substrates to engineer biomimetic microenvironments. In vitro and in vivo experiments demonstrate that ePDA coating functionalized with vascular endothelial growth factor can greatly enhance the desired cellular responses of endothelial cells and prevent the neointima formation after stent implantation. The proposed methodology may find applications in the area of metallic surface engineering, especially for the cardiovascular stents and potentially all biomedical devices with electroconductive surface as well.