| Popis: |
Biofouling represents a critical challenge in marine transportation, healthcare, and food manufacturing, among other industries, as it promotes contamination and increases maintenance costs. Zwitterionic polymers, known for their exceptional antifouling properties, offer a promising solution for biofouling deterrence. Despite the rapid development of zwitterionic polymers in recent years, the design rules, especially concerning the choice of cationic moieties to optimize biofouling deterrence, remain elusive. In this study, we leveraged a versatile all-dry synthesis scheme to achieve a selection of 9 zwitterionic polymers, 5 of which are unprecedented for this synthesis paradigm, thus systematically unraveling that molecular design rule. Notably, we developed a synthesis strategy to enable nanoscale compositional gradient along the coating cross-section, which ensures the robustness of the zwitterionic polymer coatings irrespective of the choice of cation-anion combinations. That robustness is enabled by an organosilicon-based layer at the coating-substrate interface, which simultaneously enhances coating adhesion and chemical stability while ensuring high concentration of zwitterionic moieties at the polymer-liquid interface to maximize biofouling deterrence. The antifouling efficacy was assessed using biofilms of Pseudomonas aeruginosa or Bacillus subtilis. All coatings demonstrated antifouling efficacy, with a novel zwitterionic polymer comprising a combination of imidazolium and carboxyl groups achieving the greatest antibiofilm effects, which we attributed to the strong hydration. This study highlights the coating architecture, i.e., one with nanoscale gradient and varying crosslinking densities, as a valid strategy to render zwitterionic polymers robust coatings and the imidazolium-based carboxybetaine as a promising next-generation antibiofouling chemistry. |
