RESUMEN
The development of durable and eco-friendly coatings with excellent adhesion and remarkable surface properties remains a critical pursuit in various industries. This study introduces an innovative methodology for the synthesis of glycidyl methacrylate-co-fluorinated methacrylate (P(GMA-co-FMA)) random copolymers with variable fluorine contents derived from GMA and FMA monomers. The copolymerization of these constituents yields coatings with enhanced durability and unique surface characteristics. Particularly, the incorporation of FMA introduces novel surface functionalities, leading to high water and oil repellent properties. The copolymer-coated surfaces exhibited impressive water contact angles ranging from 105° to 125° and decane contact angles ranging from 50° to 85°. The wettability of the P(GMA-co-FMA) coatings demonstrated a strong dependence on the fluorine content in the copolymers, with higher fluorine content resulting in superior water and oil repellency. Through a comprehensive characterization, we demonstrate the exceptional adhesion and self-cleaning capabilities of the fabricated films. Notably, the self-cleaning efficacy of P(GMA-co-FMA)-coated surfaces persists even following a prolonged duration of 6 months. Furthermore, our investigation reveals the influence of copolymer composition on surface wettability and contact angle hysteresis, providing valuable insights for tailoring coating properties. Overall, the novelty of this study lies in the synthesis of P(GMA-co-FMA) copolymer coatings with superior adhesion and self-cleaning properties. These advancements present promising applications in various fields, including electronics, textiles, and medical supplies, where such durable and functional coatings can significantly enhance product performance and longevity.
RESUMEN
The presence of a variety of bacteria is an inevitable/indispensable part of human life. In particular, for patients, the existence and spreading of bacteria lead to prolonged treatment period with many more complications. The widespread use of urinary catheters is one of the main causes for the prevalence of infections. The necessity of long-term use of indwelling catheters is unavoidable in terms of the development of bacteriuria and blockage. As is known, since a permanent solution to this problem has not yet been found, research and development activities continue actively. Herein, polyethylene glycol (PEG)-like thin films were synthesized by a custom designed plasma enhanced chemical vapor deposition (PE-CVD) method and the long-term effect of antifouling properties of PEG-like coated catheters was investigated against Escherichia coli and Proteus mirabilis. The contact angle measurements have revealed the increase of wettability with the increase of plasma exposure time. The antifouling activity of surface-coated catheters was analyzed against the Gram-negative/positive bacteria over a long-term period (up to 30 days). The results revealed that PE-CVD coated PEG-like thin films are highly capable of eliminating bacterial attachment on surfaces with relatively reduced protein attachment without having any toxic effect. Previous statements were supported with SEM, XPS, FTIR spectroscopy, and contact angle analysis.