: The main aim of this work is to account for the prevention and control of microbial growth on surfaces of interest in medical technology. Surface modification is often achieved by physiotherapy or chemical treatments that can involve time-consuming steps, hazardous reagents, and harsh conditions. One of the ways to overcome these drawbacks is the use of surface-active proteins such as hydrophobins. They can form stable protein layers on different surfaces, serving as anchoring points for other molecules of interest. The fungal hydrophobin Vmh2, already exploited for its adhesive ability, has been fused with the antimicrobial peptide GKY20, forming the chimeric protein used herein for functionalizing polystyrene (PS) and bacterial cellulose (BC). As a natural biomass, BC has multiple advantages, including biodegradability, low cost, renewability, high purity, and excellent mechanical properties. The chimeric protein has been proven to successfully adhere to both surfaces. A strong decrease in biofilm formation on PS and a good bactericidal effect of BC have been demonstrated. These findings provide evidence of an alternative strategy to obtain functional composites using a green, easy process.
Antimicrobial Functionalization of Surfaces by a Chimeric Adhesive Protein / Pitocchi, Rossana; Pennacchio, Anna; Zuber, Flavia; Ren, Qun; Notomista, Eugenio; Campioni, Silvia; Nyström, Gustav; Giardina, Paola; Piscitelli, Alessandra. - In: ACS APPLIED BIO MATERIALS. - ISSN 2576-6422. - (2024). [10.1021/acsabm.4c00760]
Antimicrobial Functionalization of Surfaces by a Chimeric Adhesive Protein
Pitocchi, Rossana;Pennacchio, Anna;Notomista, Eugenio;Giardina, Paola;Piscitelli, Alessandra
Ultimo
2024
Abstract
: The main aim of this work is to account for the prevention and control of microbial growth on surfaces of interest in medical technology. Surface modification is often achieved by physiotherapy or chemical treatments that can involve time-consuming steps, hazardous reagents, and harsh conditions. One of the ways to overcome these drawbacks is the use of surface-active proteins such as hydrophobins. They can form stable protein layers on different surfaces, serving as anchoring points for other molecules of interest. The fungal hydrophobin Vmh2, already exploited for its adhesive ability, has been fused with the antimicrobial peptide GKY20, forming the chimeric protein used herein for functionalizing polystyrene (PS) and bacterial cellulose (BC). As a natural biomass, BC has multiple advantages, including biodegradability, low cost, renewability, high purity, and excellent mechanical properties. The chimeric protein has been proven to successfully adhere to both surfaces. A strong decrease in biofilm formation on PS and a good bactericidal effect of BC have been demonstrated. These findings provide evidence of an alternative strategy to obtain functional composites using a green, easy process.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.