Litcius/Paper detail

The design and development of short peptide-based novel smart materials to prevent fouling by the formation of non-toxic and biocompatible coatings

Amutha Arul, Subramaniyam Sivagnanam, Ananta Dey, Oindrilla Mukherjee, Soumyajit Ghosh, Priyadip Das

2020RSC Advances25 citationsDOIOpen Access PDF

Abstract

the bi-dentate coordination of dicarboxylate groups and (iii) exhibit antifouling activity and generate a non-toxic biocompatible supramolecular coating on the desired surface. PA1 having aspartic acid as the anchoring moiety exhibits better antifouling activity compared to PA2 that has glutamic acid as the anchoring moiety. This is probably due to the greater adhesive force or binding affinity of aspartic acid to the examined surface compared to that of glutamic acid, as confirmed by force measurement studies using AFM. Most importantly, the simple drop-coating method promises great advantages due to its ease of operation, which leads to a reduction in the production cost and increase in the scope of commercialization. To the best of our knowledge, this is the first attempt to develop an ultra-short peptide-based smart antifouling material with a dicarboxylate group as the surface binding moiety. Furthermore, these findings promise to provide further insights into antifouling mechanisms in the future by the development of a smart material using a dicarboxylate group as an anchoring moiety.

Topics & Concepts

Biocompatible materialFoulingNanotechnologyChemistryPeptideMaterials scienceChemical engineeringEngineeringBiomedical engineeringBiochemistryMembranePolymer Surface Interaction StudiesMarine Biology and Environmental ChemistryBone Tissue Engineering Materials