Litcius/Paper detail

Facile strategy of Fe3+ rich collagen-based composite hydrogel for antibacterial, electricity harvesting and sensing applications

Md. Ashraful Alam, Arup Kumar Debnath, Khandoker Tahmina Tasnim, Shashanka Shekhar Sarker, Md. Tushar Uddin, Sarker Kamruzzaman, Ilnaz Fargul Chowdhury, Md. Tanzil Ahamed Shawon, Zuwu Tang, Ajoy Kanti Mondal

2024Materials Today Communications22 citationsDOIOpen Access PDF

Abstract

Conventional hydrogels have poor conductivity and low stretchability, limiting their practical applications for different purposes. Herein, collagen (CL) based, poly(vinyl alcohol) (PVA) and glutaraldehyde (GT) cross-linked ferric ion (Fe 3+ ) rich highly conductive CL/GT/PVA/Fe hydrogel was developed. The presence of high CL, PVA and Fe 3+ ions, together with the effective Fe 3+ complexes formation, delivers the hydrogel with some particular assigns, such as high ionic conductivity (3.44 S.m −1 ) and antibacterial activity ; furthermore, a very high stretchability. The CL/GT/PVA/Fe hydrogel demonstrated excellent mechanical properties, where the highest tensile strength of the hydrogels was ∼204.5 kPa at an elongation of 674 %, and the highest compressive strength was ∼0.39 MPa, with the highest stretchability of 81.67 %. The strengths are enhanced significantly by the incorporation of Fe 3+ ions because of the formation of effective complexation of Fe 3+ with rich hydroxyl and carboxyl groups of PVA and CL. As a flexible strain sensor, the CL/GT/PVA/Fe hydrogel with excellent conductivity manifests high sensitivity in human motion monitor. The hydrogels’ sufficient –OH and –COOH groups play a key role in imparting moist-induce electricity supply and the highest 173 mV of open circuit voltage (V oc ) generated during moisture spray.

Topics & Concepts

Materials scienceComposite numberComposite materialChemical engineeringNanotechnologyEngineeringSilk-based biomaterials and applications3D Printing in Biomedical ResearchElectrospun Nanofibers in Biomedical Applications