Electroactive Calcium-alginate/polycaprolactone/reduced Graphene Oxide Nanohybrid Hydrogels for Skeletal Muscle Tissue Engineering

Overview

Journal Colloids Surf B Biointerfaces

Publisher Elsevier

Specialty Chemistry

Date 2022 Mar 19

PMID 35305322

Authors

J L Aparicio-Collado

N Garcia-San-Martin

J Molina-Mateo

C Torregrosa Cabanilles

V Donderis Quiles

A Serrano-Aroca

R Sabater I Serra

Affiliations

Soon will be listed here.

Abstract

Graphene derivatives such as reduced graphene oxide (rGO) are used as components of novel biomaterials for their unique electrical properties. Electrical conductivity is a crucial factor for muscle cells, which are electrically active. This study reports the development of a new type of semi-interpenetrated polymer network based on two biodegradable FDA-approved biomaterials, sodium alginate (SA) and polycaprolactone (PCL), with Ca ions as SA crosslinker. Several drawbacks such as the low cell adhesion of SA and weak structural stability can be improved with the incorporation of PCL. Furthermore, this study demonstrates how this semi-IPN can be engineered with rGO nanosheets (0.5% and 2% wt/wt rGO nanosheets) to produce electroactive nanohybrid composite biomaterials. The study focuses on the microstructure and the enhancement of physical and biological properties of these advanced materials, including water sorption, surface wettability, thermal behavior and thermal degradation, mechanical properties, electrical conductivity, cell adhesion and myogenic differentiation. The results suggest the formation of a complex nano-network with different interactions between the components: bonds between SA chains induced by Ca ions (egg-box model), links between rGO nanosheets and SA chains as well as between rGO nanosheets themselves through Ca ions, and strong hydrogen bonding between rGO nanosheets and SA chains. The incorporation of rGO significantly increases the electrical conductivity of the nanohybrid hydrogels, with values in the range of muscle tissue. In vitro cultures with C2C12 murine myoblasts revealed that the conductive nanohybrid hydrogels are not cytotoxic and can greatly enhance myoblast adhesion and myogenic differentiation. These results indicate that these novel electroactive nanohybrid hydrogels have great potential for biomedical applications related to the regeneration of electroactive tissues, particularly in skeletal muscle tissue engineering.

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