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Carbon-based Hierarchical Scaffolds for Myoblast Differentiation: Synergy Between Nano-functionalization and Alignment

Overview
Journal Acta Biomater
Publisher Elsevier
Specialty Biomedical Engineering
Date 2016 Jan 16
PMID 26768231
Citations 21
Authors
Akhil Patel
Shilpaa Mukundan
Wenhu Wang
Anil Karumuri
Vinayak Sant
Sharmila M Mukhopadhyay
Shilpa Sant
Affiliations
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Abstract

Statement Of Significance: Due to limited regenerative potential of skeletal muscle, strategies stimulating regeneration of functional muscles are important. These strategies are aimed at promoting differentiation of progenitor cells (myoblasts) into multinucleated myotubes, a key initial step in functional muscle regeneration. Recent tissue engineering approaches utilize various scaffolds ranging from decellularized matrices to aligned biomaterial scaffolds. Although, majority of them have focused on nano- or microscale organization, a systematic approach to build the multiscale hierarchy into these scaffolds is lacking. Here, we engineered multiscale hierarchy into carbon-based materials and demonstrated that the nanoscale features govern the differentiation of individual myoblasts into myocytes whereas microscale alignment cues orchestrate fusion of multiple myocytes into multinucleated myotubes underlining the importance of multiscale hierarchy in enhancing coordinated tissue regeneration.

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