Add to ORKGWhile several scaffolds have been proposed for skeletal muscle regeneration, multiscale hierarchical scaffolds with the complexity of extracellular matrix (ECM) haven’t been engineered successfully. By precise control over nano- and microscale features, comprehensive understanding of the effect of multiple factors on skeletal muscle regeneration can be derived. In this study, we engineered carbon-based scaffolds with hierarchical nano- and microscale architecture with controlled physico-chemical properties. More specifically, we built multiscale hierarchy by growing carbon nanotube (CNT) carpets on two types of scaffolds, namely, interconnected microporous carbon foams and aligned carbon fiber mats. Nanostructured CNT carpets offered fine c...
The development of new, viable, and functional engineered tissue is a complex and challenging task. ...
Currently, the fabrication of scaffolds for engineered skeletal muscle tissues is unable to reach th...
Tissue engineering combines a scaffold, cells and regulatory signals, reproducing a biomimetic extra...
While several scaffolds have been proposed for skeletal muscle regeneration, multiscale hierarchical...
Recreating native microenvironment and providing appropriate guidance cues are instrumental in the d...
Surface features, such as topographical or chemical cues, can affect cell behavior and morphogenesis...
The engineering of skeletal muscle requires platforms that facilitate the proliferation and maintena...
Proliferation and fusion of myoblasts are needed for the generation and repair of multinucleated ske...
Accepted ManuscriptIn bone tissue engineering, the development of advanced biomimetic scaffolds has ...
Expansion of mesenchymal stem cells (MSCs) and maintenance of their self-renewal capacity in vitro r...
Biological tissues are compositionally and structurally exquisite – a complex network of proteins an...
Skeletal muscle consists of parallel bundles of myotubes formed by the fusion of myoblasts. We fabri...
Skeletal muscles can self-repair minor strains, lacerations, and contusions; however, in cases of vo...
Abstract Biohybrid artificial muscle produced by integrating living muscle cells and their scaffolds...
Cartilage tissue is a nanostructured tissue which is notoriously hard to regenerate due to its extre...
The development of new, viable, and functional engineered tissue is a complex and challenging task. ...
Currently, the fabrication of scaffolds for engineered skeletal muscle tissues is unable to reach th...
Tissue engineering combines a scaffold, cells and regulatory signals, reproducing a biomimetic extra...
While several scaffolds have been proposed for skeletal muscle regeneration, multiscale hierarchical...
Recreating native microenvironment and providing appropriate guidance cues are instrumental in the d...
Surface features, such as topographical or chemical cues, can affect cell behavior and morphogenesis...
The engineering of skeletal muscle requires platforms that facilitate the proliferation and maintena...
Proliferation and fusion of myoblasts are needed for the generation and repair of multinucleated ske...
Accepted ManuscriptIn bone tissue engineering, the development of advanced biomimetic scaffolds has ...
Expansion of mesenchymal stem cells (MSCs) and maintenance of their self-renewal capacity in vitro r...
Biological tissues are compositionally and structurally exquisite – a complex network of proteins an...
Skeletal muscle consists of parallel bundles of myotubes formed by the fusion of myoblasts. We fabri...
Skeletal muscles can self-repair minor strains, lacerations, and contusions; however, in cases of vo...
Abstract Biohybrid artificial muscle produced by integrating living muscle cells and their scaffolds...
Cartilage tissue is a nanostructured tissue which is notoriously hard to regenerate due to its extre...
The development of new, viable, and functional engineered tissue is a complex and challenging task. ...
Currently, the fabrication of scaffolds for engineered skeletal muscle tissues is unable to reach th...
Tissue engineering combines a scaffold, cells and regulatory signals, reproducing a biomimetic extra...