Bioengineering of skeletal muscle in vitro in order to produce highly aligned myofibres in relevant three dimensional (3D) matrices have allowed scientists to model the in vivo skeletal muscle niche. This review discusses essential experimental considerations for developing bioengineered muscle in order to investigate exercise mimicking stimuli. We identify current knowledge for the use of electrical stimulation and co-culture with motor neurons to enhance skeletal muscle maturation and contractile function in bioengineered systems in vitro. Importantly, we provide a current opinion on the use of acute and chronic exercise mimicking stimuli (electrical stimulation and mechanical overload) and the subsequent mechanisms underlying physiologic...
Advanced in vitro models of human skeletal muscle tissue are increasingly needed to model complex de...
Engineering models of human skeletal muscle tissue provides unique translational opportunities to in...
PURPOSE OF REVIEW: Cell based muscle tissue engineering carries the potential to revert the function...
Bioengineering of skeletal muscle in vitro in order to produce highly aligned myofibres in relevant ...
The bioengineering of skeletal muscle tissue in-vitro has enabled researchers to more closely mimic ...
The bioengineering of skeletal muscle tissue in-vitro has enabled researchers to more closely mimic ...
Research within exercise physiology has traditionally focused upon measurements of gross physiologic...
Skeletal muscle is the most abundant tissue in the lean human body and is responsible for all motor ...
Cellular and molecular exercise physiology is the study of the underlying regulatory mechanisms that...
Muscular dystrophies are a group of highly disabling disorders that share degenerative muscle weakne...
In native skeletal muscle, densely packed myofibers exist in close contact with surrounding motor ne...
Purpose of review: To highlight recent breakthroughs and controversies in the use of myoblast models...
Classical approaches to engineer skeletal muscle tissue based on current regenerative and surgical p...
Recent advances in skeletal muscle tissue engineering have resulted in an in vitro tissue model that...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2019Cat...
Advanced in vitro models of human skeletal muscle tissue are increasingly needed to model complex de...
Engineering models of human skeletal muscle tissue provides unique translational opportunities to in...
PURPOSE OF REVIEW: Cell based muscle tissue engineering carries the potential to revert the function...
Bioengineering of skeletal muscle in vitro in order to produce highly aligned myofibres in relevant ...
The bioengineering of skeletal muscle tissue in-vitro has enabled researchers to more closely mimic ...
The bioengineering of skeletal muscle tissue in-vitro has enabled researchers to more closely mimic ...
Research within exercise physiology has traditionally focused upon measurements of gross physiologic...
Skeletal muscle is the most abundant tissue in the lean human body and is responsible for all motor ...
Cellular and molecular exercise physiology is the study of the underlying regulatory mechanisms that...
Muscular dystrophies are a group of highly disabling disorders that share degenerative muscle weakne...
In native skeletal muscle, densely packed myofibers exist in close contact with surrounding motor ne...
Purpose of review: To highlight recent breakthroughs and controversies in the use of myoblast models...
Classical approaches to engineer skeletal muscle tissue based on current regenerative and surgical p...
Recent advances in skeletal muscle tissue engineering have resulted in an in vitro tissue model that...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2019Cat...
Advanced in vitro models of human skeletal muscle tissue are increasingly needed to model complex de...
Engineering models of human skeletal muscle tissue provides unique translational opportunities to in...
PURPOSE OF REVIEW: Cell based muscle tissue engineering carries the potential to revert the function...