Exploiting biomechanics to direct the formation of nervous tissue

Exploiting biomechanics to direct the formation of nervous tissue

Forces and displacements play essential roles in the development and maintenance of all living organisms. The biomechanics in living systems includes traction in cell motility, motor proteins driving cellular transport, tensegrity of the cytoskeleton, and mechanotransduction of signal pathways. In t...

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Bibliographic Details
Published in:Current opinion in biomedical engineering Vol. 14; pp. 59 - 66
Main Authors: Pfister, Bryan J., Grasman, Jonathan M., Loverde, Joseph R.
Format: Journal Article
Language:English
Published: Elsevier Inc 01-06-2020
Subjects:
Directional scaffolding
Durotaxis
Mechanotransduction
Nerve development
Nerve growth
Stretch growth
Tension
Durotaxis
Directional scaffolding
Stretch growth
Mechanotransduction
Tension
Nerve growth
Nerve development
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Summary:Forces and displacements play essential roles in the development and maintenance of all living organisms. The biomechanics in living systems includes traction in cell motility, motor proteins driving cellular transport, tensegrity of the cytoskeleton, and mechanotransduction of signal pathways. In the past few decades, we have learned a great deal about how biomechanics is important in the development, maintenance, and repair of the nervous system. In this review, we critically assess recent advances in using mechanical stimuli toward exploiting the directed growth and formation of nervous tissues. We discuss current systems that recapitulate the mechanical environment surrounding neural tissues as engineering solutions to explore the relationship forces play in modifying neurons and their processes, as well as exploit these processes to enhance regeneration and repair.
ISSN:2468-4511
2468-4511
DOI:10.1016/j.cobme.2020.05.009