Journal article

Growth, collapse, and stalling in a mechanical model for neurite motility

Abstract:: Neurites, the long cellular protrusions that form the routes of the neuronal network are capable to actively extend during early morphogenesis or to regenerate after trauma. To perform this task, they rely on their cytoskeleton for mechanical support. In this paper, we present a threecomponent active gel model that describes neurites in the three robust mechanical states observed experimentally: collapsed, static, and motile. These states arise from an interplay between the physical forces driven by growth of the microtubule-rich inner core of the neurite and the actomyosin contractility of its surrounding cortical membrane. In particular, static states appear as a mechanical traction/compression balance of these two parallel structures. The model predicts how the response of a neurite to a towing force depends on the force magnitude and recovers the response of neurites to several drug treatments that modulate the cytoskeleton active and passive properties.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Recho, P., Jerusalem, A., & Goriely, A. (2016). Growth, collapse, and stalling in a mechanical model for neurite motility. Physical Review E, 93(3).

MLA Style

Recho, P., et al. “Growth, Collapse, and Stalling in a Mechanical Model for Neurite Motility.” Physical Review E, vol. 93, no. 3, American Physical Society, 2016.

Chicago Style

Recho, P, A Jerusalem, and A Goriely. 2016. “Growth, Collapse, and Stalling in a Mechanical Model for Neurite Motility.” Physical Review E 93 (3).
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Files:: Growth collapse and stalling in a mechanical model for neurite...

(Preview, Accepted manuscript, pdf, 1.2MB, Terms of use)

Publisher copy:: 10.1103/PhysRevE.93.032410

Authors

+ Recho, P More by this author

Role:: Author

+ Jerusalem, A More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Engineering Science
Role:: Author

+ Goriely, A More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Mathematical Institute
Role:: Author

+ Royal Society More from this funder

Funding agency for:: Goriely, A
Grant:: Wolfson Research Merit Award

+ European Research Council More from this funder

Funding agency for:: Jerusalem, A
Grant:: 306587

Publisher:: American Physical Society
Journal:: Physical Review E More from this journal
Volume:: 93
Issue:: 3
Article number:: 032410
Publication date:: 2016-01-01
Acceptance date:: 2016-02-24
DOI:: 10.1103/PhysRevE.93.032410
EISSN:: 2470-0053
ISSN:: 2470-0045

Pubs id:: pubs:613753
UUID:: uuid:77271a9c-9dd2-48cb-8f15-748ad763a212
Local pid:: pubs:613753
Source identifiers:: 613753
Deposit date:: 2016-04-05

Terms of use

Copyright holder:: American Physical Society
Copyright date:: 2016
Notes:: Copyright © 2016 American Physical Society.

Licence:: Terms and Conditions of Use for Oxford University Research Archive

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