- New
-
Topics
- All Categories
- Metaphysics and Epistemology
- Value Theory
- Science, Logic, and Mathematics
- Science, Logic, and Mathematics
- Logic and Philosophy of Logic
- Philosophy of Biology
- Philosophy of Cognitive Science
- Philosophy of Computing and Information
- Philosophy of Mathematics
- Philosophy of Physical Science
- Philosophy of Social Science
- Philosophy of Probability
- General Philosophy of Science
- Philosophy of Science, Misc
- History of Western Philosophy
- Philosophical Traditions
- Philosophy, Misc
- Other Academic Areas
- Journals
- Submit material
- More
High frequency force generation in outer hair cells from the mammalian ear
Bioessays 13 (3):115-120 (1991)
Abstract
Mammalian outer hair cells generate mechanical forces at acoustic frequencies and can thus amplify the sound stimulus within the inner ear. The mechanism of force generation depends upon the plasma membrane potential but not upon either calcium or ATP. Forces are generated in the lateral cortex along the full length of the cell. The cortex includes a two‐dimensional cytoskeletal lattice composed of circumferential filaments 6–7 nm thick that are cross‐linked by filaments 3–4 nm thick and 40–60 nm long. The two filament types may, respectively, be actin and some form of spectrin. The lattice reinforces the cylindrical shape of the cell and permits limited changes in length. Beneath it lie the lateral cisternae, a regular system of multi‐layered membranes. Force–generation may depend upon voltage‐dependent shape changes in proteins that lie either in the plasma membrane or in the cytoskeletal lattice.Other Versions
No versions found
My notes
Similar books and articles
Entropic forces drive contraction of cytoskeletal networks.Marcus Braun, Zdenek Lansky, Feodor Hilitski, Zvonimir Dogic & Stefan Diez - 2016 - Bioessays 38 (5):474-481.
Actin filaments and photoreceptor membrane turnover.David S. Williams - 1991 - Bioessays 13 (4):171-178.
The Mechanical Role of Microtubules in Tissue Remodeling.Maja Matis - 2020 - Bioessays 42 (5):1900244.
The membrane skeleton – A distinct structure that regulates the function of cells.Joan E. B. Fox & Janet K. Boyles - 1988 - Bioessays 8 (1):14-18.
Crosstalk between Cell Adhesion Complexes in Regulation of Mechanotransduction.Alba Zuidema, Wei Wang & Arnoud Sonnenberg - 2020 - Bioessays 42 (11):2000119.
Do Cell Membranes Flow Like Honey or Jiggle Like Jello?Adam E. Cohen & Zheng Shi - 2020 - Bioessays 42 (1):1900142.
An extracellular driving force of cell‐shape changes.Otto Schmidt & Ulrich Theopold - 2004 - Bioessays 26 (12):1344-1350.
Actomyosin forces in cell migration: Moving beyond cell body retraction.Kai Weißenbruch & Roberto Mayor - 2024 - Bioessays 46 (10):2400055.
Neutrophil chemoattractant receptors and the membrane skeleton.Karl-Norbert Klotz & Algirdas J. Jesaitis - 1994 - Bioessays 16 (3):193-198.
Analytics
Added to PP
2014-01-19
Downloads
16 (#1,191,247)
6 months
3 (#1,470,638)
2014-01-19
Downloads
16 (#1,191,247)
6 months
3 (#1,470,638)
Historical graph of downloads
PhilPapers logo by Andrea Andrews and Meghan Driscoll.
This site uses cookies and Google Analytics (see our terms & conditions for details regarding the privacy implications). Use of this site is subject to terms & conditions.
All rights reserved by The PhilPapers Foundation
Server: philpapers-web-667477cd97-sfdq8 dc2