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Molecular basis of mechanotransduction in living cells
O. P. Hamill
, B. Martinac
Neuroscience & Cell
Research output
:
Contribution to journal
›
Review article
›
peer-review
959
Scopus citations
Overview
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Dive into the research topics of 'Molecular basis of mechanotransduction in living cells'. Together they form a unique fingerprint.
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Keyphrases
Mechanosensitivity
100%
Living Cells
100%
Animal Cells
100%
Mechanotransduction
100%
Lipid Bilayer
100%
Mechanically Gated Channels
100%
Bilayer Tension
100%
Hydrophobic Mismatch
66%
Transmitter Release
33%
Mechanical Force
33%
Protein Membrane
33%
Cytoskeletal Proteins
33%
Xenopus Oocytes
33%
Cytoskeleton
33%
Lipid Vesicles
33%
Hair Cell
33%
Plant Cells
33%
Tight
33%
Cell Wall
33%
Microvilli
33%
Water Volume
33%
Intracellular Ca2+ Release
33%
Channel Opening
33%
Membrane Curvature
33%
Membrane Blebbing
33%
Membrane Area
33%
Cell-like
33%
Cortical Cytoskeleton
33%
Bacteria Cell
33%
Bilayer Thickness
33%
Elastic Membrane
33%
Curvature Change
33%
Mechanical Deformation
33%
Alamethicin
33%
MscL
33%
Contractile Element
33%
Sudden Change
33%
Bacterial Membrane Proteins
33%
Gramicidin
33%
Energetic Cost
33%
Structural Framework
33%
Patch Formation
33%
Occupied Area
33%
Biochemistry, Genetics and Molecular Biology
Mechanotransduction
100%
Tension
100%
Lipid Bilayer
100%
Mechanosensitivity
75%
Cytoskeleton
50%
Neurotransmitter Release
25%
Energy Transfer
25%
Membrane Protein
25%
Xenopus
25%
Conformation
25%
Membrane Curvature
25%
Microvillus
25%
Blebbing
25%
Cytoskeletal Protein
25%
Gramicidin
25%
Pinnipedia
25%
Alamethicin
25%