Literature DB >> 17660317

Effect of the stress phase angle on the strain energy density of the endothelial plasma membrane.

Shigeru Tada1, Cheng Dong, John M Tarbell.   

Abstract

Endothelial cells are simultaneously exposed to the mechanical forces of fluid wall shear stress (WSS) imposed by blood flow and solid circumferential stress (CS) induced by the blood vessel's elastic response to the pressure pulse. Experiments have demonstrated that these combined forces induce unique endothelial biomolecular responses that are not characteristic of either driving force alone and that the temporal phase angle between WSS and CS, referred to as the stress phase angle, modulates endothelial responses. In this article, we provide the first theoretical model to examine the combined forces of WSS and CS on a model of the endothelial cell plasma membrane. We focus on the strain energy density of the membrane that modulates the opening of ion channels that can mediate signal transduction. The model shows a significant influence of the stress phase angle on the strain energy density at the upstream and downstream ends of the cell where mechanotransduction is most likely to occur.

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Year:  2007        PMID: 17660317      PMCID: PMC2025663          DOI: 10.1529/biophysj.106.100685

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  28 in total

1.  Spatiotemporal analysis of flow-induced intermediate filament displacement in living endothelial cells.

Authors:  B P Helmke; D B Thakker; R D Goldman; P F Davies
Journal:  Biophys J       Date:  2001-01       Impact factor: 4.033

2.  Rapid displacement of vimentin intermediate filaments in living endothelial cells exposed to flow.

Authors:  B P Helmke; R D Goldman; P F Davies
Journal:  Circ Res       Date:  2000-04-14       Impact factor: 17.367

3.  Interaction between wall shear stress and circumferential strain affects endothelial cell biochemical production.

Authors:  Y Qiu; J M Tarbell
Journal:  J Vasc Res       Date:  2000 May-Jun       Impact factor: 1.934

4.  Shear stress induces a time- and position-dependent increase in endothelial cell membrane fluidity.

Authors:  P J Butler; G Norwich; S Weinbaum; S Chien
Journal:  Am J Physiol Cell Physiol       Date:  2001-04       Impact factor: 4.249

5.  Mapping mechanical strain of an endogenous cytoskeletal network in living endothelial cells.

Authors:  Brian P Helmke; Amy B Rosen; Peter F Davies
Journal:  Biophys J       Date:  2003-04       Impact factor: 4.033

6.  A three-dimensional viscoelastic model for cell deformation with experimental verification.

Authors:  Hélène Karcher; Jan Lammerding; Hayden Huang; Richard T Lee; Roger D Kamm; Mohammad R Kaazempur-Mofrad
Journal:  Biophys J       Date:  2003-11       Impact factor: 4.033

7.  Coronary endothelium expresses a pathologic gene pattern compared to aortic endothelium: correlation of asynchronous hemodynamics and pathology in vivo.

Authors:  Michael B Dancu; John M Tarbell
Journal:  Atherosclerosis       Date:  2006-06-27       Impact factor: 5.162

8.  Reconstruction of carotid bifurcation hemodynamics and wall thickness using computational fluid dynamics and MRI.

Authors:  David A Steinman; Jonathan B Thomas; Hanif M Ladak; Jaques S Milner; Brian K Rutt; J David Spence
Journal:  Magn Reson Med       Date:  2002-01       Impact factor: 4.668

9.  Strain energy function of red blood cell membranes.

Authors:  R Skalak; A Tozeren; R P Zarda; S Chien
Journal:  Biophys J       Date:  1973-03       Impact factor: 4.033

10.  Microviscoelasticity of the apical cell surface of human umbilical vein endothelial cells (HUVEC) within confluent monolayers.

Authors:  Wolfgang Feneberg; Martin Aepfelbacher; Erich Sackmann
Journal:  Biophys J       Date:  2004-08       Impact factor: 4.033
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  8 in total

1.  Fluid Mechanics, Arterial Disease, and Gene Expression.

Authors:  John M Tarbell; Zhong-Dong Shi; Jessilyn Dunn; Hanjoong Jo
Journal:  Annu Rev Fluid Mech       Date:  2014-01       Impact factor: 18.511

2.  Mechanotransmission in endothelial cells subjected to oscillatory and multi-directional shear flow.

Authors:  Mahsa Dabagh; Payman Jalali; Peter J Butler; Amanda Randles; John M Tarbell
Journal:  J R Soc Interface       Date:  2017-05       Impact factor: 4.118

3.  Shear-induced force transmission in a multicomponent, multicell model of the endothelium.

Authors:  Mahsa Dabagh; Payman Jalali; Peter J Butler; John M Tarbell
Journal:  J R Soc Interface       Date:  2014-09-06       Impact factor: 4.118

4.  Mechanotransduction in Endothelial Cells in Vicinity of Cancer Cells.

Authors:  Alessandra Ebben; Mahsa Dabagh
Journal:  Cell Mol Bioeng       Date:  2022-07-05       Impact factor: 3.337

5.  Stress phase angle depicts differences in coronary artery hemodynamics due to changes in flow and geometry after percutaneous coronary intervention.

Authors:  Ryo Torii; Nigel B Wood; Nearchos Hadjiloizou; Andrew W Dowsey; Andrew R Wright; Alun D Hughes; Justin Davies; Darrel P Francis; Jamil Mayet; Guang-Zhong Yang; Simon A McG Thom; X Yun Xu
Journal:  Am J Physiol Heart Circ Physiol       Date:  2009-01-16       Impact factor: 4.733

6.  The Interaction between Fluid Wall Shear Stress and Solid Circumferential Strain Affects Endothelial Gene Expression.

Authors:  Ronny Amaya; Alexis Pierides; John M Tarbell
Journal:  PLoS One       Date:  2015-07-06       Impact factor: 3.240

7.  Interaction between the Stress Phase Angle (SPA) and the Oscillatory Shear Index (OSI) Affects Endothelial Cell Gene Expression.

Authors:  Ronny Amaya; Limary M Cancel; John M Tarbell
Journal:  PLoS One       Date:  2016-11-15       Impact factor: 3.240

8.  Stress phase angle regulates differentiation of human adipose-derived stem cells toward endothelial phenotype.

Authors:  Shahrokh Shojaei; Mohammad Tafazzoli-Shadpour; Mohammad Ali Shokrgozar; Nooshin Haghighipour; Fatemeh Hejazi Jahromi
Journal:  Prog Biomater       Date:  2018-05-21
  8 in total

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