about
The role of mechanotransduction on vascular smooth muscle myocytes' [corrected] cytoskeleton and contractile functionFlow (shear stress)-induced endothelium-dependent dilation is altered in mice lacking the gene encoding for dystrophinBiomechanical regulation of hedgehog signaling in vascular smooth muscle cells in vitro and in vivoTyrosine phosphorylation following alterations in arteriolar intraluminal pressure and wall tension.Endothelin and nitric oxide mediate reduced myogenic reactivity of small renal arteries from pregnant rats.Nitric oxide-mediated arteriolar dilation after endothelial deformation.Control of microtubule assembly by extracellular matrix and externally applied strain.Effects of synergistic massage and physical exercise on the expression of angiogenic markers in rat tendons.A silicone-based stretchable micropost array membrane for monitoring live-cell subcellular cytoskeletal responseForcing stem cells to behave: a biophysical perspective of the cellular microenvironment.Effects of pregnancy, hypertension and nitric oxide inhibition on rat uterine artery myogenic reactivityInvited review: arteriolar smooth muscle mechanotransduction: Ca(2+) signaling pathways underlying myogenic reactivity.Cellular signalling in arteriolar myogenic constriction: involvement of tyrosine phosphorylation pathways.Molecular control of capillary growth in skeletal muscle.20-Hydroxyeicosatetraenoic acid potentiates stretch-induced contraction of canine basilar artery via PKC alpha-mediated inhibition of KCa channel.The first three minutes: smooth muscle contraction, cytoskeletal events, and soft glasses.Alteration by lipopolysaccharide of the relationship between intracellular calcium levels and contraction in rat mesenteric artery.Differential effects of substrate modulus on human vascular endothelial, smooth muscle, and fibroblastic cellsImpaired flow-induced dilation in mesenteric resistance arteries from mice lacking vimentin.Interactions of airway smooth muscle cells with their tissue matrix: implications for contractionRole of elevated EGFR phosphorylation in the induction of structural remodelling and altered mechanical properties of resistance artery from type 2 diabetic miceLocal uteroplacental influences are responsible for the induction of uterine artery myogenic tone during rat pregnancy.Fibroblasts contracting collagen matrices form transient plasma membrane passages through which the cells take up fluorescein isothiocyanate-dextran and Ca2+Nanoengineered Platforms to Guide Pluripotent Stem Cell Fate.Regulation of Mitochondrial Structure and Dynamics by the Cytoskeleton and Mechanical Factors.Regulatory Roles of Fluctuation-Driven Mechanotransduction in Cell FunctionDifferential inhibition by hyperglycaemia of shear stress- but not acetylcholine-mediated dilatation in the iliac artery of the anaesthetized pig.Reduction of renal mass is lethal in mice lacking vimentin. Role of endothelin-nitric oxide imbalanceThe effects of matrix stiffness and RhoA on the phenotypic plasticity of smooth muscle cells in a 3-D biosynthetic hydrogel system.Induction of apoptosis in vascular smooth muscle cells by mechanical stretch.Attenuation of pressure-induced myogenic contraction and tyrosine phosphorylation by fasudil, a cerebral vasodilator, in rat cerebral artery.A new experimental approach in endothelium-dependent pharmacological investigations on isolated porcine coronary arteries mounted for impedance planimetry.Computational modeling of hypertensive growth in the human carotid artery.Effects of cyclic strain and growth factors on vascular smooth muscle cell responses.Actin cytoskeletal modulation of pressure-induced depolarization and Ca(2+) influx in cerebral arteries.Different roles of PKC and MAP kinases in arteriolar constrictions to pressure and agonists.Delayed arteriolar relaxation after prolonged agonist exposure: functional remodeling involving tyrosine phosphorylation.Intraluminal pressure stimulates MAPK phosphorylation in arterioles: temporal dissociation from myogenic contractile response.Regulation of expression and activity of four PKC isozymes in confluent and mechanically stimulated UMR-108 osteoblastic cells.Mathematical modeling of collagen turnover in biological tissue.
P2860
Q27026682-31DCFF1B-96F1-45F1-B69E-11C3EE41521EQ28348557-83E36F03-0D9C-4289-8619-5B9AC861FD8FQ28574693-3C516BD6-0938-4EE4-BD25-89C5D7EBEE4AQ31004413-685ED877-DE88-4735-A3C5-7610F4905535Q31731441-C15C5062-B0DB-4D1D-9C1F-A1AE68DA911DQ31833735-088D0578-F602-4692-9090-7D20A75D9ABEQ31919408-7811FBAD-79DA-48A5-AB78-055046289C80Q33679182-29FA3AE0-0191-4782-AB8E-8D47A4DE8FBCQ33994720-C1C107B5-D8CB-40F8-B299-A3BFF8E2D752Q34009916-2E3B70A7-09D3-4FF8-86A1-33430D21CD8BQ34154020-0246EEB2-C2F0-409C-BD9D-937573AD60C8Q34310359-D19EC996-726C-4A10-8457-E615A03545EFQ34680789-47C1CA2B-BA10-4637-AB61-464E19465D43Q34995545-79DB6198-67D6-43FB-85BD-EE4D9DEF8818Q35044798-A6EEBD17-8F74-4927-B276-F4AA072D888EQ35148551-08AF45E5-E50B-4134-AE16-A58614274EDCQ35873660-C0A08980-6B11-4188-B0CC-479768D9849EQ35955696-8911205F-0C3C-402F-BA33-B257E7B7449AQ36894216-F2A9CDC7-898C-433B-B772-98A300437B2EQ37038045-8DE7E688-8AA7-430D-A94C-752E9F3E8ABEQ37287730-769774D8-9539-449D-B409-1BB716B7FC05Q37382272-DF9E24DC-6D5A-4FFA-AFF8-B39CB80068A9Q37384244-C0E42505-10A8-4402-A3B5-86585E7F4091Q38600209-B52C70DF-C2DD-431A-B65A-FFB2D3E4538DQ38616278-B1FF378D-FE51-4E88-BED6-69CCD0526F43Q38924290-2F1090D1-228A-4B1A-85AA-0619173FFDD0Q39133016-D8EC2CBE-A7BC-4BE0-A5EA-774F0B221BA8Q39790972-E4C20D7F-E25F-4A2D-9F41-367734D96561Q40035512-BC3F46B4-AF02-4075-8F18-60DC6B818146Q40737542-853A99FA-0609-4915-973C-BA47C283A532Q41784902-6A175291-ADBA-4953-9D54-DDF29C1D465EQ41902656-502282BD-D5EC-4273-851B-35D9FB02B63DQ41949843-E99EEE39-1DF7-43AD-AE5E-1EB878F0F291Q42077021-5AEB30E7-92A4-4CF0-A243-018CBC27F7E0Q43917364-FEDC245B-A2DD-4F79-BD64-A8768D493208Q44213320-B8911CE2-F2AB-4A51-BD69-1C7BD23A4F4EQ44417036-1B56BA62-5EF8-49D0-8D2D-A27F1E65E4B1Q44477005-EF909DEC-BE10-4283-985B-73AF7E0B1D76Q44884059-30C5F2B0-7B51-440D-9156-9752B0123E34Q45077001-DAEE598F-89BC-4A78-83BD-A6EECCF78024
P2860
description
1995 nî lūn-bûn
@nan
1995年の論文
@ja
1995年学术文章
@wuu
1995年学术文章
@zh-cn
1995年学术文章
@zh-hans
1995年学术文章
@zh-my
1995年学术文章
@zh-sg
1995年學術文章
@yue
1995年學術文章
@zh
1995年學術文章
@zh-hant
name
Mechanotransduction by vascular smooth muscle.
@en
type
label
Mechanotransduction by vascular smooth muscle.
@en
prefLabel
Mechanotransduction by vascular smooth muscle.
@en
P356
P1476
Mechanotransduction by vascular smooth muscle.
@en
P2093
P304
P356
10.1159/000159102
P577
1995-09-01T00:00:00Z