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| Q64120635 | Drug-induced activation of integrin alpha IIb beta 3 leads to minor localized structural changes |
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| Q91523081 | Evidence for functional selectivity in TUDC- and norUDCA-induced signal transduction via α5β1 integrin towards choleresis |
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| Q30497295 | Forcing Switch from Short- to Intermediate- and Long-lived States of the αA Domain Generates LFA-1/ICAM-1 Catch Bonds |
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| Q41239491 | In Vivo Cancer Cells Elimination Guided by Aptamer-Functionalized Gold-Coated Magnetic Nanoparticles and Controlled with Low Frequency Alternating Magnetic Field |
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| Q46824098 | Integrin-like allosteric properties of the catch bond-forming FimH adhesin of Escherichia coli |
| Q30423615 | Integrins and extracellular matrix in mechanotransduction |
| Q92349966 | Integrins, CAFs and Mechanical Forces in the Progression of Cancer |
| Q37810633 | Integrins: versatile receptors controlling melanocyte adhesion, migration and proliferation |
| Q30512956 | Lateral mobility of individual integrin nanoclusters orchestrates the onset for leukocyte adhesion |
| Q37360844 | Linking integrin conformation to function |
| Q28115946 | Lymph node chemokines promote sustained T lymphocyte motility without triggering stable integrin adhesiveness in the absence of shear forces |
| Q38127775 | Matrix mechanics and regulation of the fibroblast phenotype |
| Q35699122 | Mechanical force effect on the two-state equilibrium of the hyaluronan-binding domain of CD44 in cell rolling. |
| Q27016079 | Mechanical regulation of T-cell functions |
| Q50120833 | Mechanosensation: A Catch Bond That Only Hooks One Way. |
| Q57591551 | Molecular Dynamics Reveal that isoDGR-Containing Cyclopeptides Are True αvβ3 Antagonists Unable To Promote Integrin Allostery and Activation |
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| Q27334036 | Molecular dynamics simulations of forced unbending of integrin α(v)β₃ |
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| Q38223234 | Non-channel mechanosensors working at focal adhesion-stress fiber complex. |
| Q39862600 | Phenomenological and microscopic theories for catch bonds. |
| Q58688346 | Poly(amidoamine) Hydrogels as Scaffolds for Cell Culturing and Conduits for Peripheral Nerve Regeneration |
| Q37374292 | Protein Mechanics: A New Frontier in Biomechanics |
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| Q34125138 | Regulation of Catch Binding by Allosteric Transitions |
| Q37324659 | Regulation of integrin activity and signalling |
| Q33954244 | Role of altered sialylation of the I-like domain of beta1 integrin in the binding of fibronectin to beta1 integrin: thermodynamics and conformational analyses |
| Q37540219 | Rolling cell adhesion |
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| Q37779877 | Stretchy proteins on stretchy substrates: the important elements of integrin-mediated rigidity sensing |
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| Q43014937 | Structural insight for the roles of fas death domain binding to FADD and oligomerization degree of the Fas-FADD complex in the death-inducing signaling complex formation: a computational study |
| Q30622385 | Structurally governed cell mechanotransduction through multiscale modeling |
| Q36744293 | Structure and mechanics of integrin-based cell adhesion. |
| Q27653293 | Structure of a Complete Integrin Ectodomain in a Physiologic Resting State and Activation and Deactivation by Applied Forces |
| Q41489885 | Subcellular domain-dependent molecular hierarchy of SFK and FAK in mechanotransduction and cytokine signaling |
| Q33348048 | T cell receptor triggering by force |
| Q42582837 | Targeted molecular dynamics reveals overall common conformational changes upon hybrid domain swing-out in beta3 integrins |
| Q64907768 | The Cytoskeleton-A Complex Interacting Meshwork. |
| Q33381441 | The GPIIb/IIIa (integrin alphaIIbbeta3) odyssey: a technology-driven saga of a receptor with twists, turns, and even a bend |
| Q39552692 | The Integrin Receptor in Biologically Relevant Bilayers: Insights from Molecular Dynamics Simulations. |
| Q35751058 | The beta-tail domain (betaTD) regulates physiologic ligand binding to integrin CD11b/CD18 |
| Q90013704 | The bioenergetics of integrin-based adhesion, from single molecule dynamics to stability of macromolecular complexes |
| Q50940275 | The effect of the physical properties of the substrate on the kinetics of cell adhesion and crawling studied by an axisymmetric diffusion-energy balance coupled model. |
| Q34106011 | The final steps of integrin activation: the end game |
| Q38739038 | The growth determinants and transport properties of tunneling nanotube networks between B lymphocytes. |
| Q37550239 | The heel and toe of the cell's foot: a multifaceted approach for understanding the structure and dynamics of focal adhesions |
| Q49806464 | The human platelet antigen-1b variant of αIIbβ3 allosterically shifts the dynamic conformational equilibrium of this integrin toward the active state |
| Q47153377 | The involvement of the laminin-integrin α7β1 signaling pathway in mechanical ventilation-induced pulmonary fibrosis |
| Q37998158 | The leucocyte β2 (CD18) integrins: the structure, functional regulation and signalling properties |
| Q37360851 | The mechanical integrin cycle. |
| Q47959485 | Understanding the Functional Roles of Multiple Extracellular Domains in Cell Adhesion Molecules with a Coarse-Grained Model |
| Q97526629 | When Stiffness Matters: Mechanosensing in Heart Development and Disease |
| Q50492543 | α5 β1-integrins are sensors for tauroursodeoxycholic acid in hepatocytes. |
| Q91929786 | β1 integrin is a sensor of blood flow direction |