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Primary cilia-mediated mechanotransduction in human mesenchymal stem cells.Mechanical signals promote osteogenic fate through a primary cilia-mediated mechanismAdenylyl cyclase 6 mediates loading-induced bone adaptation in vivo.Centriole splitting caused by loss of the centrosomal linker protein C-NAP1 reduces centriolar satellite density and impedes centrosome amplification.The mechanics of the primary cilium: an intricate structure with complex functionA role for the primary cilium in paracrine signaling between mechanically stimulated osteocytes and mesenchymal stem cells.On the Automatic Decellularisation of Porcine Aortae: A Repeatability Study Using a Non-Enzymatic Approach.Mechanically stimulated bone cells secrete paracrine factors that regulate osteoprogenitor recruitment, proliferation, and differentiation.An experimental and computational analysis of primary cilia deflection under fluid flow.Oscillatory fluid flow influences primary cilia and microtubule mechanics.TGFβ1 - induced recruitment of human bone mesenchymal stem cells is mediated by the primary cilium in a SMAD3-dependent manner.Genomic identification, expression profiling, and functional characterization of CatSper channels in the bovine.Mechanical behavior of primary cilia.Quantitative analysis of the effect of porosity on the fatigue strength of bone cement.Oscillatory fluid flow induces the osteogenic lineage commitment of mesenchymal stem cells: The effect of shear stress magnitude, frequency, and duration.TRPV4-mediates oscillatory fluid shear mechanotransduction in mesenchymal stem cells in part via the primary cilium.TGFβ1 Signalling in human mesenchymal stem cells is regulated by the primary cilium.Direct mechanical characterization of prostate tissue-a systematic reviewMesenchymal stem cell mechanotransduction is cAMP dependent and regulated by adenylyl cyclase 6 and the primary ciliumPhysiological cyclic hydrostatic pressure induces osteogenic lineage commitment of human bone marrow stem cells: a systematic studyFluid flow-induced bending of the primary cilium triggers a distinct intraciliary calcium flux in mesenchymal stem cellsEstrogen deficiency impairs integrin αβ-mediated mechanosensation by osteocytes and alters osteoclastogenic paracrine signallingStatistical distribution of the fatigue strength of porous bone cementMediating human stem cell behaviour via defined fibrous architectures by melt electrospinning writingThe effect of pore size within fibrous scaffolds fabricated using melt electrowriting on human bone marrow stem cell osteogenesisAged Osteoporotic Bone Marrow Stromal Cells Demonstrate Defective Recruitment, Mechanosensitivity, and Matrix DepositionEnhanced corrosion resistance and cytocompatibility of biomimetic hyaluronic acid functionalised silane coating on AZ31 Mg alloy for orthopaedic applicationsCiliotherapy Treatments to Enhance Biochemically- and Biophysically-Induced Mesenchymal Stem Cell Osteogenesis: A Comparison StudyUtilizing Osteocyte Derived Factors to Enhance Cell Viability and Osteogenic Matrix Deposition within IPN HydrogelsIntegrins in Osteocyte Biology and Mechanotransduction
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Q30530971-78CDBB65-84E3-4F1D-9798-39466043CB3BQ36705331-B73EDFCE-6201-4B05-BCD4-4CA6DE7C1D26Q37594004-966CCF5B-6263-4B35-8FD5-FDBA148E74DEQ37699012-30641D98-4ED4-44DB-946E-9C7086FC0402Q37928761-24826ADE-5069-40DB-ABA1-6BF596A2FD71Q38254472-8214A66F-AC30-438B-9E52-31AA7D6BE72BQ38871661-C280C151-FC59-4734-A6C9-8379D1122EA3Q38905635-FDBEBAB2-C665-4075-A618-B6C9757FE154Q38962914-EEFC719D-D827-4B5E-9A68-6499EF4AD22CQ38973454-ADFAD4D2-DB0F-4DD8-BADD-E94914459D0BQ41474810-2E067AE1-C5AF-4040-B00A-B5AA51558E5FQ46281768-75DC1752-510A-498F-98B4-7EB93F0FC0EAQ46289085-DEB6E2A8-7F4A-4D36-BA14-CE5955888C52Q47313194-5F054249-A83E-4E42-85EC-9E7DA6853BF2Q47338823-77EB74C7-B016-42FB-AF80-8D9570F9A7C1Q52680690-696FCD9E-10CC-481B-87EB-273AD2342F06Q55188540-92ED6773-2CFA-4B39-865A-8ECF258FC6DCQ57092673-85EEF410-FB22-4B14-B7D9-EBEDAF989232Q57289872-2795D73C-9E92-4550-B264-7C6314A61C54Q57789070-01177712-9725-44BE-8510-9DAFF59A4F7FQ59412255-8415D377-C205-4004-B47C-63F448BCE56FQ64091103-C78E09F6-3BB0-48B0-88CB-DADF47580B35Q84449252-15918BA1-FAC4-45BE-9ACC-3D3D31B677D5Q88950842-4EB84210-468E-4E92-A866-568CE2DF06ECQ90416429-F95D89DB-A598-40F4-8D52-7D24CBDBDB38Q90958848-43965A2A-0AEE-4E2E-9065-B34DFE678439Q91192213-A8394952-35EF-47AD-BC20-1D9734873032Q91261206-58B104DA-98BB-438E-AD5B-E26417F32A26Q91670222-BBD6F443-5C4D-4CB5-9FC0-8B3B64FD5B32Q93094774-EDC92A2D-C5FE-43C9-8024-F43EB879934B
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description
hulumtues
@sq
researcher
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wetenschapper
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հետազոտող
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name
David A. Hoey
@ast
David A. Hoey
@en
David A. Hoey
@es
David A. Hoey
@nl
David A. Hoey
@sl
type
label
David A. Hoey
@ast
David A. Hoey
@en
David A. Hoey
@es
David A. Hoey
@nl
David A. Hoey
@sl
prefLabel
David A. Hoey
@ast
David A. Hoey
@en
David A. Hoey
@es
David A. Hoey
@nl
David A. Hoey
@sl
P1053
G-3301-2013
P106
P1153
6603613776
P21
P31
P3829
P496
0000-0001-5898-0409