about
Vav1 and Rac control chemokine-promoted T lymphocyte adhesion mediated by the integrin alpha4beta1Topical Treatment With Bromfenac Reduces Retinal Gliosis and Inflammation After Optic Nerve Crush.Intracellular signaling required for CCL25-stimulated T cell adhesion mediated by the integrin alpha4beta1.Evaluation of cytocompatibility of calcium silicate-based endodontic sealers and their effects on the biological responses of mesenchymal dental stem cells.Silk-Fibroin and Graphene Oxide Composites Promote Human Periodontal Ligament Stem Cell Spontaneous Differentiation into Osteo/Cementoblast-Like Cells.Positive and negative regulation by SLP-76/ADAP and Pyk2 of chemokine-stimulated T-lymphocyte adhesion mediated by integrin α4β1Chemokine-induced Zap70 kinase-mediated dissociation of the Vav1-talin complex activates alpha4beta1 integrin for T cell adhesion.The chemokine receptor CXCR4 and the metalloproteinase MT1-MMP are mutually required during melanoma metastasis to lungs.The effects of Ca2SiO4-Ca3(PO4)2 ceramics on adult human mesenchymal stem cell viability, adhesion, proliferation, differentiation and function.Comparative analysis of the biological effects of the endodontic bioactive cements MTA-Angelus, MTA Repair HP and NeoMTA Plus on human dental pulp stem cells.Cytotoxicity and bioactivity of various pulpotomy materials on stem cells from human exfoliated primary teeth.Biological effects of silk fibroin 3D scaffolds on stem cells from human exfoliated deciduous teeth (SHEDs).Biocompatibility of New Pulp-capping Materials NeoMTA Plus, MTA Repair HP, and Biodentine on Human Dental Pulp Stem Cells.Analysis of the Adherence of Dental Pulp Stem Cells on Two-Dimensional and Three-Dimensional Silk Fibroin-Based Biomaterials.Biocompatibility of three new calcium silicate-based endodontic sealers on human periodontal ligament stem cells.Effects of composite films of silk fibroin and graphene oxide on the proliferation, cell viability and mesenchymal phenotype of periodontal ligament stem cells.Cytoprotective effects of melatonin on zoledronic acid-treated human mesenchymal stem cells in vitro.Potential of graphene for tissue engineering applications.Sphingosine-1-phosphate activates chemokine-promoted myeloma cell adhesion and migration involving α4β1 integrin functionHuman Wharton's jelly mesenchymal stem cells protect axotomized rat retinal ganglion cells via secretion of anti-inflammatory and neurotrophic factorsSilk fibroin scaffolds seeded with Wharton's jelly mesenchymal stem cells enhance re-epithelialization and reduce formation of scar tissue after cutaneous wound healingPhysicochemical, cytotoxicity and in vivo biocompatibility of a high-plasticity calcium-silicate based materialBiological effects of acid-eroded MTA Repair HP and ProRoot MTA on human periodontal ligament stem cells.Human Dental Pulp Stem Cells Exhibit Different Biological Behaviours in Response to Commercial Bleaching Products.RGS10 restricts upregulation by chemokines of T cell adhesion mediated by α4β1 and αLβ2 integrinsThermo-setting glass ionomer cements promote variable biological responses of human dental pulp stem cellsGlioblastoma ablates pericytes antitumor immune function through aberrant up-regulation of chaperone-mediated autophagySafety and Biodistribution of Human Bone Marrow-Derived Mesenchymal Stromal Cells Injected Intrathecally in Non-Obese Diabetic Severe Combined Immunodeficiency Mice: Preclinical StudyIn Vitro Evaluation of the Biological Effects of ACTIVA Kids BioACTIVE Restorative, Ionolux, and Riva Light Cure on Human Dental Pulp Stem CellsProduction via good manufacturing practice of exofucosylated human mesenchymal stromal cells for clinical applicationsMesenchymal stromal cell therapy for damaged retinal ganglion cells, is gold all that glitters?Evaluation of changes in ion release and biological properties of NeoMTA-Plus and Endocem-MTA exposed to an acidic environmentComparison of diffusion, cytotoxicity and tissue inflammatory reactions of four commercial bleaching products against human dental pulp stem cellsAutophagy in the Immunosuppressive Perivascular Microenvironment of GlioblastomaCytocompatibility, bioactivity potential, and ion release of three premixed calcium silicate-based sealersBiological Effects of New Hydraulic Materials on Human Periodontal Ligament Stem CellsGuttaFlow Bioseal promotes spontaneous differentiation of human periodontal ligament stem cells into cementoblast-like cellsAllogeneic Bone Marrow Mesenchymal Stem Cell Transplantation in Tooth Extractions Sites Ameliorates the Incidence of Osteonecrotic Jaw-Like Lesions in Zoledronic Acid-Treated RatsDefibrotide inhibits donor leucocyte-endothelial interactions and protects against acute graft-versus-host disease
P50
Q33877050-7BD88EB7-19CF-42DD-8769-5BDA77AC7E0DQ34544403-BD9DA563-D5BF-42D3-8E26-9AE522B5C61CQ34629420-CE805E01-EDBB-4223-B6CE-8804E4E1A7F6Q35867480-6CB0214E-8BA4-461F-BE59-CA208B4D2ED4Q38801773-90A992D4-A4CA-444C-9E58-B88536537A8DQ38850223-6894E5C4-CCBF-4F34-8D70-E5DE51D5563EQ39764391-B5DF9654-2BFF-4768-BBCA-358A2AAFA3BAQ39894560-7DA55478-0952-4C7C-B531-AF942928FA46Q47873305-7437D0F4-3DDD-417C-832E-E2713E0E8E90Q48054374-7F7AA4FA-B249-449B-95F0-B41FB49A7C2EQ48267830-B07C7833-F77D-4AF3-8777-6161A766B3DAQ48274851-10C00429-F9AC-46C2-A516-A8BD39DD7BA7Q50099540-D9D58BA6-98D5-4908-A459-8A1DF7232549Q50993363-099FBDB4-20F6-4F61-AF16-D645A28C4612Q52999400-A01CDD30-2714-4043-A747-113FA5171BC0Q53484910-0A8DDDD4-8E62-4A8D-A452-ED3A5B431F5BQ53485251-495013DB-E243-4A26-92B8-17DED7BCB21FQ53520816-BEE2CF75-880E-4F1F-9456-7FCA4D9A62ADQ58498450-B4BBD6F4-0058-4A62-8B85-D7071889AC0FQ58618229-9FB5312C-44A7-48BD-BDB0-53B5A007ED59Q64084026-F267F017-AFB0-4E88-A6C1-5822CAE6E48AQ64118332-0F2B37E6-0A8B-4625-8B4E-AA7B6BEB813DQ64968647-567F4B38-0D28-420A-BACB-2EDA8AF0B44DQ64980298-A1F49076-9652-4673-8367-A78D5B466F40Q84447594-D19AAC32-EA3D-4089-AA80-C14DA1B48515Q88344601-F4D0EF44-CD9A-409E-876B-BA15437460E2Q90240689-2128939B-3C4C-4EE6-84B9-58B82E577BDFQ90784207-626151E8-C7E8-42AA-BDF4-2D9BA373F161Q91252502-E9C1C37D-F34B-41A5-935F-8A550E2FB6B5Q91253079-053AF7D5-108D-4C71-91B4-5583368B19AFQ91762111-BB3F49EC-F453-4509-8ACA-D93D67A97059Q92091526-BD882541-C595-43D0-8709-7C71E2EB5BAEQ92256030-761B75FD-940D-4182-BD09-F4936D469340Q92444553-4FB3B996-51C2-4B52-B54E-EFCC4DF4EE40Q92535881-52369371-C356-4156-BE67-37221E9CE529Q92642471-EC14B465-00C3-430E-8F32-902C20F382CAQ93355216-59B57FC2-8A73-410A-A4CE-61F39CBB01F5Q96117708-54FE126A-6A8F-4289-9ED3-A4CA7EAA706EQ96234727-D676CB7C-B2D1-4FA3-8AEF-3AFB27E74450
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
David García-Bernal
@ast
David García-Bernal
@en
David García-Bernal
@es
David García-Bernal
@nl
David García-Bernal
@sl
type
label
David García-Bernal
@ast
David García-Bernal
@en
David García-Bernal
@es
David García-Bernal
@nl
David García-Bernal
@sl
prefLabel
David García-Bernal
@ast
David García-Bernal
@en
David García-Bernal
@es
David García-Bernal
@nl
David García-Bernal
@sl
P106
P1153
8612697800
P21
P31
P496
0000-0001-6610-8442