about
Characterization of the age-dependent intervertebral disc changes in rabbit by correlation between MRI, histology and gene expression.An injectable vehicle for nucleus pulposus cell-based therapy.Effects of in vitro low oxygen tension preconditioning of adipose stromal cells on their in vivo chondrogenic potential: application in cartilage tissue repairPharmacological modulation of human mesenchymal stem cell chondrogenesis by a chemically oversulfated polysaccharide of marine origin: potential application to cartilage regenerative medicineMesenchymal stem cell therapy to rebuild cartilage.Olive and grape seed extract prevents post-traumatic osteoarthritis damages and exhibits in vitro anti IL-1β activities before and after oral consumption.Cartilage tissue engineering: towards a biomaterial-assisted mesenchymal stem cell therapy.Cartilage tissue engineering: From biomaterials and stem cells to osteoarthritis treatments.Update on hypoxia-inducible factors and hydroxylases in oxygen regulatory pathways: from physiology to therapeuticsEnriching a cellulose hydrogel with a biologically active marine exopolysaccharide for cell-based cartilage engineering.Inverse regulation of early and late chondrogenic differentiation by oxygen tension provides cues for stem cell-based cartilage tissue engineering.Sterilization of exopolysaccharides produced by deep-sea bacteria: impact on their stability and degradation.In vitro biological effects of titanium rough surface obtained by calcium phosphate grid blasting.Differential effects of hypoxia on osteochondrogenic potential of human adipose-derived stem cells.The effect of two- and three-dimensional cell culture on the chondrogenic potential of human adipose-derived mesenchymal stem cells after subcutaneous transplantation with an injectable hydrogel.Nasal chondrocytes and fibrin sealant for cartilage tissue engineering.A silanized hydroxypropyl methylcellulose hydrogel for the three-dimensional culture of chondrocytes.The in vitro and in vivo effects of a low-molecular-weight fucoidan on the osteogenic capacity of human adipose-derived stromal cells.Polysaccharide Hydrogels Support the Long-Term Viability of Encapsulated Human Mesenchymal Stem Cells and Their Ability to Secrete Immunomodulatory Factors.Adipose-derived mesenchymal stem cells and biomaterials for cartilage tissue engineering.An injectable cellulose-based hydrogel for the transfer of autologous nasal chondrocytes in articular cartilage defects.Purification of the exopolysaccharide produced by Alteromonas infernus: identification of endotoxins and effective process to remove them.Engineering cartilage with human nasal chondrocytes and a silanized hydroxypropyl methylcellulose hydrogel.Cartilage tissue engineering: From hydrogel to mesenchymal stem cells.Role of the Inflammation-Autophagy-Senescence Integrative Network in Osteoarthritis.State of art and limitations in genetic engineering to induce stable chondrogenic phenotypeClinical relevance of 3D gait analysis in patients with haemophiliaIn vivo experimental imaging of osteochondral defects and their healing using 99mTc-NTP 15-5 radiotracerLaser-treated Nucleus pulposus as an innovative model of intervertebral disc degenerationA comparison between bone reconstruction following the use of mesenchymal stem cells and total bone marrow in association with calcium phosphate scaffold in irradiated boneIdentification of phenotypic discriminating markers for intervertebral disc cells and articular chondrocytesThe intervertebral disc: From pathophysiology to tissue engineeringChasing Chimeras - The elusive stable chondrogenic phenotype
P50
Q33949926-557484F1-5E40-42E6-88C9-65CC0BF7ADCFQ34161286-1B0F289C-1964-42DE-990C-3FB8A8790369Q34701311-2CE2FECF-39A6-417D-9E36-16AA38671E36Q36236903-AEED487A-E9C2-42D3-BDBE-B8779B66AC47Q36280677-D337A20A-3C9C-4413-BCE7-1915C6737037Q37264662-029B3F72-E8A7-4902-AC56-44724789C2BBQ37608619-32A60254-7378-4795-8478-030B874CF902Q38808513-2D16CE64-788F-4D0E-8591-348AF6916738Q39205984-BF15F4D3-F955-44E4-8E99-497825D4DB97Q41138689-C3581D6F-A958-4FA0-BA2B-C5EDE1691ABBQ41509935-AC135F40-90A1-43D0-8BD1-DC02ABDB4869Q42102348-8ACE11C9-473F-4E1F-83A6-51B796664993Q42827972-5EBF1719-F15E-4929-8BD4-911EE781CE78Q43235373-EDF37BDD-1FFB-4C82-AE08-238A516E1C1AQ43748960-1227AF1B-FCB3-4B5F-B773-CADC0BD3833CQ43928784-E9083DF6-65FD-49B6-A8C1-20237A3C8FD1Q46540650-09409EFD-A7E9-42C6-A6CD-3AEC7D96CD5BQ46874184-8F3C3300-C1D3-4705-831E-49D28F33748DQ47161558-3C7F12EA-F4C1-4725-ADBE-7DFDF7495850Q47248061-262B5FA6-3017-4124-B293-FCF4E87D5F51Q47278208-51E03A54-E106-4DC3-AB69-F610C1518857Q48227556-9E508DE8-1A2A-4227-BEEC-08A8B8194D8FQ50476044-C243DE33-3D10-4030-99B0-D12F8CD42BA1Q50664123-B73AA545-D6F6-4F7F-9E08-F8D323DA3205Q55516438-47C9C95C-0525-4E00-9260-C6127C88F1D3Q57971766-AEBD2AEB-6E11-4EF6-AB5F-5F2A24190E2EQ61868328-6FE0B152-2876-4A8B-A98E-3A85E3CAD2D5Q61868356-36F387E1-4A8C-4578-B085-BBC5DF76DA35Q61868360-29642167-25ED-41C1-A8CA-C19D56EFFA8EQ61868373-A105FF51-8D50-4E05-840B-ACB24D1D87E8Q61868380-FE6C64AC-985E-4D6B-A173-98A12D8F43B8Q61868385-B7F3E756-120A-409E-B735-927C7759E986Q93213956-8B2F3229-5508-47F2-B426-A995DD624304
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Claire Vinatier
@ast
Claire Vinatier
@en
Claire Vinatier
@es
Claire Vinatier
@nl
Claire Vinatier
@sl
type
label
Claire Vinatier
@ast
Claire Vinatier
@en
Claire Vinatier
@es
Claire Vinatier
@nl
Claire Vinatier
@sl
prefLabel
Claire Vinatier
@ast
Claire Vinatier
@en
Claire Vinatier
@es
Claire Vinatier
@nl
Claire Vinatier
@sl
P1053
P-1686-2014
P106
P21
P31
P3829
P496
0000-0002-6063-9901