Dynamic compressive loading enhances cartilage matrix synthesis and distribution and suppresses hypertrophy in hMSC-laden hyaluronic acid hydrogels.
about
Programmable mechanobioreactor for exploration of the effects of periodic vibratory stimulus on mesenchymal stem cell differentiation.Substrate stiffness and oxygen as regulators of stem cell differentiation during skeletal tissue regeneration: a mechanobiological model.Modulating gradients in regulatory signals within mesenchymal stem cell seeded hydrogels: a novel strategy to engineer zonal articular cartilage.Effects of in vitro low oxygen tension preconditioning of adipose stromal cells on their in vivo chondrogenic potential: application in cartilage tissue repairStrategies to minimize hypertrophy in cartilage engineering and regeneration.High mesenchymal stem cell seeding densities in hyaluronic acid hydrogels produce engineered cartilage with native tissue properties.The role of environmental factors in regulating the development of cartilaginous grafts engineered using osteoarthritic human infrapatellar fat pad-derived stem cellsThe inhibition by interleukin 1 of MSC chondrogenesis and the development of biomechanical properties in biomimetic 3D woven PCL scaffolds.The influence of hyaluronic acid hydrogel crosslinking density and macromolecular diffusivity on human MSC chondrogenesis and hypertrophy.TGFβ signaling promotes matrix assembly during mechanosensitive embryonic salivary gland restorationMechanical regulation of chondrogenesis.Mechanical loading inhibits hypertrophy in chondrogenically differentiating hMSCs within a biomimetic hydrogel.Engineering synthetic hydrogel microenvironments to instruct stem cells.Scaffold-mediated lentiviral transduction for functional tissue engineering of cartilage.Functional properties of bone marrow-derived MSC-based engineered cartilage are unstable with very long-term in vitro culture.Bioreactor engineering of stem cell environmentsCurrent strategies in multiphasic scaffold design for osteochondral tissue engineering: A review.Application of Extrusion-Based Hydrogel Bioprinting for Cartilage Tissue EngineeringDesign and validation of a biomechanical bioreactor for cartilage tissue culture.Athletic groin pain (part 2): a prospective cohort study on the biomechanical evaluation of change of direction identifies three clusters of movement patterns.Cell-laden hydrogels for osteochondral and cartilage tissue engineering.Seven diverse human embryonic stem cell-derived chondrogenic clonal embryonic progenitor cell lines display site-specific cell fates.Effects of mechanical loading on human mesenchymal stem cells for cartilage tissue engineering.A human embryonic stem cell-derived clonal progenitor cell line with chondrogenic potential and markers of craniofacial mesenchyme.Chondro-protective effects of low intensity pulsed ultrasound.In Vitro Engineering of High Modulus Cartilage-Like Constructs.Preconditioning of mesenchymal stromal cells toward nucleus pulposus-like cells by microcryogels-based 3D cell culture and syringe-based pressure loading system.Anatomical region-dependent enhancement of 3-dimensional chondrogenic differentiation of human mesenchymal stem cells by soluble meniscus extracellular matrix.Synergistic effects on mesenchymal stem cell-based cartilage regeneration by chondrogenic preconditioning and mechanical stimulationHuman chondrocyte migration behaviour to guide the development of engineered cartilage.Cyclic Tensile Strain Can Play a Role in Directing both Intramembranous and Endochondral Ossification of Mesenchymal Stem Cells.Mechanical stimulation of mesenchymal stem cells: Implications for cartilage tissue engineering.Unravelling the Role of Mechanical Stimuli in Regulating Cell Fate During Osteochondral Defect Repair.Global chondrocyte gene expression after a single anabolic loading period: Time evolution and re-inducibility of mechano-responses.Engineering mechanical microenvironment of macrophage and its biomedical applications.Characterising the effects of in vitro mechanical stimulation on morphogenesis of developing limb explants.Suspension-based differentiation of adult mesenchymal stem cells toward chondrogenic lineage.Engineering zonal cartilaginous tissue by modulating oxygen levels and mechanical cues through the depth of infrapatellar fat pad stem cell laden hydrogels.Articular Cartilage Aging-Potential Regenerative Capacities of Cell Manipulation and Stem Cell Therapy.Duration of TGF-β3 Exposure Impacts the Chondrogenic Maturation of Human MSCs in Photocrosslinked Carboxymethylcellulose Hydrogels.
P2860
Q30442650-2D0F9400-660A-49BB-A8C2-BC1115F27C08Q34387499-43ED10CD-1335-44A9-8BDA-281B1BA967CFQ34683772-C3CD88E1-A63D-4B01-A4D2-111AD7DDA4D1Q34701311-3A557143-F678-4921-86BF-FAC8F7FE6C05Q35624042-D8A0CCF4-13B8-4358-92B2-8977FE0A4CA7Q36074525-61B553B4-B9A7-4252-9401-AD7893FD7670Q36166500-5A6F9340-9231-4088-BBEB-D79329C26B55Q36303611-B483827A-91C1-45D5-80CF-C8A99654F590Q36626768-652E22DA-FC3C-4A28-9DF7-616DEFA862C4Q36983894-DD6BD056-BC3D-4FC7-8650-F0A42BB73B68Q36998714-44193F93-620B-4E2C-98E1-2C73BA19D63DQ37150009-18FC926D-CAB6-437D-A8DA-89E415A2AB1DQ37198721-93F3E921-1B05-4581-B446-F6FC40740F2CQ37628097-E4FDE1D8-02A7-470F-AD6A-B21A3B9C65BCQ37716972-E4C25C73-D9F4-4A15-BC3B-D796099F122DQ38093335-2519566B-226A-4A5A-9F6E-7AED5472969BQ38262783-B7E1C82E-B2C3-4DAD-8B73-84BE04667B71Q38652777-FE34BAFA-6519-4593-891F-EA1E39021F4EQ38855541-7F83CC81-1695-458D-AB60-00D6C7C7CC94Q38956499-FCC781D0-71D4-47AD-A36E-02EA325E4203Q39088959-1A86CBA1-A9BC-4C64-A336-9F0084E18228Q39224553-D1DD6F5C-F4BF-47E7-9628-BBC0D50992EEQ39329223-D375ABD1-45DB-49EC-9833-EDA85919E689Q39361737-5AD1A507-681F-430F-AB3A-AF3BE051E1EDQ39641161-C58028B9-0AB7-419D-96AB-270476EFEADEQ40022571-B5628B69-1269-4C9A-BE9F-6DF8AF43BD28Q40903943-2615FA4F-03BD-4151-9804-1538358B14C4Q41252507-791337B4-AD23-4118-BE0E-7399D7150A40Q42281035-D9422E81-4BBF-4C30-B98E-EB46759C6EF6Q46445252-92136E91-74BD-41E9-8491-2F20FF5AD617Q47137278-49092DE3-D7FE-4E7F-880E-C676FD8EAEE5Q47858719-4404767B-D63E-4105-AAEE-F328868C80CBQ48191360-7EEBDB8D-E53A-43E6-B589-1A10A1A4710AQ48335036-8E931BFA-2F54-41C4-AD65-0C33FC8840C7Q50046074-62BFB9C8-ED04-4948-BAD4-52FC4B26F758Q50483969-572A0566-FF0D-46D2-A20E-C659F718A9FBQ51115184-D59F70A8-22D1-47E9-955E-D87690BD2E20Q51347957-A9F9D190-35D6-439E-82BC-D303B3B3988EQ51767972-04C3D7C6-BC65-4FB0-B88A-6F5AC5DC629AQ53394263-E3785261-30BD-4175-8BA6-B1E51BC6E6BF
P2860
Dynamic compressive loading enhances cartilage matrix synthesis and distribution and suppresses hypertrophy in hMSC-laden hyaluronic acid hydrogels.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@ast
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@en
type
label
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@ast
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@en
prefLabel
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@ast
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@en
P2093
P2860
P1476
Dynamic compressive loading en ...... den hyaluronic acid hydrogels.
@en
P2093
David Y Zhai
Emily C Zhang
Jason A Burdick
Liming Bian
Robert L Mauck
P2860
P304
P356
10.1089/TEN.TEA.2011.0455
P577
2011-12-02T00:00:00Z