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Intrinsic multipotential mesenchymal stromal cell activity in gelatinous Heberden's nodes in osteoarthritis at clinical presentation.Altering the architecture of tissue engineered hypertrophic cartilaginous grafts facilitates vascularisation and accelerates mineralisation.The role of environmental factors in regulating the development of cartilaginous grafts engineered using osteoarthritic human infrapatellar fat pad-derived stem cellsRapid Chondrocyte Isolation for Tissue Engineering Applications: The Effect of Enzyme Concentration and Temporal Exposure on the Matrix Forming Capacity of Nasal Derived ChondrocytesCell-based therapies for intervertebral disc and cartilage regeneration- Current concepts, parallels, and perspectives.Living Cell Factories - Electrosprayed Microcapsules and Microcarriers for Minimally Invasive Delivery.Decellularized grafts with axially aligned channels for peripheral nerve regeneration.Fabrication and characterization of a porous multidomain hydroxyapatite scaffold for bone tissue engineering investigations.Bone Marrow Stem Cells in Response to Intervertebral Disc-Like Matrix Acidity and Oxygen Concentration: Implications for Cell-based Regenerative Therapy.High abundance of CD271(+) multipotential stromal cells (MSCs) in intramedullary cavities of long bones.Infrapatellar fat pad-derived stem cells maintain their chondrogenic capacity in disease and can be used to engineer cartilaginous grafts of clinically relevant dimensions.A comparison of self-assembly and hydrogel encapsulation as a means to engineer functional cartilaginous grafts using culture expanded chondrocytes.European Society of Biomechanics S.M. Perren Award 2012: the external mechanical environment can override the influence of local substrate in determining stem cell fate.Scaffold architecture determines chondrocyte response to externally applied dynamic compression.Engineering osteochondral constructs through spatial regulation of endochondral ossification.Cyclic hydrostatic pressure promotes a stable cartilage phenotype and enhances the functional development of cartilaginous grafts engineered using multipotent stromal cells isolated from bone marrow and infrapatellar fat pad.Cyclic Tensile Strain Can Play a Role in Directing both Intramembranous and Endochondral Ossification of Mesenchymal Stem Cells.Dynamic compression can inhibit chondrogenesis of mesenchymal stem cells.Chondrocyte-based intraoperative processing strategies for the biological augmentation of a polyurethane meniscus replacement.Priming and cryopreservation of microencapsulated marrow stromal cells as a strategy for intervertebral disc regeneration.Biomechanical properties of feline ventral abdominal wall and celiotomy closure techniques.Chondrocytes and bone marrow-derived mesenchymal stem cells undergoing chondrogenesis in agarose hydrogels of solid and channelled architectures respond differentially to dynamic culture conditions.Oxygen tension regulates the osteogenic, chondrogenic and endochondral phenotype of bone marrow derived mesenchymal stem cells.Engineering cartilaginous grafts using chondrocyte-laden hydrogels supported by a superficial layer of stem cells.Anisotropic Shape-Memory Alginate Scaffolds Functionalized with Either Type I or Type II Collagen for Cartilage Tissue Engineering.Enhancing cell migration in shape-memory alginate-collagen composite scaffolds: In vitro and ex vivo assessment for intervertebral disc repair.In vitro extracellular matrix accumulation of nasal and articular chondrocytes for intervertebral disc repair.Coupling Freshly Isolated CD44(+) Infrapatellar Fat Pad-Derived Stromal Cells with a TGF-β3 Eluting Cartilage ECM-Derived Scaffold as a Single-Stage Strategy for Promoting Chondrogenesis.Engineering zonal cartilaginous tissue by modulating oxygen levels and mechanical cues through the depth of infrapatellar fat pad stem cell laden hydrogels.Fibrin hydrogels functionalized with cartilage extracellular matrix and incorporating freshly isolated stromal cells as an injectable for cartilage regeneration.The effects of dynamic compression on the development of cartilage grafts engineered using bone marrow and infrapatellar fat pad derived stem cells.The use of the reamer-irrigator-aspirator to harvest mesenchymal stem cells.Extracellular matrix production by nucleus pulposus and bone marrow stem cells in response to altered oxygen and glucose microenvironments.Engineering articular cartilage-like grafts by self-assembly of infrapatellar fat pad-derived stem cells.Knot Security of 5 Metric (USP 2) Sutures: Influence of Knotting Technique, Suture Material, and Incubation Time for 14 and 28 Days in Phosphate Buffered Saline and Inflamed Equine Peritoneal Fluid.Controlled release of transforming growth factor-β3 from cartilage-extra-cellular-matrix-derived scaffolds to promote chondrogenesis of human-joint-tissue-derived stem cells.Oxygen tension differentially regulates the functional properties of cartilaginous tissues engineered from infrapatellar fat pad derived MSCs and articular chondrocytes.The Response of Bone Marrow-Derived Mesenchymal Stem Cells to Dynamic Compression Following TGF-β3 Induced Chondrogenic DifferentiationThe effect of concentration, thermal history and cell seeding density on the initial mechanical properties of agarose hydrogelsAdvancing cell therapies for intervertebral disc regeneration from the lab to the clinic: Recommendations of the ORS spine section
P50
Q33822356-E6C57D81-0151-419E-8D48-A67B3A5CF2CBQ35111362-0B491368-FD37-4E0B-B4B2-53127CC90947Q36166500-F72ED2AC-A3A4-421B-ABD0-3C8561821B65Q37699910-460F4A4B-AB04-4892-84D6-F677F3C5A185Q38814837-E634BCCF-2DB1-47B5-A851-69AC4B8F9EE4Q38928904-6DB015B4-D0B2-458C-A15A-F13E8CCAD247Q39086999-FBF3C81E-950D-412B-AC54-0280566363F5Q39737909-F34D3EF7-4D66-4840-B098-5CA165A9987FQ40249210-5045E115-1593-4750-A138-7DDEA986B398Q40727691-8A9B98AD-386F-41BE-A2F2-2DCAAD26F529Q41867111-D875F86C-C316-4F3A-8C4A-1F23D88B9A5CQ42780089-E23151B5-62A6-442C-8C61-3FDB81D6DE7EQ43687376-D9D95E20-4A6B-4831-9BF7-9791B50D6A15Q45939078-CD904C2C-1C74-45F0-9D6F-50E02A29C0E6Q46289416-CDC7C109-176E-4328-8013-AA21F6B55281Q46973578-439543DA-7922-47C3-8436-B848852FE9F5Q47137278-E74E775F-15A9-450B-84CA-42DADC549CD6Q47299124-C6E2E5C5-BABA-40F5-A6E0-4A029DFA761DQ47306852-1E531BD9-2A83-40D9-9362-C238DFA460B6Q48143583-91775022-2B47-43CA-953E-71BDBE5A9219Q48278297-65B8EA6B-E115-4403-AB1D-C93D1BC5398FQ50270754-4EBB4E6E-8CA2-468D-8AD5-2FE6E634F661Q50521027-DE745769-0A2C-4217-968D-4B7B088C6D39Q50585358-F01886C4-DEA1-4AD1-9C51-9F2246A4D987Q50621639-CE73EBCA-BBED-49EF-BE91-D80D19574516Q50772015-A03CE77C-F5E9-415F-8D44-2840BA60908EQ50871144-F9DDB0C6-EBA4-4DD8-9E34-586CF9535A03Q51010944-6A9C69D3-CBDA-499A-B270-7098EA63776BQ51347957-9618024F-B0A1-4878-90B7-EB388B4A79EDQ51455212-31875D8B-494F-4BE3-9845-CF3C1C07F81BQ51712557-DCDBD8D6-9D59-48D4-B624-236AB66790CAQ52845884-3E9C0566-B7C8-438F-9E28-FE235BE4BBFEQ53252239-F57B0BA4-1034-4DF0-AC3E-3BCC108FC387Q53479938-572E793B-86B5-4C76-A9D6-88A625EE99ADQ53496563-A8A4CD3B-EF59-4C16-B1E6-C43262C05BCAQ53531671-6E351C55-DA6F-46C3-BACF-05C7AF06F6AAQ54475371-34EF4FFD-B942-4A24-8D09-A58E91F9B82AQ57879793-3145B30D-AD73-4485-B6D3-8853905679E1Q57879882-94E4B6F6-6ED9-4C47-9723-759CB55D07A0Q61699166-DA8A4847-0900-48F5-AD08-59EF18A7EE8C
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Conor T Buckley
@es
Conor T. Buckley
@en
Conor T. Buckley
@nl
Conor T. Buckley
@sl
type
label
Conor T Buckley
@es
Conor T. Buckley
@en
Conor T. Buckley
@nl
Conor T. Buckley
@sl
altLabel
Buckley, C T
@en
Conor Timothy
@en
prefLabel
Conor T Buckley
@es
Conor T. Buckley
@en
Conor T. Buckley
@nl
Conor T. Buckley
@sl
P1053
C-3575-2014
P106
P1153
14629842800
P21
P31
P3829
P496
0000-0001-7452-4534
P569
2000-01-01T00:00:00Z