about
The Analysis of Plantar Pressure Data Based on Multimodel Method in Patients with Anterior Cruciate Ligament Deficiency during WalkingEmerging Roles of circRNA Related to the Mechanical Stress in Human Cartilage Degradation of OsteoarthritisModified Team-Based Learning in an Ophthalmology Clerkship in China.Translation, Validation and Cross-Cultural Adaptation of a Simplified-Chinese Version of the Tegner Activity Score in Chinese Patients with Anterior Cruciate Ligament InjurySimilarity of Center of Pressure Progression during Walking and Jogging of Anterior Cruciate Ligament Deficient Patients.A composite scaffold of MSC affinity peptide-modified demineralized bone matrix particles and chitosan hydrogel for cartilage regeneration.Runx2-Modified Adipose-Derived Stem Cells Promote Tendon Graft Integration in Anterior Cruciate Ligament Reconstruction.Circular RNA Related to the Chondrocyte ECM Regulates MMP13 Expression by Functioning as a MiR-136 'Sponge' in Human Cartilage Degradation.Silencing of miR-101 Prevents Cartilage Degradation by Regulating Extracellular Matrix-related Genes in a Rat Model of Osteoarthritis.Inhibition of transforming growth factor β-activated kinase 1 prevents inflammation-related cartilage degradation in osteoarthritisA novel rabbit model of early osteoarthritis exhibits gradual cartilage degeneration after medial collateral ligament transection outside the joint capsule.The TMSB4 Pseudogene LncRNA Functions as a Competing Endogenous RNA to Promote Cartilage Degradation in Human Osteoarthritis.Effects of mechanical stress on chondrocyte phenotype and chondrocyte extracellular matrix expression.Comparison Between Single- and Double-Bundle Anterior Cruciate Ligament Reconstruction With 6- to 8-Stranded Hamstring Autograft: A Prospective, Randomized Clinical Trial.The potential of using semitendinosus tendon as autograft in rabbit meniscus reconstruction.Isokinetic angle-specific moments and ratios characterizing hamstring and quadriceps strength in anterior cruciate ligament deficient kneesSynthesis and characterization of polyphosphazene microspheres incorporating demineralized bone matrix scaffolds controlled release of growth factor for chondrogenesis applications.Dextran-coated fluorapatite crystals doped with Yb3+/Ho3+ for labeling and tracking chondrogenic differentiation of bone marrow mesenchymal stem cells in vitro and in vivo.Relationship between quadriceps strength and patellofemoral joint chondral lesions after anterior cruciate ligament reconstruction.Concurrent arthroscopic osteochondral lesion treatment and lateral ankle ligament repair has no substantial effect on the outcome of chronic lateral ankle instability.Structurally and Functionally Optimized Silk-Fibroin-Gelatin Scaffold Using 3D Printing to Repair Cartilage Injury In Vitro and In Vivo.Microfracture combined with functional pig peritoneum-derived acellular matrix for cartilage repair in rabbit models.A functional biphasic biomaterial homing mesenchymal stem cells for in vivo cartilage regeneration.Transplantation of allogenic chondrocytes with chitosan hydrogel-demineralized bone matrix hybrid scaffold to repair rabbit cartilage injury.Comparative study on immediate versus delayed meniscus allograft transplantation: 4- to 6-year follow-up.A co-culture system of rat synovial stem cells and meniscus cells promotes cell proliferation and differentiation as compared to mono-culture.Muscular Force Patterns during Level Walking in ACL-Deficient Patients with a Concomitant Medial Meniscus Tear.The diagnostic value of magnetic resonance imaging for different types of subscapularis lesionsAcetabular Labral Reconstruction With Autologous Tendon Tissue in a Porcine Model: In Vivo Histological Assessment and Gene Expression Analysis of the Healing TissueA more flattened bone tunnel has a positive effect on tendon-bone healing in the early period after ACL reconstruction
P50
Q31152581-057C153E-1590-48B9-AB61-59CFFFBBD57FQ33633097-3BB8EF9D-21A5-4E97-91EB-C0BF5D297851Q35995776-C6E0F274-1348-430E-B07D-B6B0C549C1C7Q36019682-9316B28D-F1BE-42A3-BA46-2BA42D5593AEQ36245630-B38B3312-7BB0-4246-98D2-8608D115235FQ36343904-D0067513-5FAA-416E-BA9D-C8372E345C67Q36442654-AC3015F3-ECEF-42D7-AE5A-F2070AB8922BQ36638569-42E25D25-14DB-413B-9956-B9C49349527FQ36757016-C88E06E1-4B41-4E59-A28E-92D6078A0828Q37294091-32C224DC-DB09-45C2-A4F1-91394461C753Q37348762-95CFCCFF-EA34-44DA-9000-11E266927B6EQ37418494-F857FD49-572D-41D8-91AC-522CF60B56FFQ37419090-83691BE9-009F-413D-A329-37828F9F83A0Q39655953-CF006F9F-5326-43DB-B04C-06A8CDD0537CQ41204581-84EA9A52-58D1-4545-8D93-E6C9C09C5810Q41260850-8B6A6871-08A3-40EE-9C2E-D2298E7B83F5Q48522922-DDD32B82-AA6B-4A52-9592-E5289FF8C6A2Q48678670-BFCEA520-FA05-4710-9D59-8EA711511F9AQ49025879-0C76D43C-77A0-42CF-989F-72A0C4262CB3Q50013742-AE9CAD2F-CDE1-4F73-993A-36B8D5BD39B8Q50851249-056C31A9-B188-4FF9-8E35-6FB32B123165Q51032218-17FD6747-AF33-4DB8-BE52-7AEC019EAD97Q51058815-BB7DEDFD-3E0F-4B0C-ADC1-1822C2FE7963Q51161847-33534EF7-40C8-4670-AD41-905BC09D6248Q53086310-14958285-3D56-4241-87B8-79FB29321D36Q55221903-3570257B-3354-455C-888F-D0D34C3AE872Q64983881-65848323-0CF2-4547-9927-C77C21B72A99Q85635268-A0BC6C1D-AC9C-432F-8BEE-4633ABEFC890Q87215534-20110D1F-E8F3-4FC9-BBBD-E8A60EDA6DFBQ92403650-123CB1FA-524C-4DC1-A9BC-2EDBBD05E522
P50
description
researcher ORCID ID = 0000-0002-8909-2022
@en
wetenschapper
@nl
name
Yingfang Ao
@ast
Yingfang Ao
@en
Yingfang Ao
@nl
type
label
Yingfang Ao
@ast
Yingfang Ao
@en
Yingfang Ao
@nl
prefLabel
Yingfang Ao
@ast
Yingfang Ao
@en
Yingfang Ao
@nl
P106
P31
P496
0000-0002-8909-2022