about
Chondrocyte-Specific Knockout of TSC-1 Leads to Congenital Spinal Deformity in Mice.Rheb GTPase controls apoptosis by regulating interaction of FKBP38 with Bcl-2 and Bcl-XLCitric acid-based hydroxyapatite composite scaffolds enhance calvarial regeneration.Citrate-based biphasic scaffolds for the repair of large segmental bone defects.Development of Injectable Citrate-Based Bioadhesive Bone Implants.Rictor/mTORC2 pathway in oocytes regulates folliculogenesis, and its inactivation causes premature ovarian failure.mTORC1 Prevents Preosteoblast Differentiation through the Notch Signaling Pathway.Fast degradable citrate-based bone scaffold promotes spinal fusionmTORC2 promotes cell survival through c-Myc-dependent up-regulation of E2F1.Tsc1 deficiency impairs mammary development in mice by suppression of AKT, nuclear ERα, and cell-cycle-driving proteins.mTORC1 regulates PTHrP to coordinate chondrocyte growth, proliferation and differentiation.Fluorescence imaging enabled biodegradable photostable polymeric micelles.mTORC1 promotes aging-related venous thrombosis in mice via elevation of platelet volume and activation.Synthesis and characterization of biomimetic citrate-based biodegradable composites.Activation of mTORC1 in collecting ducts causes hyperkalemia.Key factors in mTOR regulation.Click chemistry plays a dual role in biodegradable polymer design.Targeted Inhibition of Rictor/mTORC2 in Cancer Treatment: A New Era after Rapamycin.n-3 polyunsaturated fatty acids abrogate mTORC1/2 signaling and inhibit adrenocortical carcinoma growth in vitro and in vivo.Low-dose arsenic trioxide combined with aclacinomycin A synergistically enhances the cytotoxic effect on human acute myelogenous leukemia cell lines by induction of apoptosis.Inhibition of endometrial cancer by n-3 polyunsaturated fatty acids in preclinical models.Targeted inhibition of mTORC2 prevents osteosarcoma cell migration and promotes apoptosis.miR-483-5p promotes invasion and metastasis of lung adenocarcinoma by targeting RhoGDI1 and ALCAM.mTORC1 is a target of nordihydroguaiaretic acid to prevent breast tumor growth in vitro and in vivo.Targeting of mTORC2 prevents cell migration and promotes apoptosis in breast cancer.Chondrocyte-Specific Ablation of AMPKα1 Does Not Affect Bone Development or Pathogenesis of Osteoarthritis in Mice.NF-kappaB and Hsp70 are involved in the phospholipase Cgamma1 signaling pathway in colorectal cancer cells.The switch I region of Rheb is critical for its interaction with FKBP38.Endogenous Production of n-3 Polyunsaturated Fatty Acids Promotes Fracture Healing in Mice.A new generation of sodium chloride porogen for tissue engineering.Rictor Regulates Spermatogenesis by Controlling Sertoli Cell Cytoskeletal Organization and Cell Polarity in the Mouse Testis.Enhancement of osteogenesis post-splenectomy does not attenuate bone loss in ovariectomized rats.TPX2 Level Correlates with Hepatocellular Carcinoma Cell Proliferation, Apoptosis, and EMT.Activation of mTORC1 in B Lymphocytes Promotes Osteoclast Formation via Regulation of β-Catenin and RANKL/OPG.Acellular spinal cord scaffold seeded with bone marrow stromal cells protects tissue and promotes functional recovery in spinal cord-injured rats.Acellular spinal cord scaffold seeded with mesenchymal stem cells promotes long-distance axon regeneration and functional recovery in spinal cord injured rats[Soft tissue regeneration after implantation of two novel citric acid-based biodegradable materials in rats]Celecoxib inhibits the heterotopic ossification in the rat model with Achilles tenotomyChondrocyte mTORC1 activation stimulates miR-483-5p via HDAC4 in osteoarthritis progressionN-(3-methoxybenzyl)-(9Z,12Z,15Z)-octadecatrienamide promotes bone formation via the canonical Wnt/β-catenin signaling pathway
P50
Q33646350-C7756BAC-8A59-4AE8-A27D-34E24CD9919FQ33726390-54BF4F83-A788-4BB5-BB89-CDF97860A99AQ34455025-D3065784-E0AF-4A68-9F9D-F57AD8A9F51BQ34517247-7950B22E-9EB9-4DCE-A09F-BE28A1B5FA2FQ34866856-8E441119-BF38-47E0-9F78-E1C6B7B23DD6Q35172973-EEDA3732-4025-4F8A-A8C8-891CBCD8EE7AQ35737544-38BBF006-839C-4B0E-BE70-8B1F38BA488DQ35879779-2B60A2FD-EA83-4BD9-A904-BDB71F7C7F5BQ36149386-CA0AAEEC-FBA0-4DA5-A301-E9CC3B0AF90BQ36500453-C93E84C3-F6BB-42F2-8E38-7706D927DA76Q36768735-2835938A-67BF-48BF-B8ED-A5797FF7177BQ37351089-71DF8FA2-B698-491E-8E39-AA2FEBF92BC9Q37396328-870822B8-293C-460E-BF8B-409D1E86A925Q37597686-5F8A4D74-1FBD-43F3-8C8E-7F8A24A8B047Q37604717-B07D6497-4442-493A-8E45-92CDD27B3E2BQ37613506-2DF948B4-B1D6-457F-A0F1-63101BDEF0CAQ37672282-B263333E-7623-4256-9590-7F3A6FB3A68FQ38632212-EB5A5B0F-E15A-4665-BEFD-A968E08ED937Q38781799-25B46F60-6250-4F89-84CE-50E7B3CA8506Q38903506-9A7B4BF9-40A3-4CD0-A518-66B3320C5C4DQ38991105-2A9424B0-533B-42E4-A3CD-789394985BBEQ38993838-8FB42E40-DF9B-43C1-A771-5ABE96001180Q39006783-009C22D0-0E4D-431F-B316-83756BB8B5E1Q39262361-F641FFB7-27DE-434D-A8A3-F8C6AE1E7994Q39369234-6A226527-6CAD-4A2D-A0D6-039AE7589EB7Q40133509-F4FD2345-CAC0-4A7F-8B73-5FC23D05ADBDQ40401958-C3C3C66B-23D6-4B68-AD04-AD1F577305CCQ42062574-B587E385-D2D5-41F7-895A-33D3B3CF591BQ42967908-CE07F3F9-4A5B-4031-ABFB-5E22E26CF18AQ48222610-1193F0DE-1826-41E0-9BD7-A3F7387FB4FAQ50561965-D69BD83E-5027-4FBA-A24F-F53B96101D66Q51060644-C97D6E02-36C0-44BC-B8B6-97B1F9561190Q52940060-4AA91295-AAF3-4399-8E69-B3B8112ED524Q53190419-1FDB3684-A607-424D-9DBE-20AC6C8231A2Q54388562-EA4AB0A9-4833-4920-A8C4-BFC3E5075E23Q85895523-11B6BED7-9119-46F7-9D53-4DB39554D1FEQ85908589-AB90E8F1-FEE3-45D7-8C3A-B58CC3E6C544Q86124307-63A329BF-04F3-43AD-8FCA-AC007A123956Q91143564-089C09FD-3607-4A7A-AE37-E9BE604C61D6Q91620901-E1A3223C-7B25-459F-99A2-75C790D58A46
P50
description
investigador
@es
researcher
@en
wetenschapper
@nl
name
Xiaochun Bai
@en
Xiaochun Bai
@nl
type
label
Xiaochun Bai
@en
Xiaochun Bai
@nl
prefLabel
Xiaochun Bai
@en
Xiaochun Bai
@nl
P31
P496
0000-0001-9631-4781