The pivotal role of reactive oxygen species generation in the hypoxia-induced stimulation of adipose-derived stem cells. - Wikidata - awgldk - TriplyDB

The pivotal role of reactive oxygen species generation in the hypoxia-induced stimulation of adipose-derived stem cells.

The pivotal role of reactive oxygen species generation in the hypoxia-induced stimulation of adipose-derived stem cells.

http://www.wikidata.org/entity/Q38583113

about

Advances in the Treatment of Ischemic Diseases by Mesenchymal Stem Cells Redox homeostasis: the linchpin in stem cell self-renewal and differentiation Hypoxic conditioning enhances the angiogenic paracrine activity of human adipose-derived stem cells.The molecular mechanism underlying the proliferating and preconditioning effect of vitamin C on adipose-derived stem cells In situ normoxia enhances survival and proliferation rate of human adipose tissue-derived stromal cells without increasing the risk of tumourigenesis Hydrogen peroxide fuels aging, inflammation, cancer metabolism and metastasis: the seed and soil also needs "fertilizer".Megestrol Acetate Increases the Proliferation, Migration, and Adipogenic Differentiation of Adipose-Derived Stem Cells via Glucocorticoid Receptor Hypoxia Enhances Proliferation of Human Adipose-Derived Stem Cells via HIF-1ɑ Activation.Generation of reactive oxygen species in adipose-derived stem cells: friend or foe?Primary involvement of NADPH oxidase 4 in hypoxia-induced generation of reactive oxygen species in adipose-derived stem cells Ultraviolet B preconditioning enhances the hair growth-promoting effects of adipose-derived stem cells via generation of reactive oxygen species.Aging-related decrease of human ASC angiogenic potential is reversed by hypoxia preconditioning through ROS production.Reactive oxygen species-responsive miR-210 regulates proliferation and migration of adipose-derived stem cells via PTPN2 Hypoxia Suppresses Spontaneous Mineralization and Osteogenic Differentiation of Mesenchymal Stem Cells via IGFBP3 Up-Regulation.Adipose-derived mesenchymal stem cells promote the survival of fat grafts via crosstalk between the Nrf2 and TLR4 pathways.NFκB signaling regulates embryonic and adult neurogenesis.Mimicking the functional niche of adipose-derived stem cells for regenerative medicine.Cellular and molecular stimulation of adipose-derived stem cells under hypoxia.An update on niche composition, signaling and functional regulation of the adipose-derived stem cells.Redox mechanisms in regulation of adipocyte differentiation: beyond a general stress response Metabolic regulation of mesenchymal stem cell in expansion and therapeutic application.Hypoxic Culturing Enhances the Wound-Healing Potential of Adipose-Derived Stem Cells.Hypoxia induces osteogenesis in rabbit adipose-derived stem cells overexpressing bone morphogenic protein-2.Role of adipose-derived stem cells in enhancing angiogenesis early after aspirated fat transplantation: induction or differentiation?Different response to hypoxia of adipose-derived multipotent cells from obese subjects with and without metabolic syndrome.Induction of functional mesenchymal stem cells from rabbit embryonic stem cells by exposure to severe hypoxic conditions.Nox, Reactive Oxygen Species and Regulation of Vascular Cell Fate.Development of S-Methylmethionine Sulfonium Derivatives and Their Skin-Protective Effect against Ultraviolet Exposure.Functional regulation of adipose-derived stem cells by PDGF-D.Hypoxia induces adipocyte differentiation of adipose-derived stem cells by triggering reactive oxygen species generation.Intramyocardial injection of hypoxia-preconditioned adipose-derived stromal cells treats acute myocardial infarction: an in vivo study in swine.Mathematical modelling of interacting mechanisms for hypoxia mediated cell cycle commitment for mesenchymal stromal cells.Isolation of adipose-derived stem cells by using a subfractionation culturing method.Increased SCF/c-kit by hypoxia promotes autophagy of human placental chorionic plate-derived mesenchymal stem cells via regulating the phosphorylation of mTOR.Physioxia: a more effective approach for culturing human adipose-derived stem cells for cell transplantation.High-performance reoxygenation from PLGA-PEG/PFOB emulsions: a feedback relationship between ROS and HIF-1α.

P2860

Q26746977-DE5AEB41-43B9-4B82-9AAB-4D1CD00A5F55 Q28396335-3E9E30BD-6E2C-49FD-9148-71952BD4D423 Q30539770-5C63D3CC-C55B-4245-874C-98F9A4D27341 Q33713771-0B7D9772-93C7-4AD2-8C84-EABA7C832D3B Q35007204-8223942E-8979-465C-9E3E-7A553F481541 Q35232552-D866182D-54BF-4D61-BA72-C51A523B9E37 Q35777541-4FE13046-F620-4704-92E5-555E93FAB973 Q35806537-B29CAAEE-7C02-42DA-B6A4-DE5E78371CB4 Q36020772-4EFFE0D7-3A56-4CE2-B9CD-7ADA965AA411 Q36138498-EB6ED0AA-33B5-4D85-B0BE-F5722A307268 Q36482258-42195207-4E9C-4110-9F25-D2CFCEC56C3E Q36673690-853A68ED-05EA-468E-97CA-F540AC21CDD0 Q36809534-E83C719A-29F4-4011-AE1C-62CF82023A86 Q37286237-2F3359D6-D345-4CE3-B14D-D98E67ADF7E1 Q37330852-16C6E57C-49E2-4EC2-B407-CCBDD70DB3FF Q37373888-DCBF4592-78DB-4048-AD42-66E74385EC13 Q38041206-739BD58C-3FDC-4E78-B7E4-A1A818D21D83 Q38180398-B202F9E3-65C0-4141-B226-5D9C5EDDAAE9 Q38202671-2DB3E880-BB52-42FA-85D8-F221B2A43601 Q38202879-BD7AEE55-84B1-4B4A-AE2E-0FCA93E99EE3 Q38287785-9378C1B0-8A57-401C-A645-73D482DC440A Q43198541-69091C7A-B48A-4ADD-9DAB-F3A66A5A21CC Q43874393-7D117055-D22C-464C-89D7-3128FFBB3D06 Q44312934-48095D91-46BA-4E0B-8DD4-292DC6F4FB87 Q45402080-BF04C40C-BBDC-4B74-8ACB-78C4E96AF8DA Q45851611-5F87579A-AC4D-4F23-9DC1-EECF3ACE3DD9 Q46261737-B8651292-7463-48E6-A2A8-543A2E6B377C Q46263132-646CF0D8-2C84-40A3-BE9B-D0963169C23C Q46823306-22A2447B-23C7-4E97-AF74-944CAB713231 Q47752324-734BC5A7-BA3F-48BC-8BA2-627C5B3AA3B1 Q51703162-6FC84745-2858-4B36-B307-52A13B6A8117 Q52722475-4967AC34-791D-4818-AEA9-AEB69D34BBD3 Q53267899-0B51AB9A-DE30-4DF7-BC25-95D9F9B3A190 Q53367084-09228480-C3DE-40D5-87F1-CE1624BEDF47 Q55110887-6847205F-3FAE-400A-AC4A-331C540D30C6 Q55248750-A4A0220A-6A6A-4183-871B-9A02B55C3AEC

P2860

The pivotal role of reactive oxygen species generation in the hypoxia-induced stimulation of adipose-derived stem cells.

http://www.wikidata.org/entity/Q38583113

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

The pivotal role of reactive o ...... of adipose-derived stem cells.

@en

type

label

The pivotal role of reactive o ...... of adipose-derived stem cells.

@en

prefLabel

The pivotal role of reactive o ...... of adipose-derived stem cells.

@en

P1433

Q38583113-9D05FA04-187B-45D8-BE2F-B5E138AEEB7E

P1476

Q38583113-6334B4F9-2C35-431B-BAF7-086C8CC9BC03

P2093

Q38583113-3694EBAF-346C-4A13-B4C3-EBD2DBA6852E

Q38583113-44BA9D12-BD1B-4B6B-BCB1-87617B401B2A

Q38583113-73AE126D-8841-41A6-93B0-C5F603760D81

Q38583113-889BAB02-F38E-460C-9F47-89032985026F

Q38583113-952192DD-3AB3-4707-A796-B6640699BCA1

P2860

Q38583113-02883648-BFEF-4009-BEFD-3C85346BA146

Q38583113-099C4671-FC15-4F86-AEE7-6EB75C1606FC

Q38583113-224D7AF3-C76B-469E-AF10-B61C90E30255

Q38583113-26527ABB-4721-4A14-A422-71EAC6603E7E

Q38583113-36231013-B475-42DE-A6FE-647075BA474B

Q38583113-4324B64F-1121-4336-A861-D56BE9907C05

Q38583113-51E83D64-1F4D-462B-A97F-39782C5D3729

Q38583113-5B158750-C10A-436E-A968-F8DFA1E40FF6

Q38583113-5E55F3C5-F565-4CFA-80BA-982185BB39ED

Q38583113-6292616D-BC27-46D6-801E-74C5EC2D200B

P304

Q38583113-5E51BA01-4B6F-4539-B483-2904B4CE58AB

P31

Q38583113-EB00C255-F404-4A83-8221-E28935A733E9

P356

Q38583113-05804360-2597-40DC-97A7-F47CA1DBC31F

P433

Q38583113-7DEC8FC1-C506-43B2-B078-9B5BC820D4BE

P478

Q38583113-D119F0F2-4D6F-4992-A967-EBE749A3629B

P50

Q38583113-2815E00D-AA13-4360-9E5B-F44D35D8D568

P577

Q38583113-76C7BF05-48F8-4F9B-B33E-4965A48EAC26

P5875

Q38583113-EA25D94D-CD9E-4689-BF3F-1E80A4F9C8CF

P698

Q38583113-E4A487A3-9CD3-4951-B6EA-376721786A9E

P921

Q38583113-5491358C-9974-4F36-A728-F62FEC9026A5

P932

Q38583113-CFD320AD-AE9A-40D8-BBF3-75A63841F06C

P356

P1433

Stem Cells and Development

P1476

The pivotal role of reactive o ...... of adipose-derived stem cells

@en

P2093

Ji Hye Kim

http://www.w3.org/2001/XMLSchema#string

Jong-Hyuk Sung

http://www.w3.org/2001/XMLSchema#string

Joon-Seok Choi

http://www.w3.org/2001/XMLSchema#string

Sang Gyu Park

http://www.w3.org/2001/XMLSchema#string

So-Hyun Park

http://www.w3.org/2001/XMLSchema#string

P2860

Hypoxia regulates PDGF-B interactions between glomerular capillary endothelial and mesangial cells

Effects of hypoxia on relationships between cytosolic and mitochondrial NAD(P)H redox and superoxide generation in coronary arterial smooth muscle

The NADPH oxidase NOX4 drives cardiac differentiation: Role in regulating cardiac transcription factors and MAP kinase activation

NOX enzymes and the biology of reactive oxygen

NAD(P)H oxidase: role in cardiovascular biology and disease

Novel role of NADPH oxidase in angiogenesis and stem/progenitor cell function.

Hypoxia-induced proliferation of human pulmonary microvascular endothelial cells depends on epidermal growth factor receptor tyrosine kinase activation

Oxidant signals and oxidative stress.

Vascular NAD(P)H oxidases: specific features, expression, and regulation.

Inhibition of tumor endothelial ERK activation, angiogenesis, and tumor growth by sorafenib (BAY43-9006)

P304

1753-1761

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1089/SCD.2010.0469

http://www.w3.org/2001/XMLSchema#string

P433

10

http://www.w3.org/2001/XMLSchema#string

P478

20

http://www.w3.org/2001/XMLSchema#string

P50

P577

2011-03-02T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

49784164

http://www.w3.org/2001/XMLSchema#string

P698

21265612

http://www.w3.org/2001/XMLSchema#string

P921

P932

3182032

http://www.w3.org/2001/XMLSchema#string