The potential role of systemic buffers in reducing intratumoral extracellular pH and acid-mediated invasion - Wikidata - awgldk - TriplyDB

The potential role of systemic buffers in reducing intratumoral extracellular pH and acid-mediated invasion

The potential role of systemic buffers in reducing intratumoral extracellular pH and acid-mediated invasion

http://www.wikidata.org/entity/Q42254342

about

Nitric oxide and pH modulation in gynaecological cancer Cancer stem cell metabolism: a potential target for cancer therapy Can we negotiate with a tumor?Acid gradient across plasma membrane can drive phosphate bond synthesis in cancer cells: acidic tumor milieu as a potential energy source Acidic tumor microenvironment abrogates the efficacy of mTORC1 inhibitors Evaluating pH in the Extracellular Tumor Microenvironment Using CEST MRI and Other Imaging Methods Non-metallic nanomaterials in cancer theranostics: a review of silica- and carbon-based drug delivery systems A nonrandomized cohort and a randomized study of local control of large hepatocarcinoma by targeting intratumoral lactic acidosis Investigating Effects of Acidic pH on Proliferation, Invasion and Drug-Induced Apoptosis in Lymphoblastic Leukemia.Imaging the intratumoral-peritumoral extracellular pH gradient of gliomas.Effect of Modified Alkaline Supplementation on Syngenic Melanoma Growth in CB57/BL Mice Beyond Warburg effect--dual metabolic nature of cancer cells.Invasion and proliferation kinetics in enhancing gliomas predict IDH1 mutation status.No evident dose-response relationship between cellular ROS level and its cytotoxicity--a paradoxical issue in ROS-based cancer therapy.Evaluations of extracellular pH within in vivo tumors using acidoCEST MRI Bicarbonate increases tumor pH and inhibits spontaneous metastases.Reduction of metastasis using a non-volatile buffer.Deriving mechanisms responsible for the lack of correlation between hypoxia and acidity in solid tumors.Tumor acidity as evolutionary spite.Tumor metabolism, cancer cell transporters, and microenvironmental resistance.Proton pump inhibition induces autophagy as a survival mechanism following oxidative stress in human melanoma cells Riparian ecosystems in human cancers.A mathematical model of tumour and blood pHe regulation: The HCO3-/CO2 buffering system Predicting the safety and efficacy of buffer therapy to raise tumour pHe: an integrative modelling study.Hybrid models of tumor growth.Acidic stress promotes a glioma stem cell phenotype.Opinion: Control vs. eradication: applying infectious disease treatment strategies to cancer.Drug resistance and cellular adaptation to tumor acidic pH microenvironment Modulation of autophagic activity by extracellular pH.In vivo monitoring of pH, redox status, and glutathione using L-band EPR for assessment of therapeutic effectiveness in solid tumors.Comparison of the Lonidamine Potentiated Effect of Nitrogen Mustard Alkylating Agents on the Systemic Treatment of DB-1 Human Melanoma Xenografts in Mice Aspirin, lysine, mifepristone and doxycycline combined can effectively and safely prevent and treat cancer metastasis: prevent seeds from gemmating on soil.Measuring in vivo tumor pHe with CEST-FISP MRI Intratumoral peptide injection enhances tumor cell antigenicity recognized by cytotoxic T lymphocytes: a potential option for improvement in antigen-specific cancer immunotherapy.Neutralization of Tumor Acidity Improves Antitumor Responses to Immunotherapy.Systemic buffers inhibit carcinogenesis in TRAMP mice Targeting the metabolic microenvironment of tumors.Tumour hypoxia induces a metabolic shift causing acidosis: a common feature in cancer.NaHCO3 enhances the antitumor activities of cytokine-induced killer cells against hepatocellular carcinoma HepG2 cells Buffer Therapy for Cancer.

P2860

Q26741063-DF6C434C-D15B-4F4F-B251-A130B9F97791 Q28079045-D44197AA-5142-4345-9DA0-8424E1473521 Q28541524-811634C3-135A-4A18-A512-CFD48458F84E Q28546400-96023E83-C8EA-481D-8A9E-4BAC6BA530F5 Q28817880-551ADF06-4F9A-4502-801A-7204AB08C137 Q28821895-2B3AEAE1-4710-41A4-A29F-C2E4F2C66607 Q28822460-29FA3842-7DB3-4043-9116-21E1A869E2A4 Q28831507-5FF1F6F8-1ADC-40C5-9916-F613855A57D9 Q30363892-3491C106-E83F-487F-82AE-AFD82F084BAC Q31036207-4275267F-8E57-4F3D-B0ED-F8C226373D04 Q31116734-6DFE8510-87FB-4BDB-B296-B22E6E224442 Q33600827-5F03FFBB-CC2C-4E51-9EC8-33E5300E32C6 Q33616627-BCE31D6B-1C70-40A2-A532-41BEB02BEB9F Q33647236-47CE693C-9FA5-414C-8F48-BA585AE8BECF Q33663027-07F5DA9C-ED11-40B4-B559-DE301FFAA8E6 Q33711068-C524D1E0-A5C3-4BAB-87F5-186B25528DAA Q34000971-53E7E5A1-EA67-4691-B114-8961CE3929AC Q34102943-5F1935E7-952A-43A8-AE28-4BF10BFBF10C Q34390027-7B8B47B7-B182-4EBE-AF53-E062DCEC58CF Q34513382-4A907116-A1CA-423E-B157-3CEF807F6014 Q34561771-755EDEAA-76E4-4737-85D5-1DD7F99483DF Q34581896-861743B3-1FE4-40B1-BC1A-AFD33D2899F7 Q34608666-FEEF6F0F-2DC9-4D90-A10C-815CB6AFBC6C Q34636324-37FFA33A-A5A4-4303-AFD7-ABD42B55E315 Q34676158-3B623926-D27A-441A-AAFC-1AF8469F3F95 Q34985109-A9BAD08C-0493-49CB-BA7A-AA33C1818502 Q35037877-FB405090-5326-4906-9412-0450460B0BC2 Q35592647-47456FD6-1E2A-4169-A384-F3E7EBBF581F Q35623882-22A60B35-A82A-4AD7-B5BD-6393DBEAA779 Q35834783-5C658D25-E3BC-496F-9F63-411881041A18 Q36048258-4F95AA0E-EDA2-494A-A5E3-A3114F00D79B Q36546288-A3FDDE61-2061-4624-BD05-383209C26EBE Q36610934-79ACB350-65E5-4B64-9AF4-5272C7204DB0 Q36759294-A3F74306-DAAE-4B87-AED0-4A673699D340 Q36791129-CA35AA71-404E-4E0F-99ED-87D866F39B74 Q36960515-E27B2943-2764-479C-99FD-5367FF408DE4 Q37229190-DD70B06F-2820-4DC1-AC18-8CC149772A39 Q37295258-C9D7D61D-6E4A-4839-8CE2-9B30140EF9F4 Q37406855-340D4AAA-7318-4BEE-BE5D-28D556765CAB Q37412433-2738BD64-9A38-44D0-94A3-0BC0A2660270

P2860

The potential role of systemic buffers in reducing intratumoral extracellular pH and acid-mediated invasion

http://www.wikidata.org/entity/Q42254342

description

2009 nî lūn-bûn

@nan

2009年の論文

@ja

2009年論文

@yue

2009年論文

@zh-hant

2009年論文

@zh-hk

2009年論文

@zh-mo

2009年論文

@zh-tw

2009年论文

@wuu

2009年论文

@zh

2009年论文

@zh-cn

name

The potential role of systemic ...... pH and acid-mediated invasion

@en

The potential role of systemic ...... pH and acid-mediated invasion

@nl

type

label

The potential role of systemic ...... pH and acid-mediated invasion

@en

The potential role of systemic ...... pH and acid-mediated invasion

@nl

prefLabel

The potential role of systemic ...... pH and acid-mediated invasion

@en

The potential role of systemic ...... pH and acid-mediated invasion

@nl

P1433

Q42254342-E4F694F8-9E89-4546-8907-D256879C89CC

P1476

Q42254342-5E58666F-AC72-4252-9C0A-EFE7821D4F6C

P2093

Q42254342-2948096E-C684-49BA-8EB4-7BE587A1DD32

Q42254342-386369FA-315A-4CED-A353-B8777CC25BEB

Q42254342-5996181D-29E5-4450-A170-6ED363A4CBB0

P2860

Q42254342-0770011B-C4BF-4428-B906-F50E7F6595FA

Q42254342-0A253664-46D7-494F-BCCA-6CA89B428980

Q42254342-0B7EE51A-E6FD-47AE-A4B7-F16D0AE0D2EB

Q42254342-0E421111-3332-4E90-8CB3-AF25A0786C92

Q42254342-12EEB1CA-765B-4140-B463-93EAB97B7EC5

Q42254342-144AB2B3-382A-4422-B9FD-58FB04643BB0

Q42254342-15583BCA-E69F-496C-8F5C-06E6E0FC23B0

Q42254342-2173163B-EE28-4787-9CDD-F9694EFC052C

Q42254342-2758BB31-E507-4400-86B8-C4A29C2736AC

Q42254342-2DD0A38C-78CE-4AF3-A160-4B55CBBF07CA

P304

Q42254342-4A6B9386-3958-4C81-8353-D343B2385679

P31

Q42254342-6AE13A49-400D-47DA-B8BA-62F7F4BBCD60

P356

Q42254342-0DED1DF5-1908-4024-AF45-3EAE4D8A34F8

P407

Q42254342-D90087F1-54DA-429D-9F01-070E7875319D

P433

Q42254342-BA3477A1-56AB-4B38-81F6-008A32323DB5

P478

Q42254342-62F31266-E28D-44F9-99E2-E41CA86104E7

P50

Q42254342-49D2F59C-38D6-47B4-88C3-5925F401839F

P577

Q42254342-C6CDB8C1-7EF7-4DF2-BFB1-5B68589A835E

P5875

Q42254342-18D76BB0-B1B2-4265-9B6B-99E2A4860A58

P698

Q42254342-6D881059-99B7-48FD-B180-9F9FD0CF5B7C

P932

Q42254342-5ED2DDFF-EB5D-4F6D-A1AB-451D8DD87FF4

P356

0008-5472.CAN-08-2394

P1433

Cancer Research

P1476

The potential role of systemic ...... pH and acid-mediated invasion

@en

P2093

Ariosto S Silva

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

Jose A Yunes

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

Robert A Gatenby

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

P2860

Expression of the hypoxia-inducible and tumor-associated carbonic anhydrases in ductal carcinoma in situ of the breast

Hydrogen ion buffers for biological research

Why do cancers have high aerobic glycolysis?

On respiratory impairment in cancer cells

Oxygen diffusion and reaction kinetics in the photodynamic therapy of multicell tumour spheroids.

Bicarbonate increases tumor pH and inhibits spontaneous metastases.

The effects of extracellular pH on immune function.

Involvement of cathepsins in the invasion, metastasis and proliferation of cancer cells.

MRI of the tumor microenvironment.

Positron-emission tomography in prognostic and therapeutic assessment of lung cancer: systematic review.

P304

2677-2684

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

P31

scholarly article

P356

10.1158/0008-5472.CAN-08-2394

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

P407

P433

6

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

P478

69

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

P50

Robert J Gillies

P577

2009-03-10T00:00:00Z

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

P5875

24191548

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

P698

19276380

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

P932

3718046

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