about
pH sensing and regulation in cancerGene expression profile of human lung epithelial cells chronically exposed to single-walled carbon nanotubesCarbon nanotubes induce malignant transformation and tumorigenesis of human lung epithelial cellsInduction of stem-like cells with malignant properties by chronic exposure of human lung epithelial cells to single-walled carbon nanotubes'There and back again': revisiting the pathophysiological roles of human endogenous retroviruses in the post-genomic eraGenetic Heterogeneity and Clonal Evolution of Tumor Cells and their Impact on Precision Cancer MedicineModes of resistance to anti-angiogenic therapyThe Significance of an Enhanced Concept of the Organism for MedicineOvercoming Hypoxia-Mediated Tumor Progression: Combinatorial Approaches Targeting pH Regulation, Angiogenesis and Immune DysfunctionHepatocyte Growth Factor from a Clinical Perspective: A Pancreatic Cancer ChallengeEvolutionary determinants of cancerAutophagy in stem cells.From modules to medicine: How modular domains and their associated networks can enable personalized medicineA periodic table for cancerBioinformatics for cancer immunology and immunotherapyRecent developments in targeting carbonic anhydrase IX for cancer therapeuticsQuantitative imaging in cancer evolution and ecologyHypoxia, cancer metabolism and the therapeutic benefit of targeting lactate/H(+) symportersEvolution evolves: physiology returns to centre stageChallenging the axiom: does the occurrence of oncogenic mutations truly limit cancer development with age?Lactic acidosis triggers starvation response with paradoxical induction of TXNIP through MondoALactate dehydrogenase 5 expression in Non-Hodgkin lymphoma is associated with the induced hypoxia regulated protein and poor prognosisCancer evolution is associated with pervasive positive selection on globally expressed genesEvolved tumor suppression: why are we so good at not getting cancer?How cancer shapes evolution, and how evolution shapes cancerImplications of systemic dysfunction for the etiology of malignancyEvolutionary foundations for cancer biologyActivation of β-catenin by oncogenic PIK3CA and EGFR promotes resistance to glucose deprivation by inducing a strong antioxidant responseInformation dynamics in living systems: prokaryotes, eukaryotes, and cancerClonal evolution in cancerDefining the role of hypoxia-inducible factor 1 in cancer biology and therapeuticsRadioactive 198Au-doped nanostructures with different shapes for in vivo analyses of their biodistribution, tumor uptake, and intratumoral distribution.New paradigm for management of hepatocellular carcinoma by imaging.Emergence of spatial structure in the tumor microenvironment due to the Warburg effectWarburg effect's manifestation in aggressive pheochromocytomas and paragangliomas: insights from a mouse cell model applied to human tumor tissue.The genomic analysis of lactic acidosis and acidosis response in human cancersCancer reduces transcriptome specialization.Modeling tumor growth and treatment response based on quantitative imaging dataThe Müllerian HOXA10 gene promotes growth of ovarian surface epithelial cells by stimulating epithelial-stromal interactionsEvaluations of extracellular pH within in vivo tumors using acidoCEST MRI
P2860
Q21129239-719D812A-8B88-42DA-BD82-101AA8AB4262Q23912208-C8705F8B-8653-437E-8283-C01F8FBD0CEDQ23917072-21A961E8-9CD2-4961-9A1F-0A25B0F8AB08Q23921936-0AC4EE14-7F06-4A71-A878-DA91AD20CC92Q24289157-C5F9A4AE-D458-4248-BE0F-07F3E5692A7FQ24604479-3BDB96F8-AC53-451D-B448-2D420939C135Q24608005-FFCAB0E1-EA8A-4A1E-BFD4-1760D6A9AC96Q26742133-4CEFA17F-6CC5-4F0F-B944-E031321D1F4AQ26749333-BFC10BBE-503B-454A-963C-20B42BCE2A9DQ26781273-898D3368-5FA3-454E-8732-15EC51AF5CF1Q26801710-7575980C-C505-4471-BE54-B3F60AC93BC4Q26823995-85945656-DE29-4DE9-BB6D-F955C51BE056Q26830811-E04C0BF3-A1A6-41D8-B888-83DBFA68DB9AQ26858878-9DE233B6-AB31-4E8D-92D0-5F9718400EFBQ26864876-81B7E627-B242-4F94-BC82-CCDFB19BBF13Q27013023-04F0FF53-2798-48E2-98A2-625A4EC22EDDQ27016021-B2F7A41C-4848-4EDC-8FFB-B56815CFBB72Q28081811-C62D56DB-3DDD-4D9E-9068-5FD395B0FC11Q28241056-0243ED98-A6D0-4C1A-B818-D5D7D817146BQ28383732-B94AB859-6599-480B-AE24-5CE5B56CCA07Q28475481-6BD76337-C698-4767-918A-9A6BB0C6D7B4Q28533757-4E4D5F09-5644-4A0A-AB63-0006DD4C9172Q28540541-AD3A290D-CA76-4596-BBEA-DC9341A5384EQ28681637-5B0A2655-4825-4959-B026-1F96D074D364Q28688052-86980119-5189-4F4A-B3EE-4A129219177CQ28708952-6DAA040F-7EF2-471F-BC8B-0BCC0E7434D4Q28709090-05545580-36B8-48BE-BCD2-1EA13BEE2AB0Q28729157-DF2451C2-EF3E-4B59-8B5B-512508CA50EDQ28742426-15314F65-3829-4412-A284-00DFD44634ADQ29547696-50728A6E-6645-4FBC-98D1-3591802B12AFQ29615944-9BC7E731-C80C-4E36-9784-97DFAA7D9880Q30413615-7B13D3F0-5951-4A00-A5CE-909CE9945BF6Q30448048-8F3AE3B5-D487-42EF-B5C9-DF886941E751Q30558209-B12F73A3-1D85-4432-91F6-18C34B01FF84Q31079334-893146A6-1FA6-4E5D-8E3B-574106F75054Q33389864-D60BD12E-2B6C-4490-92F4-3186D6BC5324Q33573483-BA8EC836-82A2-408E-BAC5-21B4F4E36DE1Q33623804-7A708C60-2345-433A-A992-9FD30B534051Q33624201-4E9822B6-A80F-4B21-8BF6-0B90B4D2F51FQ33663027-243BEDC2-DED5-4769-9483-7F3C24BFBE64
P2860
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh-hant
name
A microenvironmental model of carcinogenesis.
@en
A microenvironmental model of carcinogenesis.
@nl
type
label
A microenvironmental model of carcinogenesis.
@en
A microenvironmental model of carcinogenesis.
@nl
prefLabel
A microenvironmental model of carcinogenesis.
@en
A microenvironmental model of carcinogenesis.
@nl
P356
P1476
A microenvironmental model of carcinogenesis.
@en
P2093
Robert A Gatenby
P2888
P356
10.1038/NRC2255
P407
P577
2008-01-01T00:00:00Z