Role for TNF in atherosclerosis? Lessons from autoimmune disease.
about
Historical perspectives on tumor necrosis factor and its superfamily: 25 years later, a golden journeyInflammatory cytokines and risk of coronary heart disease: new prospective study and updated meta-analysisEffects of total flavonoids from Dracocephalum moldavica on the proliferation, migration, and adhesion molecule expression of rat vascular smooth muscle cells induced by TNF-αCardiovascular outcomes and tumour necrosis factor antagonists in chronic inflammatory rheumatic disease: a focus on rheumatoid arthritis.Curcumin suppresses tumor necrosis factor-α-induced matrix metalloproteinase-2 expression and activity in rat vascular smooth muscle cells via the NF-κB pathwayPolyphenols and aging.PMC, a potent hydrophilic α-tocopherol derivative, inhibits NF-κB activation via PP2A but not IκBα-dependent signals in vascular smooth muscle cells.Genetic regulation of endothelial inflammatory responses in baboons.Accelerated atherosclerosis in systemic lupus erythematosus: role of proinflammatory cytokines and therapeutic approaches.TNF-α, IFN-γ, IL-10, and IL-4 levels were elevated in a murine model of human sickle cell anemia maintained on a high protein/calorie diet.Elevated C-reactive protein levels and enhanced high frequency vasomotion in patients with ischemic heart disease during brachial flow-mediated dilation.Scropolioside B inhibits IL-1β and cytokines expression through NF-κB and inflammasome NLRP3 pathways.Cardiovascular risk in rheumatoid arthritis: recent advances in the understanding of the pivotal role of inflammation, risk predictors and the impact of treatmentAndrographolide enhances nuclear factor-kappaB subunit p65 Ser536 dephosphorylation through activation of protein phosphatase 2A in vascular smooth muscle cells.Probing the mechanical properties of TNF-α stimulated endothelial cell with atomic force microscopyComprehensive gene expression profiling reveals synergistic functional networks in cerebral vessels after hypertension or hypercholesterolemia.TNFa alter cholesterol metabolism in human macrophages via PKC-θ-dependent pathwayInterleukin-1 and acute brain injury.What is the future of targeted therapy in rheumatology: biologics or small molecules?Analysis of the role of interleukin 6 receptor haplotypes in the regulation of circulating levels of inflammatory biomarkers and risk of coronary heart diseaseImpact of aging vs. estrogen loss on cardiac gene expression: estrogen replacement and inflammationEffect of interleukin-6 receptor blockade on surrogates of vascular risk in rheumatoid arthritis: MEASURE, a randomised, placebo-controlled study.Paraoxonase-3 is depleted from the high-density lipoproteins of autoimmune disease patients with subclinical atherosclerosis.Sry-type HMG box 18 contributes to the differentiation of bone marrow-derived mesenchymal stem cells to endothelial cells.Targeting Tumor Necrosis Factor-α with Adalimumab: Effects on Endothelial Activation and Monocyte Adhesion.Ways of coping and biomarkers of an increased atherothrombotic cardiovascular disease risk in elderly individualsEffect of Alzheimer caregiving on circulating levels of C-reactive protein and other biomarkers relevant to cardiovascular disease risk: a longitudinal studyReactive Oxygen Species, SUMOylation, and Endothelial InflammationBeta-adrenergic receptor mediated inflammation control by monocytes is associated with blood pressure and risk factors for cardiovascular diseaseTNF-α induces CXCL1 chemokine expression and release in human vascular endothelial cells in vitro via two distinct signaling pathways.Differential TNF production by monocyte subsets under physical stress: blunted mobilization of proinflammatory monocytes in prehypertensive individuals.Treatment with chondroitin sulfate to modulate inflammation and atherogenesis in obesityPhosphorylation of protein inhibitor of activated STAT1 (PIAS1) by MAPK-activated protein kinase-2 inhibits endothelial inflammation via increasing both PIAS1 transrepression and SUMO E3 ligase activity.Unexpected arterial wall and cellular inflammation in patients with rheumatoid arthritis in remission using biological therapy: a cross-sectional study.Local perivascular adiponectin associates with lower extremity vascular operative wound complicationsSuppression of coronary atherosclerosis by helix B surface Peptide, a nonerythropoietic, tissue-protective compound derived from erythropoietin.Development of Advanced Atherosclerotic Plaque by Injection of Inflammatory Proteins in a Rabbit Iliac Artery Model.Immune activation and collateral damage in AIDS pathogenesis.Local TNF causes NFATc1-dependent cholesterol-mediated podocyte injury.Plasma from rheumatoid arthritis patients promotes pro-atherogenic cholesterol transport gene expression in THP-1 human macrophages.
P2860
Q26991848-BD11677A-608E-4C34-893C-45E093F257D9Q27001736-68ACAA36-E715-4FA3-9106-E9C6DCA4BAEFQ28569978-91E49F3F-F009-4E98-98D8-455A4CAADB54Q30240180-D01F95A3-42D1-4DD1-AAC6-616887232068Q33706241-8B0FC76C-B3DB-4C1C-BD87-8BE0DB894BDDQ33957220-61BF9A6A-3E7E-4304-9C1A-A7AAE1E67EFEQ34011446-8824124B-481B-4E64-BBC6-CDC6144DE057Q34013077-4D9D9456-9F1A-4245-9E86-BE87919D5722Q34170097-6EC2A7A3-7682-4794-8CE8-29906A4B1050Q34180765-1A344FB6-2B2D-4165-B64D-6592D60AC444Q34316820-5275BD73-C726-4BF1-9F23-CBC0C65CA994Q34438283-F89691C1-5184-4F1B-A0B1-18021FDC4F73Q34563216-177EAB02-CEB1-4FB0-87C1-C6CE13D8AA6EQ34675805-8ACAF242-F7D8-49C6-9FE7-8482901C215EQ34788119-C450D82D-DB4F-4EBB-B0C1-F28FE7BB59A7Q34848063-F358510B-FD76-41F9-94C8-6E55C7A8F326Q34892550-672C682B-7F81-4866-978C-DED6A1D00EFDQ35056860-CF48F426-F045-4788-8231-A27B4012953CQ35118364-4D48F467-9288-42FF-8EAD-FF64E4615012Q35189294-C6DE6546-846F-4A0C-83DA-600298055001Q35233878-43F03152-A67A-4AD1-8D0D-2DF03817B0F3Q35352554-1F6615B2-ECA2-4DA9-9371-D00CBA1B9F1BQ35615662-931E93A6-5DB7-4856-8FEB-10F8BED63951Q35776368-3EF7A3BE-036E-421B-8E9D-88E119361569Q36088839-06B494E7-A096-450F-9945-2BE195076702Q36118514-D212DB57-867E-4401-9057-933B245A440EQ36182377-E349AA03-677A-4111-A2D3-BA0EFA841244Q36237663-825969CC-5A37-4A6C-AE8D-0B91E73885D6Q36244806-2E3146C9-055C-4935-B597-908E301F56E4Q36287450-5B0AA3C2-C5D0-469B-9AD9-D7173DDE2571Q36456727-FD0ACEEF-B685-4847-A1A9-8139DE1C8D57Q36535288-7EE2755C-C475-4DA1-9E5D-FCB8D720FDBDQ36542470-4D76B0DE-9EDE-4F35-AF7B-6BF07344FE20Q36923331-663E7264-B06E-457E-9CAC-AFE55F6FC1FCQ36995501-F003A391-31FC-400C-9716-68F834BAACD4Q37100284-BDB19042-1EEF-4E56-8100-B9F7D35E1251Q37124756-1EA78B92-AC27-422C-8B30-F4E4C6C7C7C9Q37199493-6C04A88C-1CA2-4507-98A7-5530EA98E914Q37217446-FB2345C0-1118-4AFB-8309-310FEC8C4BDEQ37413355-294374C7-D5A9-4198-A5B9-8868DAEF5B0D
P2860
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on June 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@en
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@nl
type
label
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@en
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@nl
prefLabel
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@en
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@nl
P356
P1476
Role for TNF in atherosclerosis? Lessons from autoimmune disease.
@en
P2093
David W McCarey
Gayle E McKellar
P2888
P304
P356
10.1038/NRCARDIO.2009.57
P407
P577
2009-06-01T00:00:00Z
P6179
1002527448