about
Synchronous recruitment of epigenetic modifiers to endotoxin synergistically activated Tnf-α gene in acute kidney injuryEpigenetics in acute kidney injuryDeficiency of heme oxygenase-1 impairs renal hemodynamics and exaggerates systemic inflammatory responses to renal ischemia.Acute hepatic ischemic-reperfusion injury induces a renal cortical "stress response," renal "cytoresistance," and an endotoxin hyperresponsive stateHsp72 is a novel biomarker to predict acute kidney injury in critically ill patients.MicroRNA-24 antagonism prevents renal ischemia reperfusion injuryCardio-renal cachexia syndromes (CRCS): pathophysiological foundations of a vicious pathological circleCatalpol protects mice against renal ischemia/reperfusion injury via suppressing PI3K/Akt-eNOS signaling and inflammation.Erythropoietin gene-enhanced marrow mesenchymal stromal cells decrease cisplatin-induced kidney injury and improve survival of allogeneic mice.Hsp72 is an early and sensitive biomarker to detect acute kidney injury.Heterogeneity of epigenetic changes at ischemia/reperfusion- and endotoxin-induced acute kidney injury genes.Long-term remote organ consequences following acute kidney injury.Efficacy and safety of renal tubule cell therapy for acute renal failureAcute kidney injury leads to inflammation and functional changes in the brain.Cordyceps sinensis protects against liver and heart injuries in a rat model of chronic kidney disease: a metabolomic analysis.Nucleophosmin, a critical Bax cofactor in ischemia-induced cell deathThe kidney in the critically ill.BRG1 increases transcription of proinflammatory genes in renal ischemia.Uremia impacts renal inflammatory cytokine gene expression in the setting of experimental acute kidney injury.The bioartificial kidney in the treatment of acute kidney injury.Urinary biomarkers of AKI and mortality 3 years after cardiac surgery.Cardio-renal syndromes: from foggy bottoms to sunny hills.Acute kidney injury: the beginning of the end of the dark agesAre recently reported biomarkers helpful for early and accurate diagnosis of acute kidney injury?Epigenetic alterations in acute kidney injury.Organ cross talk and remote organ damage following acute kidney injury.Vascular and circulating microRNAs in renal ischaemia-reperfusion injury.Fabry's disease: an example of cardiorenal syndrome type 5.Mechanisms and mediators of lung injury after acute kidney injury.Reno-Cerebral Reflex Activates the Renin-Angiotensin System, Promoting Oxidative Stress and Renal Damage After Ischemia-Reperfusion Injury.Intravenous cell therapy for acute renal failure with serum amyloid A protein-reprogrammed cells.Acute Kidney Injury as a Risk Factor for Delirium and Coma during Critical Illness.Our paper 20 years later: from acute renal failure to acute kidney injury--the metamorphosis of a syndrome.Gender Differences in the Acute Kidney Injury to Chronic Kidney Disease Transition.Ultrasonography: Ariadne's Thread in the Diagnosis of the Cardiorenal Syndrome.Human marrow-derived mesenchymal stromal cells decrease cisplatin renotoxicity in vitro and in vivo and enhance survival of mice post-intraperitoneal injection.Adrenalectomy prevents renal ischemia-reperfusion injury.Comparison of protective and curative potential of Daucus carota root extract on renal ischemia reperfusion injury in rats.A Call to Action to Develop Integrated Curricula in Cardiorenal Medicine.Hypoxia-induced long non-coding RNA Malat1 is dispensable for renal ischemia/reperfusion-injury.
P2860
Q27310345-21E4369A-0427-453C-B83C-24427E98EBCCQ28080924-DD52462E-CEC0-454A-9A82-6473BF33CE56Q34170314-CF22F81D-B418-4A4A-BDC5-861AB8697AF9Q34295298-80EC97FF-3314-477A-B714-E9CA4A526D0EQ34338185-230BE772-B5F5-4A4D-A3B6-81094BAB9F5EQ34568822-2629E513-AEF0-460A-93F2-5F097D28152DQ35223968-8CC16E68-48B1-4329-BBD6-63805363A01AQ35479838-421EA82A-D5D6-44E3-B50C-D8D2FE9B2D02Q35568537-6DA1A91C-40A7-42BA-802E-6FF846117E59Q36108356-5EE07F61-0A3E-4A27-96DE-BF286FE38B90Q36108877-B0951901-8D5A-4772-BE31-7F511F3BC19AQ36424776-97B69850-BAB9-4D91-AAD3-B51F18AE39B1Q36662156-531234CA-A486-4F97-BC16-51BBCC67934EQ36736770-EF29C0FA-8DCD-45D7-B8BB-F26EF710AE1EQ36745803-61828DBD-545F-4872-9B8E-37D3C002C5BDQ36826808-EE8766D2-2516-4865-B356-95A86A6591EFQ36938144-E1C0F0AE-6434-4F56-A530-86BA7BB769ABQ37297704-80C55212-716F-45D8-9C9F-438DAE2C7B84Q37417285-0FF4868A-AACB-43DC-81FB-07585AD0B0FBQ37466080-170E5E8D-72B4-4A44-B95A-65572F4A0959Q37733594-2CF825AA-613D-4996-AE28-1F4D13338887Q37831837-C9D11861-CFF5-404D-89D1-EDF7E6DCB322Q37911897-247E7988-335C-4581-B30C-ED4B76573539Q38003686-E6A64305-C9A0-4645-9865-EB055C7918D6Q38134935-0ABEF76B-A341-43AB-8300-C7B64E758DBBQ38223326-F8ED9C0B-9932-4916-A6E4-1E029A0980EEQ38359546-EBF9E6E6-4266-4C95-95F1-3FB1B5F39621Q38558725-A61D17F7-759D-4106-AE9E-AF0E8901D230Q38598669-FFB1689E-57E6-4F10-8EF0-82F5C94B0A4FQ39057673-BA113D6B-E916-4BDE-B114-93F42D4FE64EQ39695145-FFC1255E-E45C-4F01-B553-4E65B58B9D07Q40472274-22643639-99E5-47CE-B072-43A538875C93Q40618014-87976A60-FA27-4069-860D-DA484EE3C4F2Q41933558-AE113C99-2D50-44C2-BFED-DBBD8D50C78EQ42093120-C3D72213-2523-4DE9-975C-434B0141286EQ42906411-E56F450A-C687-4B9F-80D5-D6533464B490Q43298131-5C9E9877-99AF-4CCF-8EC3-81F0F6926856Q45751202-06608D03-3453-4DC7-8B71-183A06264F9DQ47879265-358CC5CF-A40E-424B-962E-3444FC891DFFQ50284691-703733C0-8CBF-4DBE-BF27-3D7E1E748291
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh
2006年學術文章
@zh-hant
name
Acute renal failure: much more than a kidney disease.
@ast
Acute renal failure: much more than a kidney disease.
@en
type
label
Acute renal failure: much more than a kidney disease.
@ast
Acute renal failure: much more than a kidney disease.
@en
prefLabel
Acute renal failure: much more than a kidney disease.
@ast
Acute renal failure: much more than a kidney disease.
@en
P1476
Acute renal failure: much more than a kidney disease.
@en
P2093
P304
P356
10.1016/J.SEMNEPHROL.2005.09.003
P577
2006-03-01T00:00:00Z