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Literature DB >> 31076465

Mitochondria in Sepsis-Induced AKI.

Jian Sun^1,2, Jingxiao Zhang^1,2, Jiakun Tian¹, Grazia Maria Virzì^2,3, Kumar Digvijay^2,3,4, Laura Cueto^2,5, Yongjie Yin⁶, Mitchell H Rosner⁷, Claudio Ronco^2,3.

Abstract

AKI is a common clinical condition associated with the risk of developing CKD and ESKD. Sepsis is the leading cause of AKI in the intensive care unit (ICU) and accounts for nearly half of all AKI events. Patients with AKI who require dialysis have an unacceptably high mortality rate of 60%-80%. During sepsis, endothelial activation, increased microvascular permeability, changes in regional blood flow distribution with resulting areas of hypoperfusion, and hypoxemia can lead to AKI. No effective drugs to prevent or treat human sepsis-induced AKI are currently available. Recent research has identified dysfunction in energy metabolism as a critical contributor to the pathogenesis of AKI. Mitochondria, the center of energy metabolism, are increasingly recognized to be involved in the pathophysiology of sepsis-induced AKI and mitochondria could serve as a potential therapeutic target. In this review, we summarize the potential role of mitochondria in sepsis-induced AKI and identify future therapeutic approaches that target mitochondrial function in an effort to treat sepsis-induced AKI.

Entities: Disease Species

Keywords: Sepsis-induced AKI; biomarkers; metabolism; mitochondria; therapeutic targets

Mesh：

Substances：

Year: 2019 PMID： 31076465 PMCID： PMC6622414 DOI： 10.1681/ASN.2018111126

Source DB: PubMed Journal: J Am Soc Nephrol ISSN： 1046-6673 Impact factor: 10.121

110 in total

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Journal: N Engl J Med Date: 1999-08-19 Impact factor: 91.245

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Journal: Nat Genet Date: 1999-10 Impact factor: 38.330

Review 3. The pathogenesis of vasodilatory shock.

Authors: D W Landry; J A Oliver
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Authors: Robert W Schrier; Wei Wang
Journal: N Engl J Med Date: 2004-07-08 Impact factor: 91.245

6. Rapamycin impairs recovery from acute renal failure: role of cell-cycle arrest and apoptosis of tubular cells.

Authors: W Lieberthal; R Fuhro; C C Andry; H Rennke; V E Abernathy; J S Koh; R Valeri; J S Levine
Journal: Am J Physiol Renal Physiol Date: 2001-10

Review 7. Nitric oxide in septic shock.

Authors: M A Titheradge
Journal: Biochim Biophys Acta Date: 1999-05-05

8. Vital organ blood flow during hyperdynamic sepsis.

Authors: David Di Giantomasso; Clive N May; Rinaldo Bellomo
Journal: Chest Date: 2003-09 Impact factor: 9.410

9. An autoregulatory loop controls peroxisome proliferator-activated receptor gamma coactivator 1alpha expression in muscle.

Authors: Christoph Handschin; James Rhee; Jiandie Lin; Paul T Tarr; Bruce M Spiegelman
Journal: Proc Natl Acad Sci U S A Date: 2003-05-22 Impact factor: 11.205

10. Arterial norepinephrine changes in patients with septic shock.

Authors: C R Benedict; J A Rose
Journal: Circ Shock Date: 1992-11

53 in total

1. miR-214 represses mitofusin-2 to promote renal tubular apoptosis in ischemic acute kidney injury.

Authors: Yu Yan; Zhengwei Ma; Jiefu Zhu; Mengru Zeng; Hong Liu; Zheng Dong
Journal: Am J Physiol Renal Physiol Date: 2020-01-31

2. Lactate guided resuscitation-nothing is more dangerous than conscientious foolishness.

Authors: Paul E Marik
Journal: J Thorac Dis Date: 2019-09 Impact factor: 2.895

3. Penicilliumin B Protects against Cisplatin-Induced Renal Tubular Cell Apoptosis through Activation of AMPK-Induced Autophagy and Mitochondrial Biogenesis.

Authors: Weiwei Shen; Nan Jia; Jinhua Miao; Shuangqin Chen; Shan Zhou; Ping Meng; Xuefeng Zhou; Lan Tang; Lili Zhou
Journal: Kidney Dis (Basel) Date: 2021-04-01

4. Diabetes Exacerbates Sepsis-Induced Neuroinflammation and Brain Mitochondrial Dysfunction.

Authors: Solange de Souza Stork; Marcos Hübner; Erica Biehl; Lucineia Gainski Danielski; Sandra Bonfante; Larissa Joaquim; Tais Denicol; Thaina Cidreira; Anita Pacheco; Erick Bagio; Everton Lanzzarin; Gabriela Bernades; Mariana Pacheco de Oliveira; Larissa Espindola da Silva; Josiel M Mack; Franciane Bobinski; Gislaine Tezza Rezin; Tatiana Barichello; Emilio Luiz Streck; Fabricia Petronilho
Journal: Inflammation Date: 2022-06-10 Impact factor: 4.092

Review 5. The role of metabolic reprogramming in tubular epithelial cells during the progression of acute kidney injury.

Authors: Zhenzhen Li; Shan Lu; Xiaobing Li
Journal: Cell Mol Life Sci Date: 2021-06-29 Impact factor: 9.261

6. NMR-based serum and urine metabolomic profile reveals suppression of mitochondrial pathways in experimental sepsis-associated acute kidney injury.

Authors: Stephen W Standage; Shenyuan Xu; Lauren Brown; Qing Ma; Adeleine Koterba; Patrick Lahni; Prasad Devarajan; Michael A Kennedy
Journal: Am J Physiol Renal Physiol Date: 2021-04-12

7. Stratifin promotes renal dysfunction in ischemic and nephrotoxic AKI mouse models via enhancing RIPK3-mediated necroptosis.

Authors: Fang Wang; Jia-Nan Wang; Xiao-Yan He; Xiao-Guo Suo; Chao Li; Wei-Jian Ni; Yu-Ting Cai; Yuan He; Xin-Yun Fang; Yu-Hang Dong; Tian Xing; Ya-Ru Yang; Feng Zhang; Xiang Zhong; Hong-Mei Zang; Ming-Ming Liu; Jun Li; Xiao-Ming Meng; Juan Jin
Journal: Acta Pharmacol Sin Date: 2021-04-08 Impact factor: 6.150

Mitochondria in Sepsis-Induced AKI.

Review 1. Hormones and hemodynamics in heart failure.

2. Reanalysis and revision of the Cambridge reference sequence for human mitochondrial DNA.

Review 3. The pathogenesis of vasodilatory shock.

Review 4. Reactive oxygen species and acute renal failure.

Review 5. Acute renal failure and sepsis.

6. Rapamycin impairs recovery from acute renal failure: role of cell-cycle arrest and apoptosis of tubular cells.

Review 7. Nitric oxide in septic shock.

8. Vital organ blood flow during hyperdynamic sepsis.

9. An autoregulatory loop controls peroxisome proliferator-activated receptor gamma coactivator 1alpha expression in muscle.

10. Arterial norepinephrine changes in patients with septic shock.

1. miR-214 represses mitofusin-2 to promote renal tubular apoptosis in ischemic acute kidney injury.

2. Lactate guided resuscitation-nothing is more dangerous than conscientious foolishness.

3. Penicilliumin B Protects against Cisplatin-Induced Renal Tubular Cell Apoptosis through Activation of AMPK-Induced Autophagy and Mitochondrial Biogenesis.

4. Diabetes Exacerbates Sepsis-Induced Neuroinflammation and Brain Mitochondrial Dysfunction.

Review 5. The role of metabolic reprogramming in tubular epithelial cells during the progression of acute kidney injury.

6. NMR-based serum and urine metabolomic profile reveals suppression of mitochondrial pathways in experimental sepsis-associated acute kidney injury.

7. Stratifin promotes renal dysfunction in ischemic and nephrotoxic AKI mouse models via enhancing RIPK3-mediated necroptosis.

Review 8. Sepsis-Associated Acute Kidney Injury.

Review 9. Innovations and Emerging Therapies to Combat Renal Cell Damage: NAD⁺ As a Drug Target.

Review 10. The application of omic technologies to research in sepsis-associated acute kidney injury.

Review 1. Hormones and hemodynamics in heart failure.

Review 3. The pathogenesis of vasodilatory shock.

Review 4. Reactive oxygen species and acute renal failure.

Review 5. Acute renal failure and sepsis.

Review 7. Nitric oxide in septic shock.

Review 5. The role of metabolic reprogramming in tubular epithelial cells during the progression of acute kidney injury.

Review 8. Sepsis-Associated Acute Kidney Injury.

Review 9. Innovations and Emerging Therapies to Combat Renal Cell Damage: NAD+ As a Drug Target.

Review 10. The application of omic technologies to research in sepsis-associated acute kidney injury.

Review 9. Innovations and Emerging Therapies to Combat Renal Cell Damage: NAD⁺ As a Drug Target.