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Difference between revisions of "Rutai 2019 Shock"

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{{Publication
{{Publication
|title=Rutai A, Fejes R, Juhåsz L, Tallósy SP, Poles MZ, Földesi I, Mészåros AT, Szabó A, Boros M, Kaszaki J (2019) Endothelin A and B receptors: Potential pargets for microcirculatory-mitochondrial therapy in experimental sepsis. Shock [Epub ahead of print].
|title=Rutai A, Fejes R, Juhåsz L, Tallósy SP, Poles MZ, Földesi I, Mészåros AT, Szabó A, Boros M, Kaszaki J (2019) Endothelin A and B receptors: Potential pargets for microcirculatory-mitochondrial therapy in experimental sepsis. Shock 54:87-95.
|info=[https://www.ncbi.nlm.nih.gov/pubmed/31318833 PMID: 31318833]
|info=[https://www.ncbi.nlm.nih.gov/pubmed/31318833 PMID: 31318833]
|authors=Rutai A, Fejes R, Juhasz L, Tallosy SP, Poles MZ, Foeldesi I, Meszaros AT, Szabo A, Boros M, Kaszaki J
|authors=Rutai A, Fejes R, Juhasz L, Tallosy SP, Poles MZ, Foeldesi I, Meszaros AT, Szabo A, Boros M, Kaszaki J

Latest revision as of 16:52, 30 June 2020

Publications in the MiPMap
Rutai A, Fejes R, Juhåsz L, Tallósy SP, Poles MZ, Földesi I, Mészåros AT, Szabó A, Boros M, Kaszaki J (2019) Endothelin A and B receptors: Potential pargets for microcirculatory-mitochondrial therapy in experimental sepsis. Shock 54:87-95.

» PMID: 31318833

Rutai A, Fejes R, Juhasz L, Tallosy SP, Poles MZ, Foeldesi I, Meszaros AT, Szabo A, Boros M, Kaszaki J (2019) Shock

Abstract: The hypoxia-sensitive endothelin (ET) system plays an important role in circulatory regulation through vasoconstrictor ETA and ETB2 and vasodilator ETB1 receptors. Sepsis progression is associated with microcirculatory and mitochondrial disturbances along with tissue hypoxia. Our aim was to investigate the consequences of treatments with the ETA receptor (ETA-R) antagonist, ETB1 receptor (ETB1-R) agonist, or their combination on oxygen dynamics, mesenteric microcirculation and mitochondrial respiration in a rodent model of sepsis. Sprague Dawley rats were subjected to fecal peritonitis (0.6 g kg ip) or a sham operation. Septic animals were treated with saline or the ETA-R antagonist ETR-p1/fl peptide (100 nmol kg iv), the ETB1-R agonist IRL-1620 (0.55 nmol kg iv), or a combination therapy 22 h after induction. Invasive hemodynamic monitoring and blood gas analysis were performed during a 90-min observation, plasma ET-1 levels were determined, and intestinal capillary perfusion (CPR) was detected by intravital videomicroscopy. Mitochondrial Complex I (CI)- and CII-linked oxidative phosphorylation (OXPHOS) was evaluated by high-resolution respirometry in liver biopsies. Septic animals were hypotensive with elevated plasma ET-1. The ileal CPR, oxygen extraction (ExO2), and CI-CII-linked OXPHOS capacities decreased. ETR-p1/fl treatment increased ExO2 (by >45%), CPR, and CII-linked OXPHOS capacity. The administration of IRL-1620 countervailed the sepsis-induced hypotension (by >30%), normalized ExO2, and increased CPR. The combined ETA-R antagonist-ETB1-R agonist therapy reduced the plasma ET-1 level, significantly improved the intestinal microcirculation (by >41%), and reversed mitochondrial dysfunction. The additive effects of a combined ETA-R-ETB1-R-targeted therapy may offer a tool for a novel microcirculatory and mitochondrial resuscitation strategy in experimental sepsis. ‱ Keywords: Fecal peritonitis, Endothelin receptors, Oxygen extraction, Microcirculation, Mitochondrial respiration, Resuscitation, Rat ‱ Bioblast editor: Plangger M ‱ O2k-Network Lab: HU Szeged Boros M, AT Innsbruck Oroboros


Labels: MiParea: Respiration, Pharmacology;toxicology  Pathology: Sepsis 

Organism: Rat  Tissue;cell: Liver  Preparation: Homogenate 


Coupling state: LEAK, OXPHOS  Pathway: N, S, ROX  HRR: Oxygraph-2k 

Labels, 2020-02