Oxidative Damage in Clinical Ischemia/Reperfusion Injury: A Reappraisal

Vries, Dorottya K. de; Kortekaas, Kim E.; Tsikas, Dimitrios; Wijermars, Leonie G.M.; Noorden, C. J. F. Van; Suchy, Maria-Theresia; Cobbaert, Christa; Klautz, Robert J.M.; Schaapherder, Alexander F.; Lindeman, J.

doi:10.1089/ars.2012.4580

Cited by 75 publications

(57 citation statements)

References 45 publications

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“…Metabolic pathways are responsible for mitochondrial ROS production in a large range of tissues, including livers, kidneys, hearts, and brain [52][53][54]. ].…”

Section: Mitochondrial Effectsmentioning

confidence: 99%

Hypothermic machine perfusion in liver transplantation

Schlegel

Kron

Dutkowski

2016

Current Opinion in Organ Transplantation

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Purpose of the reviewThe purpose of the review is to report recent human application of hypothermic machine liver perfusion, and to discuss potential protective mechanisms. Recent findingsHuman application of hypothermic machine liver perfusion is still very limited. Currently, three transplant centers apply this novel treatment in donation after cardiac death (DCD) or donation after brain death (DBD) liver grafts. In all cases, endischemic perfusion was performed after initial cold storage for organ transport. Perfusion conditions differ slightly in terms of oxygenation (pO 2 15-60 kPa), perfusion route (dual vs. portal), perfusion time (2-4 h), and perfusate. SummaryThe current data support the hypothesis that applying endischemic hypothermic machine liver perfusion protects extended criteria DBD and DCD livers from initial reperfusion injury, with better graft function and less biliary complications. Hypothermic machine perfusion may therefore offer revitalization of liver grafts before implantation by a simple and practical perfusion technique with a high impact on enlarging the donor pool. Multicentric phase III randomized control trials in DBD and DCD liver transplantation have been initiated to further test this strategy, which may establish machine liver perfusion in the clinical setting.

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“…Metabolic pathways are responsible for mitochondrial ROS production in a large range of tissues, including livers, kidneys, hearts, and brain [52][53][54]. ].…”

Section: Mitochondrial Effectsmentioning

confidence: 99%

Hypothermic machine perfusion in liver transplantation

Schlegel

Kron

Dutkowski

2016

Current Opinion in Organ Transplantation

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“…The generation of isoprostanes resulting from lipid peroxidation seems to occur immediately after reperfusion because no further increase in the isoprostane concentration could be observed in subsequent post-operative period Ulus et al, 2003). In contrast, in clinical ischaemia/ reperfusion injury, no increase of 8-iso-PGF 2α levels in plasma and urine during early reperfusion of the ischaemic kidney or heart has been described, indicating a highly complex and sensitive process of isoprostane formation under ischaemic conditions (de Vries et al, 2013). Furthermore, in patients with ischaemic chronic heart failure, levels of 8-iso-PGF2α correlated significantly with indices of remodelling (Radovanovic et al, 2008).…”

mentioning

confidence: 95%

Pathophysiology of isoprostanes in the cardiovascular system: implications of isoprostane‐mediated thromboxane A₂ receptor activation

Bauer

Ripperger

Frantz

et al. 2014

British J Pharmacology

133

109

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Isoprostanes are free radical-catalysed PG-like products of unsaturated fatty acids, such as arachidonic acid, which are widely recognized as reliable markers of systemic lipid peroxidation and oxidative stress in vivo. Moreover, activation of enzymes, such as COX-2, may contribute to isoprostane formation. Indeed, formation of isoprostanes is considerably increased in various diseases which have been linked to oxidative stress, such as cardiovascular disease (CVD), and may predict the atherosclerotic burden and the risk of cardiovascular complications in the latter patients. In addition, several isoprostanes may directly contribute to the functional consequences of oxidant stress via activation of the TxA2 prostanoid receptor (TP), for example, by affecting endothelial cell function and regeneration, vascular tone, haemostasis and ischaemia/reperfusion injury. In this context, experimental and clinical data suggest that selected isoprostanes may represent important alternative activators of the TP receptor when endogenous TxA2 levels are low, for example, in aspirin-treated individuals with CVD. In this review, we will summarize the current understanding of isoprostane formation, biochemistry and (patho) physiology in the cardiovascular context. IntroductionOxidative stress in biological systems is defined as an imbalance between the generation of reactive oxygen species (ROS) and antioxidant defence mechanisms (Dalle-Donne et al., 2006;Giustarini et al., 2009). In contrast to the physiological condition, during which ROS are only present at moderate levels and play an important role as messengers in redox signalling, in pathological conditions, when the physiological redox state of cells is disturbed, ROS can severely affect cellular signalling and function. Indeed, ROS which are not neutralized or scavenged by antioxidant molecules, such as GSH or superoxide dismutase, may react with nucleic acids and proteins and thereby alter the biochemical and physical properties of these important cellular components. Moreover, exposure of lipids to free radicals induces a non-enzymatic reaction cascade resulting in an increased formation of bioactive molecules named isoprostanes. Consequently, systemic isoprostane formation is significantly increased in a variety of pathological processes associated with oxidative stress, for example, cancer as well as, cardiovascular, metabolic and neurodegenerative diseases, and isoprostanes are increasingly recognized not only as markers of oxidative stress but also as mediators of disease progression (Praticò et al., 1997;Reilly et al., 1998;Davì et al., 1999;Minuz et al., 2002;Vassalle et al., 2003;Schwedhelm et al., 2004, Xia et al., 2005Montuschi et al., 2007;Schwedhelm et al., 2010; Barocas et al., 2011;Davies and Roberts, 2011; KhademAnsari et al., 2011;Montine et al., 2011;Sbardella et al., 2013). Isoprostanes are PG-like compounds derived from lipid peroxidation of esterified unsaturated fatty acids, for example, arachidonic acid, which are primarily generated in a free rad...

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“…In the last years, many promising compounds showing antioxidant properties have been under investigation for the prevention and treatment of neural IRI. However, some evidences on other tissues, albeit proving oxidative stress, suggest that the contribution of oxidative damage to human IRI may be less than commonly thought and propose a reevaluation of the mechanism of IRI (15). It is conceivable that the beneficial properties of riluzole in neural IRI may be the result of a combination of different mechanisms.…”

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confidence: 94%

Ischemia-reperfusion injury: evidences for translational research

Bellanti¹

2016

Ann. Transl. Med.

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Oxidative Damage in Clinical Ischemia/Reperfusion Injury: A Reappraisal

Cited by 75 publications

References 45 publications

Hypothermic machine perfusion in liver transplantation

Hypothermic machine perfusion in liver transplantation

Pathophysiology of isoprostanes in the cardiovascular system: implications of isoprostane‐mediated thromboxane A₂ receptor activation

Ischemia-reperfusion injury: evidences for translational research

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Oxidative Damage in Clinical Ischemia/Reperfusion Injury: A Reappraisal

Cited by 75 publications

References 45 publications

Hypothermic machine perfusion in liver transplantation

Hypothermic machine perfusion in liver transplantation

Pathophysiology of isoprostanes in the cardiovascular system: implications of isoprostane‐mediated thromboxane A2 receptor activation

Ischemia-reperfusion injury: evidences for translational research

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Pathophysiology of isoprostanes in the cardiovascular system: implications of isoprostane‐mediated thromboxane A₂ receptor activation