Biochemical Changes in Cardiopulmonary Bypass in Cardiac Surgery: New Insights.
Luan Oliveira FerreiraVictoria Winkler VasconcelosJanielle de Sousa LimaJaime Rodrigues Vieira NetoGiovana Escribano da CostaJordana de Castro EstevesSallatiel Cabral de SousaJonathan Almeida MouraFelipe Ruda Silva SantosJoão Monteiro Leitão FilhoMatheus Ramos ProtásioPollyana Sousa AraújoCláudio José da Silva LemosKarina Dias ResendeDielly Catrina Favacho LopesPublished in: Journal of personalized medicine (2023)
Patients undergoing coronary revascularization with extracorporeal circulation or cardiopulmonary bypass (CPB) may develop several biochemical changes in the microcirculation that lead to a systemic inflammatory response. Surgical incision, post-CPB reperfusion injury and blood contact with non-endothelial membranes can activate inflammatory signaling pathways that lead to the production and activation of inflammatory cells, with cytokine production and oxidative stress. This inflammatory storm can cause damage to vital organs, especially the heart, and thus lead to complications in the postoperative period. In addition to the organic pathophysiology during and after the period of exposure to extracorporeal circulation, this review addresses new perspectives for intraoperative treatment and management that may lead to a reduction in this inflammatory storm and thereby improve the prognosis and possibly reduce the mortality of these patients.
Keyphrases
- oxidative stress
- patients undergoing
- induced apoptosis
- inflammatory response
- cardiac surgery
- end stage renal disease
- signaling pathway
- newly diagnosed
- chronic kidney disease
- heart failure
- diabetic rats
- coronary artery disease
- ejection fraction
- prognostic factors
- acute kidney injury
- acute myocardial infarction
- endothelial cells
- immune response
- cardiovascular disease
- patient reported outcomes
- cell proliferation
- peritoneal dialysis
- cerebral ischemia
- atrial fibrillation
- cell cycle arrest
- left ventricular
- replacement therapy
- heat shock
- heat stress