OBJECTIVE: Insufficient myocardial protection is still a considerable cause for in-hospital mortality in children. The purpose of our study was to investigate underlying the basic mechanisms of cardioplegic cardioprotection during hypothermic and normothermic ischemia in a cardiomyocyte cell culture model. METHODS: We cooled cardiomyocytes to 20°C for 20min; during this time, cardiac arrest was simulated by oxidative damage with 2mM H₂O₂ and cardioplegic solution, followed by rewarming to 37°C. Later on, we analyzed cardiomyocyte cell morphology (phase-contrast-microscopy), viability (trypan blue staining), inflammation (cyclooxygenase-2 (Cox-2) and phosphorylated-extracellular signal-regulated kinase (pERK) 1/2 expression in Western blot analysis), and expression of Akt survival protein (Western blot technique). RESULTS: Hypothermia increases cell survival of cardiomyocytes after cardioplegic ischemia, as demonstrated in significantly higher cell viability and less cell death in these cells compared with normothermic H₂O₂-damaged cardiomyocytes. As a possible underlying cellular mechanism, we found that, during cold cardioplegic ischemia, ERK 1/2 enzyme is less phosphorylated than under conditions of normothermic cardioplegic ischemia. This is in line with significantly diminished Cox-2 expression during cold cardioplegic ischemia. Moreover, hypothermic cardioplegia preserved cell survival by upregulation of Akt transcription factor in cardiomyocytes. CONCLUSION: In the present cell culture study, we clearly demonstrated that hypothermia exerts additional protection for cardiomyocytes during cardioplegic ischemia. The understanding of underlying basic mechanisms is evident to improve current techniques of myocardial protection.
OBJECTIVE:Insufficient myocardial protection is still a considerable cause for in-hospital mortality in children. The purpose of our study was to investigate underlying the basic mechanisms of cardioplegic cardioprotection during hypothermic and normothermic ischemia in a cardiomyocyte cell culture model. METHODS: We cooled cardiomyocytes to 20°C for 20min; during this time, cardiac arrest was simulated by oxidative damage with 2mM H₂O₂ and cardioplegic solution, followed by rewarming to 37°C. Later on, we analyzed cardiomyocyte cell morphology (phase-contrast-microscopy), viability (trypan blue staining), inflammation (cyclooxygenase-2 (Cox-2) and phosphorylated-extracellular signal-regulated kinase (pERK) 1/2 expression in Western blot analysis), and expression of Akt survival protein (Western blot technique). RESULTS:Hypothermia increases cell survival of cardiomyocytes after cardioplegic ischemia, as demonstrated in significantly higher cell viability and less cell death in these cells compared with normothermic H₂O₂-damaged cardiomyocytes. As a possible underlying cellular mechanism, we found that, during cold cardioplegic ischemia, ERK 1/2 enzyme is less phosphorylated than under conditions of normothermic cardioplegic ischemia. This is in line with significantly diminished Cox-2 expression during cold cardioplegic ischemia. Moreover, hypothermic cardioplegia preserved cell survival by upregulation of Akt transcription factor in cardiomyocytes. CONCLUSION: In the present cell culture study, we clearly demonstrated that hypothermia exerts additional protection for cardiomyocytes during cardioplegic ischemia. The understanding of underlying basic mechanisms is evident to improve current techniques of myocardial protection.
Authors: Rui Li; Xizhen Xu; Chen Chen; Xuefeng Yu; Matthew L Edin; Laura Miller Degraff; Craig R Lee; Darryl C Zeldin; Dao Wen Wang Journal: Prostaglandins Other Lipid Mediat Date: 2012-10-02 Impact factor: 3.072
Authors: Karla Reichert; Helison Rafael Pereira do Carmo; Fany Lima; Anali Galluce Torina; Karlos Alexandre de Souza Vilarinho; Pedro Paulo Martins de Oliveira; Lindemberg Mota Silveira Filho; Elaine Soraya Barbosa de Oliveira Severino; Orlando Petrucci Journal: Rev Bras Cir Cardiovasc Date: 2013 Oct-Dec
Authors: Jie Sun; Jyotsna Mishra; Meiying Yang; David F Stowe; James S Heisner; Jianzhong An; Wai-Meng Kwok; Amadou K S Camara Journal: Oxid Med Cell Longev Date: 2022-07-13 Impact factor: 7.310