Myocardial Protection During Cabg Procedures: "The Optimal Flow For Bloodcardioplegia During Aortic Occlusion Is Regulated By The Heart Itself"

Abstract

Myocardial protection remains an important, much discussed subject in cardiac surgical practice. Literature describes different methods. A minimal haemodilutional method of arresting and protecting the heart using warm oxygenated patient blood directly from the oxygenator is described by Calafiore et.al. bloodcardioplegiaflow (BCF) during aortic occlusion is regulated by a rollerpump. Following a defined protocol, a syringepump is set to deliver the highly concentrated potassiumsolution in the bloodcardioplegia line. Myocardial protection remains an important, much discussed subject in cardiac surgical practice. Literature describes different methods. A minimal haemodilutional method of arresting and protecting the heart using “warm” oxygenated patient blood directly from the oxygenator is described by Calafiore et.al. bloodcardioplegiaflow (BCF) during aortic occlusion is regulated by a rollerpump. Following a defined protocol (table 3), a syringepump is set to deliver the highly concentrated potassiumsolution in the bloodcardioplegia line. Figure 1 Table 3: Blood cardioplegia intervals This method of protecting the heart during aortic crossclamping appears to be more effective then cold crystalloid cardioplegia. However, using a defined BCF can be at a disadvantage because this method does not take into consideration the myocardial mass and functional status of the heart. To overcome these limitations we modified the Calafiore-method in the “Isala”-method to provide pressure/afterload regulated cardioplegia flow delivery. BCF is generated by the centrifugalpump which is integrated in our extra corporeal circuit and situated before the oxygenator. Oxygenated blood derived from the recirculationport of the oxygenator is supplemented with concentrated potassiumsolution (2 mmol/ml) and delivered directly to the myocardium through an aortic-root cannula (figure 1 and table 1). Myocardial Protection During Cabg Procedures: The Optimal Flow For Bloodcardioplegia During Aortic Occlusion Is Regulated By Heart Itself 2 of 5 Figure 2 Table 1: Components extra corporeal circuit Figure 3 Figure 1: Extra corporeal circuit BCF is measured with an ultrasonic flowmeter (HT311, Transonic Systems). value of the BCF depends on the pressure at the outletport, which equals arterial linepressure, the length of the cardioplegia line, the pressuredrop over the aortic-root cannula or saphenous vein cannula (figure 2) and, most important, the functional status of the heart and the resistance of the myocardial vasculature. Figure 4 Figure 2: Pressuredrop coronary cannula To achieve a potassium concentration of either 20 mmol/l (initial dose) or 10mmol/l (maintenance dose) the settings of the potassium syringepump are based on the measured flowrate and the patients systemic potassium concentration. This 'Isala'-technique results in a selfregulated BCF with the advantages of a centrifugalpump such as an automatic pressure limitation in the bloodcardioplegia system and the heart itself. BCF gives additional information about the presence and degree of aortic insufficiency and also about the quality of the anastomoses. This pilot-study compares the 'Isala' technique with the Calafiore technique and with the use of cold St.Thomas Hospital II cardioplegia. 60 consecutive patients (20 in each group) scheduled for first time coronary bypass surgery were enrolled in this study. All patients were operated on by the same cardiac surgeon. There were no significant differences between the groups regarding to ECC time, aortic crossclamping time and number of anastomoses (table 2). We observed that the BCF was higher with the 'Isala' technique (figure 3). Myocardial Protection During Cabg Procedures: The Optimal Flow For Bloodcardioplegia During Aortic Occlusion Is Regulated By Heart Itself 3 of 5 Figure 5 Figure 3: Blood cardioplegia flow duration of bloodcardioplegia delivery was shorter with the Isala technique (figure 4). amount of potassium administered equals the Calafiore technique (table 2). Figure 6 Table 2: Patient data Figure 7 Figure 4: Bloodcardioplegia perfusion time We observed that the CK and CK-mb was lower with the 'Isala'-technique compared with the Calafioreor crystaloid technique (figure 5). Figure 8 Figure 5: CK and CK-mb In conclusion we find the 'Isala'-technique a safe and easy method of delivering an optimal BCF during aortic occlusion and that it can be used safely for any cardiac surgical procedure requiring myocardial arrest. selfregulating characteristics of the 'Isala'-technique showed that the flow for bloodcardioplegia depends on the (metabolic) demands of the heart itself and that it varies between 100 and 550 ml/min. We observed a better myocardial protection during CABG procedures. optimal and/or maximal duration of the ischaemic intervals and the duration of the bloodcardioplegia delivery has to be investigated. Further research is necessary to determine the clinical improvement using this technique.