Six-years survival and predictors of mortality after CABG using cold vs. warm blood cardioplegia in elective and emergent settings

The concept of myocardial protection during cardiac surgery have been already described in detail in the 1950s by Bigelow, who proposed to use hypothermia as a strategy to protect the myocardium in heart surgery [1]. In this respect, a reduction in myocardial oxygen consumption up to 80 % can be achieved by lowering the blood temperature up to 20 °C. However, the disadvantage of the isolated hypothermia without an additional usage of cardioplegia results in an incomplete electromechanical cardiac arrest with ventricular fibrillation. Therefore, subsequent studies by Gay and Ebert support the use of potassium-rich solution for the induction of diastolic cardiac arrest by depolarization [2]. In addition, further development of blood cardioplegia by Follette and Buckberg as a composition of blood and crystalloid solution improved myocardial protection enormously [2, 3]. Finally, the next breakthrough was the development of normothermic blood cardioplegia in which Calafiore has set new standards in myocardial protection during cardiac surgery [4, 5].

Currently, a large variety of techniques for myocardial protection is available in cardiac surgery. Most surgical centers in the USA and west european countries preferably apply blood cardioplegia as several studies indicated superiority of blood cardioplegia over crystalloid solutions [6]. Nevertheless, the debate over the optimal cardioplegia strategy, the way of application and temperature is still under discussion [7]. Moreover, other additional potentially cardioprotective effects on ischemic myocardium are discussed in the literature [8]. In our institution intermittent blood cardioplegia is used in coronary artery bypass grafting (CABG) patients and is administered antegradely either as intermittent normothermic cardioplegia (IWC) according to Calafiore’s warm blood cardioplegia or intermittent hypothermic cardioplegia (ICC) according to Buckberg’s cold blood cardioplegia. Nowadays, the IWC as a simple and cost-effective method is in widespread use throughout the world. Whereas several studies have been focused on differences and similarities in blood cardioplegia in elective CABG patients, there has been a lack of evidence in terms of applicability of different cardioplegia in emergent settings. The aim of the present study was to critically examine both myocardial protection strategies in patients undergoing emergent CABG and patients receiving elective CABG.

Patient demographics and preoperative baseline characteristics are listed in Table 1. There were no statistically significant differences between ICC and IWC groups except for proportion of patients on regular statin medication (66.7 % in the ICC group vs. 80.7 % in the IWC group, p = 0.035) in the emergent subgroup and with the presence of left main disease with more than 50 % stenosis (34.5 % in the ICC group vs. 23.5 % in the IWC group, p = 0.026) in the elective subgroup. Patients were comparable in terms of past medical history, cardiac risk factors, preoperative medication and logistic Euroscore.

Table 2 represents intra-operative patient data for both groups. In the emergent subgroup, patients receiving IWC had longer cross clamp time (41.1 ± 13.9 vs. 35.4 ± 12.2 min, p = 0.005), whereas patients receiving ICC were associated with significantly longer administration time (5.9 ± 2,2 vs. 5.0 ± 2.7 min, p = 0.017) and amount (329 ± 155 vs. 18.5 ± 5.6 ml, p < 0.001) of cardioplegia compared to IWC group. Similar associations were also found within the elective subgroup. In terms of intraoperative data within both subgroups there were no statistically significant differences in CPB, operation and, reperfusion time, and the usage of IMA. Groups were also comparable regarding phosphodiesterase-III-inhibitor usage, and the need for hemofiltration.

Postoperative patients’ characteristics are presented in Table 3. The mean number of platelet units transfused in the elective subgroup was 0.62 ± 1.43 in the ICC group and 0.31 ± 0.72 in the IWC group (p = 0.003). The 30-day all cause mortality in the elective subgroup tended to be increased in the IWC group with 2 % in contrast to 0 % in ICC group, however it did not reach statistical significance (p = 0.072). Similarly, in the emergent subgroup, the 30-day mortality was 5,1 % in the ICC group vs. 4,2 % in the IWC group not reaching statistical significance. During cardiac surgery in the emergent subgroup 10.8 % patients of the ICC group received an intra-aortic balloon pump (IABP) compared to 6.5 % of the IWC group also not reaching statistical significance (p = 0.077). Further outcome variables, such as PMI, length of hospital and ICU stay, ventilation duration, extracorporeal membrane oxygenation (ECMO), dialysis, inotropic support, blood transfusion and total blood loss were also not statistically different. Long-term outcomes in terms of overall cumulative survival are presented in Figure 1. The overall 30-day, 1-, 3- and 6-year survival of the entire patient cohort was 93.7, 91.8, 90.4 and 89.1 %, respectively, with significantly better outcomes when operated electively (p < 0.001) but no differences between ICC and IWC both in elective (p = 0.857) and emergent (p = 0.741) subgroups.

Univariate regression analysis was executed (Tables 4 and 5), in order to show possible associations of early clinical outcome with determined variables. There were no associations found between each clinical endpoint and the application of IWC or ICC.

In order to detect independent preoperative predictors for 30-day mortality and PMI binary logistic regression analysis was performed (Table 6 and 7) using only preoperative variables. Multivariate analysis revealed that EF < 40 % was the strongest independent predictor for 30-day mortality (OR 3.66; 95 %-CI 1.79-7.52; p < 0.001), followed by atrial fibrillation, PAD and anti-platelet drugs not suspended at least 5 days before surgery (Table 6). In contrast, three independent predictor variables showed a protective influence on 30-day mortality, namely 3-vessel-disease (OR 0.36; 95 %-CI 0.16-083; p = 0.016), preoperative statin therapy and dyslipidemia. The strongest independent predictor for PMI appeared to be preoperative anti-platelet drug therapy (OR 4.79; 95 %-CI 3.10-7.40; p < 0.001), followed by IABP, hemofiltration, EF < 40 %, atrial fibrillation and cerebrovascular disease (Table 7). Preoperative statin therapy tended to be a borderline predictor with a protective influence on PMI (OR 0.66; 95 %-CI 0.41-1.08; p = 0.101).

As several clinical studies have shown superior outcomes when using blood cardioplegia, this type of myocardial protection has been increasingly implemented in most centers including our department [6, 13]. So far, most prior research has been particularly focused on cold and warm blood cardioplegia in elective CABG patients [14, 15]. Also the differences between crystalloid and cold blood cardioplegia have been largely debated in previous research [16, 17]. In order to fill the gap in terms of analysis of differences in cold and warm blood cardioplegia in emergent setting, we conducted our study with particular attention to emergent CABG patients analysing the impact of different intermittent blood cardioplegia application. Previous research has indicated that there were no significant differences between antegrade and retrograde application of blood cardioplegia in terms of mortality and myocardial infarction [14, 18]. Due to easier technical aspects it has become the standard of care to administer antegrade blood cardioplegia for CABG procedures in our institution. In this study we analyzed different cardioplegia strategies in emergent compared to elective CABG patients. The intraoperative patient data showed similar results referring to CPB, operation, and reperfusion time, usage of IMA and the need for hemodialysis. However, it is interesting to note that even though the aortic cross clamp time was significantly longer in the IWC group there were no differences in PMI. In a recent study it was even suggested that cold blood cardioplegia seems to be associated with more harmful effects on the myocardium in CABG patients when compared to warm blood cardioplegia [19]. In contrast, another study by Liakopoulos et al. demonstrated that cold blood cardioplegia according to Buckberg provided superior myocardial protection in terms of 30-day mortality, cardiac death and PMI in patients requiring prolonged aortic cross clamp time during cardiac surgery [9]. However, it is very doubtful as to whether a meaningful comparison can be made between CABG and non-CABG surgery procedures precisely because severe coronary stenosis may impair cardioplegic delivery leading to a different delivery of each solution beyond the stenosis.

Another study with prospective randomized design which was published two decades ago showed strong evidence that warm blood cardioplegia was superior to cold blood cardioplegia in CABG patients in terms of PMI [20]. As it was a randomized study, there were several exclusion criteria, such as patients with renal failure, or emergent patients who were not able to sign informed consent. In order to present a real world experience, we did not intend to exclude any cases, analyzing consecutive patients including those requiring preoperative mechanical ventilation or patients with renal failure. Moreover, an emergent subgroup was created and matched with consecutive patients from the elective subgroup in order to provide the full analysis in patients with different risk profiles. Additionally, compared to the study by Warm Heart Investigators where cardioplegia was given antegradely and/or retrogradely depending on surgeon’s preference this potential bias is not present in our study as cardioplegia was always administered antegradely [20]. Similar to our report, another study by Calafiore et al. investigated 500 consecutive CABG patients who received IWC compared to ICC [5]. However, the blood cardioplegia in that study was given antegradely in all cases, the main difference to our study is that Calafiore et al. only included elective CABG patients. Interestingly, Calafiore et al. found that the outcome in the IWC group was superior to the ICC group in terms of requirement for circulatory assistance, IABP, and incidence of myocardial infarction and cerebrovascular accidents. In another prospective randomized trial Franke et al. also showed a significantly improved myocardial protection in the IWC group compared to ICC group in elective setting [15]. Surprisingly, there is only one experimental animal study which showed that IWC is superior to ICC in ischemic myocardium [21]. Despite the fact that the concept of myocardial protection in the beginning of cardiac surgery was recommended with introduction of hypothermic crystalloid cardioplegia it has been continuously adjusted and improved by pharmacological additives, blood cardioplegia and different application techniques [22]. Despite the fact that warm and cold cardioplegia resulted in similar 30-days and long-term mortality in our study, there has been a substantial amount of research showing that warm cardioplegia reduces several adverse post-operative events [7, 23]. However, totally different results were found in a meta-analysis with a total of 41 randomized controlled trials including 5879 patients comparing warm vs. cold cardioplegia. This study demonstrated no statistically significant differences in the incidences of clinical events [24]. Hence, our results seem to support this theory that there are no statistically significant differences in using cold vs. warm blood cardioplegia in emergent CABG patients particularly those with aortic cross clamp time less than 60 min according to the mean cross clamp time results of our study. Additionally, we performed a multivariate analysis which further showed that the type cardioplegia is not an independent predictor for PMI or 30-day mortality independent of the procedure urgency.

In terms of our additional findings suggesting preoperative risk factors for PMI the strongest independent predictor appeared to be preoperative use of anti-platelet drugs also supported by Micelli et al. demonstrated previously [25]. Our further findings on predictors of early mortality, such as decreased EF of less than 40 %, AF and PAD are also consistent with previous research [26, 27]. Whereas van Straten et al. found evidence that PAD is associated with an increased risk for long-term mortality, our findings suggested that PAD is also an independent predictor for short-term mortality [28]. Finally, our data support that preoperative statin treatment may have protective effects on mortality similarly to recent studies by Kulik et al. and Girerd et al. [29, 30] and prevents cardiovascular complications by pleiotropic effects [31]. Nevertheless, optimal mortality prediction should still be performed using established scoring systems [32, 33]. Our study is also in consistence with the fact that statins may reduce cytokine release and neutrophil adhesion via a nitric oxide-mediated mechanism and improve postoperative myocardial perfusion of bypassed areas [34, 35].

Summarizing, there are no clinically significant differences in using cold and warm blood cardioplegia in emergent CABG patients including long-term outcomes regardless of the urgency status. Decreased EF, AF and PAD remain main predictors for 30-day mortalitiy whereas preoperative use of statins is associated with protective effects. Warm blood cardioplegia and normothermic systemic perfusion offer safe myocardial protection strategies in emergent CABG patients and IWC is a cost-effective alternative. Therefore, we suggest to use warm blood cardioplegia antegradely in elective and emergent CABG procedures regardless of the emergent status.