Introduction
The elderly population continues to increase in Europe and United States (US), especially age greater than 75 years. This group is expected to grow considerably over the next 20 years. In Europe, the population over 75 years is expected to reach 65 million by 2040, an approximately 49% increase compared to 2020 [
1]. By 2040 in the United States, the population over age 75 is expected to rise from about 23 million today, to more than 43 million, a projected increase of about 90% [
2,
3]. Because aortic valve stenosis (AS) and coronary artery disease (CAD) are the most commonly represented cardiac lesions in the elderly, as the elderly population increases a concomitant rise in AS and CAD is anticipated. Advanced age is associated with considerable number of comorbidities and medical frailty, exposing the elderly patient to potentially considerable operative risk. Moreover, simultaneous surgical aortic valve replacement (SAVR) and coronary artery bypass grafting (CABG) carries a higher procedural risk compared with isolated SAVR (i-SAVR). Indeed, even if AS could be addressed with transcatheter aortic valve implantation (TAVI) even in patients older than 75 years with intermediate or low risk [
4], the combination of TAVI and percutaneous coronary intervention (PCI) is not a widely accepted practice, especially for those patients with a recognized heavily calcified CAD. Several studies [
5‐
10] have reported relevant early results in patients who underwent either i-SAVR or SAVR combined with CABG. Other authors [
11‐
16] have reported unfavorable early outcome in those patients who underwent simultaneous SAVR and CABG. The results are still debated regarding long-term outcomes, as some studies have reported acceptable and comparable long-term outcomes [
17,
18], whereas other authors have reported conflicting results, with some studies showing better long-term survival in i-SAVR patients [
19] and others reporting better long-term outcomes in SAVR plus CABG patients [
20,
21]. No randomized control trials are available and, to the best of our knowledge, no meta-analyses have addressed the impact of concomitant CABG and SAVR in elderly patients. To address this limitation, a systematic review and meta-analysis was conducted with the best available evidence, evaluating the impact on early-term and long-term outcomes of CABG combined with SAVR, compared to i-SAVR in patients greater than 75 years of age.
Materials and methods
Systematic review of the literature, search strategy and eligibility criteria
A comprehensive review of previous relevant studies which were published from 1 January 2000 to 30 November 2021 was conducted. The search was conducted using the electronic databases PubMed and EMBASE. Search terms used alone or in combination included “elderly patients,” “very elderly,” “octogenarians,” “surgical aortic valve replacement,” “coronary artery bypass grafting,” “early-term results,” “75 years old” and “80 years old.” Furthermore, the references list of the obtained articles was used to implement the search.
The literature search and review were based on the PICOS format (Population; Intervention; Comparison; Outcomes; Studies); Population: patients with isolated aortic valve disease or combined with coronary artery disease; Intervention: i-SAVR; Comparison: SAVR plus CABG; Outcomes: early and long-term outcomes; Studies: randomized trials, retrospective and prospective observational studies.
Selection of relevant studies was conducted according to the following inclusion criteria: (1) patients who underwent either i-SAVR or SAVR in addition to CABG; (2) patients older than 75 years; (3) early mortality comparing the two surgical interventions; (4) long-term survival comparing the two operations; (5) studies included any of the following postoperative complications: atrial fibrillation (POAF), acute renal failure, need for dialysis, pneumonia, prolonged mechanical ventilation (PMV), stroke, re-thoracotomy for bleeding/tamponade, need for postoperative intra-aortic balloon pump (IABP), length of stay and early mortality. Studies including in the analysis other associated cardiac procedure were excluded. Moreover, studies which were published in languages other than English were excluded, as were commentaries, letters, case reports, systematic reviews and meta-analyses.
This systematic review and meta-analysis were conducted according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [
22] and was based on the following steps: (1) identification of titles and abstracts of records through database search; (2) removal of duplicates; (3) screening and selection of abstracts; (4) evaluation of study eligibility through full-text articles; and (5) final inclusion in study. Studies were selected by two independent authors (SDA, DT). When there was disagreement, a third senior author (FF) reviewer made the decision of whether to include or exclude the study.
The study protocol of the systematic review and meta-analysis was registered and published online in PROSPERO (The International Prospective Register of Systematic Reviews; ID: CRD42021276831).
Data extraction and database
Two reviewers (SDA and DT) independently performed data extraction which were reported in a standard table sheet database (Microsoft Office Excel 2016, Microsoft, Redmond, WA, USA). Median and interquartile ranges were converted into mean and standard deviations following the recommendations of Luo et al. [
23]. All studies included in the meta-analysis were identified by first author, country, study design, study period, and year of publication. The following patient factors were collected: age, gender (male), POAF, postoperative acute renal failure, need for dialysis, postoperative pneumonia, PMV, postoperative stroke, re-thoracotomy for bleeding/tamponade, postoperative IABP, postoperative length of stay.
Endpoints
The primary endpoints of the meta-analysis were the (i) early mortality, defined as death occurred within 30 days or during the index admission and (ii) the overall long-term survival. The secondary endpoints were the following postoperative complications: new onset of POAF, renal failure, need for dialysis, pneumonia, PMV (> 48 h), any stroke, re-thoracotomy for bleeding, need for IABP and length of stay.
Statistical analysis
The pooled effect size with odd ratio (OR) and 95% Confidence Interval (CI) using the Mantzel–Haenszel method was calculated for early mortality and for the secondary endpoints. The pooled hazard ratio (HR) with 95% CI using the Mantzel–Haenszel method was calculated for long-term survival. The random-effect model was preferred because the variability across the studies was taken into account in the model. HR and the corresponding 95% CI was calculated analysing time-to event outcomes according to the methods proposed by Tierney et al. [
24]. When available, the reported HRs of selected studies were compared with the estimated HRs.
Weighted mean differences were calculated for the continuous variable length of stay. Forest plots were created to represent the primary and secondary outcomes and to determine the effect size. Statistical heterogeneity was assessed with Chi-square test and
I2 test and defined as low for
I2 ranging from 0% to 25%, moderate for
I2 ranging from 26% to 50% and high for
I2 above 50% [
25]. Publication bias was assessed for each endpoint by generating the funnel plots using the trim and fill method and analysed by means of Egger’s test and Begg and Mazumdar’s test and estimated visually. Possible publication bias was suggested also by asymmetric funnel plot. Sensitivity analysis was applied to verify the influence of a single study on the primary endpoints, by sequentially removing one study, according to the leave-one-out method [
26].
Categorical variables were reported as number and percentages. Continuous variables were reported as mean and standard deviation. A two-tailed
p-value < 0.05 was considered to indicate statistical significance. All statistical analyses were completed with ProMeta3 software (
http://idostatistics.com/prometa3/), and with the Review Manager (RevMan5) Version 5.3 (The Cochrane Collaboration, 2012, The Nordic Cochrane Centre and Copenhagen, Denmark).
Discussion
AS is the most frequently identified lesion in the elderly patients, with incidence increasing with age, exceeding 5% in patients over 80 years [
54,
55]. Previous studies reported that almost half of the elderly patients undergoing SAVR were more likely to require CABG, compared to the non-elderly requiring SAVR [
56‐
58].
By this comprehensive systematic review and meta-analysis, we aimed to analyze the impact of CABG in the aged population requiring SAVR, and to the best of our knowledge this is the first meta-analysis focusing on this topic. The main findings where that (i) CABG in combination with SAVR is associated with higher early mortality compare to i-SAVR, (ii) the long-term survival is comparable between the two surgical operations and (iii) CABG plus SAVR is associated with a higher rate of postoperative complications such as acute renal failure, need for dialysis, and PMV. Interestingly, the rate of new onset POAF, IABP usage, postoperative stroke, re-thoracotomy for bleeding/tamponade, postoperative pneumonia and length of hospital stay were similar in both groups.
CAD has an unfavorable prognostic factor, accentuated even further in presence of left main stenosis greater than 50%. Such patients have an increased risk of developing myocardial injury likely secondary to an imbalance between myocardial oxygen supply and demand during cardiac surgery. Previous studies demonstrated that cardiac troponin (c-Tn) levels measured after cardiac surgery predict early mortality [
59]. C-Tn levels and mortality increase with increasing complexity of cardiac surgery, such that the median c-Tn level rises progressively in patients undergoing isolated CABG with a single graft compared with 2 or more grafts [
60].
Increased duration of cardiopulmonary bypass (CPB) and aortic cross clamping (X-Clamp) times in the elderly remain a concern. Longer CPB time is associated with increased incidence of cerebral, renal and coagulopathy, and greater X-Clamp time induces increased risk of myocardial damage, due to the lower efficiency of the physiological pathways of homeostasis. Furthermore, patients with severe CAD are more frequently affected by peripheral artery disease, which can increase the risk of postoperative ischemic complications with unfavorable outcomes, especially in elderly patients. A heart team approach including surgeons, cardiologists, anesthesiologists, internist and physiotherapists can be helpful to assess these elderly candidates and choose the best approach to treat AS [
4]. For high-risk candidates, minimally invasive treatment options are desirable. Over the last decade, transcatheter aortic valve implantation (TAVI) has been identified as the standard of care for high-surgical risk patients, or for those considered inoperable by cardiac surgeons. The switch from SAVR to TAVI for elderly patients during recent years has led to a significant decrease of early mortality following AVR [
61]. TAVI has demonstrated the potential to decrease the morbidity associated with standard SAVR owing to the avoidance of a median sternotomy, cardiopulmonary bypass and cardioplegic arrest.
Data from the recent randomized SURTAVI trial, comparing TAVI with PCI versus SAVR plus CABG in 332 patients, reported a 30-day mortality of 4.1% vs 3.7%, respectively, an incidence of stroke of 3.6% vs 4.3% and advanced acute kidney injury of 1.8% vs 3.7% [
62]. The study excluded patients with SYNTAX score > 22, however, therefore it is not possible to extrapolate the outcomes from patients with more advanced CAD. Noteworthily the current guidelines for CAD recommend CABG for a high SYNTAX score and these patients could benefit from SAVR with CABG [
63].
The German Aortic Valve Registry, an all-comers registry including 85 German centers, recently showed that the rate of in-hospital mortality for 26,618 patients undergoing isolated SAVR was 1.7%. The 30-day mortality in the 16,158 patients who underwent SAVR and CABG was significantly higher at 3.3%. In the SAVR plus CABG cohort stratified according to STS score risk, in 4044 patients in the intermediate category (STS score 4–8%), the in-hospital rate of mortality was 5.4%, the rate of disabling stroke was 2.4%, and need for new pacemaker or implantable cardioverter-defibrillator was 4.6% [
64].
No unfavorable impact of CABG in combination with SAVR on long-term mortality compared with i-SAVR was reported in this updated systematic review and meta-analysis. The comparable long-term survival between the two treatments may support the rationale that CAD, although a recognized additional risk factor, when associated with aortic valve disease, probably does not result in increased long-term mortality when addressed with CABG. Among the 23 studies that reported follow-up data, there was a high range of mean follow-up times, varying from 2.1 to 6.5 years. Interestingly, when we narrowed the analysis to those studies that reported a maximum follow-up time of 10 years or more, again no differences were reported between the two treatments. Some authors have observed a long-term benefit of patients with concomitant CAD and AS undergoing CABG plus SAVR compared with patients who did not receive the CABG procedure at the time of SAVR [
65]. The relief of AS, along with the addition of coronary revascularization, would increase coronary flow reserve and provide reversal remodeling as in patients with isolated AS who underwent i-SAVR. These factors would promote regression of left ventricular hypertrophy and increased coronary microcirculation, which are critical determinants of long-term survival [
66].
In the meta-analysis, it is interesting to emphasize the validity and safety of the conventional surgical approach in elderly patients. Once the patient has gone through the postoperative period, where the CBAG + SAVR combination is associated with higher hospital mortality, long-term survival remains comparable between the two treatments. This finding has its clinical relevance and allows confirmation of the validity and safety of the conventional surgical approach, as well as that the associated CBAG has no negative clinical impact in the long term.
The incidence of new onset POAF increases with advancing age and the multifactorial pathophysiology has not been completely elucidated [
67]. In this meta-analysis, no significant difference in postoperative AF incidence was identified between the two populations. One possible explanation for these data could be the higher incidence of POAF in elderly patients, regardless of the type of cardiac surgical procedure to which they undergo. In addition, severe aortic valve stenosis is a chronic disease that can lead to remodeling of the left ventricle with a decrease in diastolic compliance leading to increased left atrial volume and altered atrial function. Although CAD increases the risk of developing POAF [
67], in this study, CABG was not associated with the development of POAF.
As age is an established risk factor for atherosclerotic disease, so there is an increased risk of aortic calcifications is expected in elderly patients [
68]. Postoperative acute renal failure and dialysis appear to be lower in i-SAVR compared to SAVR plus CABG. A possible explanation is the increased rate of diabetes, hypertension, vascular disease, preoperative renal failure which are more represented in patients with CAD and longer CPB time in patients who underwent SAVR + CABG compared to i-SAVR [
69‐
71]. CABG added to SAVR shows a nonsignificant trend toward a greater need for postoperative IABP compared to i-SAVR. Longer CPB and aortic X-clamp times, prolonged operative time, and peripheral vascular disease are predictive for postoperative IABP [
72,
73]. These factors may explain why patients who underwent CABG in combination with SAVR had a higher incidence of postoperative IABP implantation. The meta-analysis shows that PMV was significantly associated with the SAVR + CABG surgical operation. Longer CPB time is reported to be an independent predictor of postoperative respiratory failure [
74] and PMV (> 24 h) [
75]. Since SAVR + CABG operation has a CPB time longer than i-SAVR, we can argue that this factor might be determinant in increasing the incidence of postoperative PMV in patients who received CABG added to SAVR. From the 17 studies that reported incidence of postoperative stroke, no significant differences emerged in patients undergoing i-SAVR compared to SAVR plus CABG. A plausible explanation for this finding is the pathophysiology of ischemic stroke post cardiac surgery. In patients undergoing aortic valve surgery, thromboembolism is likely attributable to aortic clamping and manipulation, as well as aortic valve decalcification, rather than to the duration of surgery [
76,
77]. As cardiopulmonary bypass is required for both i-SAVR and CABG plus SAVR, similar thromboembolism rates would expect, since that both operations share the aortic manipulation.
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