About the Authors:
Javier Mariani
* E-mail: [email protected]
Affiliations Cardiology Department, Hospital El Cruce “Néstor Carlos Kirchner”, Av. Calchaquí 5401 (B1888AAE), Florencio Varela, Buenos Aires, Argentina, Fundación GESICA, Av. Rivadavia 2358 (C1034ACP), Ciudad Autónoma de Buenos Aires, Argentina
Alejandro Macchia
Affiliation: Fundación GESICA, Av. Rivadavia 2358 (C1034ACP), Ciudad Autónoma de Buenos Aires, Argentina
Maximiliano De Abreu
Affiliation: Cardiology Department, Hospital El Cruce “Néstor Carlos Kirchner”, Av. Calchaquí 5401 (B1888AAE), Florencio Varela, Buenos Aires, Argentina
Gabriel Gonzalez Villa Monte
Affiliation: Cardiology Department, Hospital El Cruce “Néstor Carlos Kirchner”, Av. Calchaquí 5401 (B1888AAE), Florencio Varela, Buenos Aires, Argentina
Carlos Tajer
Affiliation: Cardiology Department, Hospital El Cruce “Néstor Carlos Kirchner”, Av. Calchaquí 5401 (B1888AAE), Florencio Varela, Buenos Aires, Argentina
Introduction
Current clinical practice guidelines recommend an invasive approach for patients with intermediate and high-risk features presenting with non-ST elevation acute coronary syndromes (NSTE-ACS) [1,2]. Since approximately 40–60% of NSTE-ACS patients who undergo coronary angiography, have multivessel coronary artery disease, treating physicians often face the decision of choosing the best revascularization strategy [3,4]. In cases where anatomy is suitable for percutaneous coronary intervention (PCI), and there is no clear indication of surgical revascularization, the decision usually stands between multivessel PCI (MV PCI) and culprit-vessel PCI (CV PCI). In such situations, AHA/ACC guidelines recommend that “a strategy of multivessel PCI, in contrast to culprit lesion–only PCI, may be reasonable in patients undergoing coronary revascularization as part of treatment for NSTE-ACS” [2].
Complete revascularization has the potential to improve outcomes by reducing recurrent events, particularly urgent revascularization procedures [5]. Nevertheless, these benefits could be offset by an increase in the risk of periprocedural myocardial infarction (MI), stent thrombosis, bleeding and contrast-induced nephropathy associated with MV PCI [6–8]. Furthermore, it has been suggested that MV PCI has lower procedure success rates than CV PCI [9].
In this study, the aim was to assess the evidence that compares MV PCI versus CV PCI among patients with NSTE-ACS with multivessel coronary artery disease through a systematic review and meta-analysis.
Materials and Methods
The study protocol is registered in the international prospective register of systematic reviews (PROSPERO), number CRD42014015531 (available at http://www.crd.york.ac.uk/PROSPERO/display_record.asp?ID=CRD42014015531).
Eligibility criteria
Studies were eligible if compared a revascularization strategy based on CV PCI (or one vessel only) versus MV PCI, among NSTE-ACS (MI or unstable angina) patients with multivessel coronary artery disease and with available outcome data for the analyses.
Only published articles were considered and there were no restrictions regarding design or language. Studies were included only if separated data was available for patients matching our target population.
Studies reporting data on patients with ST elevation MI and/or patients with cardiogenic shock, and those that compared PCI versus coronary artery bypass grafting (CABG) were excluded.
Search strategy
We searched in MEDLINE (via PubMed, with no date restrictions), EMBASE (from 1980 to present) and PsycINFO (from 1987 to present). The terms used for electronic search were: [coronary angioplasty OR percutaneous coronary intervention OR pci OR revascularization] AND [(unstable angina) OR (myocardial infarction AND non st elevation) OR (non st elevation AND acute coronary syndrome)] AND [multivessel].
As recommended, reference lists of relevant studies and other published reviews on this issue were handsearched for potential studies [10].
Data extraction
Two of the authors (J.M. and A.M.) assessed independently the articles retrieved by the search in an unblinded fashion. Eligibility was initially evaluated through revision of titles and abstracts and, when inclusion criteria were met or there were no clear exclusion criteria present, full texts were retrieved for further evaluation.
Since all studies were observational, to record data MOOSE guidelines were followed [10]. The extracted data from each study report included authors, year of publication, design, statistical methods for confounding control, loss in follow-up, follow-up duration, total number of patients registered, number of patients finally included in the analyses, cardiovascular risk factors, angiographic data, use of drug eluting stents (DES), outcome event data and adjusted estimates of effects. Data were collected in an ad-hoc case report form and then entered in a dedicated database.
All discrepancies were solved by consensus with the participation of a third author (C.T.).
For quality evaluation, it was computed the Newcastle-Ottawa Scale (NOS) as the sum of stars of each study [11]. The scale assigned a maximum of nine points, with more points indicating better quality. As recommended elsewhere, assessment of quality included the NOS but was not limited to it [10,12].
Outcomes
The outcomes of interest were all cause mortality, death or MI, revascularization and the combined incidence of death, MI or revascularization. In all cases, definitions of events were maintained as reported in the original articles with no attempt to re-classify events.
Statistics
The main analyses were conducted using the adjusted estimators of effects for each study (i.e. measures of effect obtained after controlling for confounders), and these were pooled with a random effects model using the generic inverse variance method, as described by DerSimonian and Laird [10,13]. To evaluate the influence of confounders on estimates of effects, we also conducted exploratory analyses using the raw data (i.e. number with events and number of patients in each study group). Individual and pooled adjusted estimates of effect were reported as hazard ratios (HR) with the corresponding 95% confidence intervals (95% CI); there were, however, four studies that reported the adjusted estimates as odds ratios (OR). In these cases, the ORs were converted to relative risks, as suggested elsewhere, and pooled in this way in a sensitivity analysis [9,14–17].
Heterogeneity was evaluated through the I2 statistic, which represents the percentage of variation between estimates of effects that cannot be explained by the play of chance; a value >50% was considered an indicator of moderate inconsistency and a value >75% as substantial inconsistency [18]. Possible sources of heterogeneity were explored in subgroup analyses that were defined by study designs, duration of follow-up, percentage of DES utilization and quality of the study determined by the NOS.
Publication bias was evaluated by the visual exploration of funnel plot, and formally through the Egger’s test, with p<0.1 considered as an indicator of a statistically significant asymmetry of the funnel plot [19].
All analyses were conducted using the R software and the meta package (the R Foundation for Statistical Computing, Vienna, Austria) [20].
Results
Included studies
The initial search identified 674 articles, 219 of which were duplicates. After revision of the remaining titles and abstracts, 16 full texts were retrieved for further evaluation (Fig 1). One was excluded because there was no control group for comparison and three reported ACS patients jointly with stable chronic angina patients [21–24]. In all, 12 studies were included with reported data of 117,685 patients (38,477 received MV PCI and 79,208 received CV PCI) (Table 1).
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Fig 1. Flow chat of studies.
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Table 1. Characteristics of included studies.
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Three studies (n = 4,456) were analyses post-hoc of randomized controlled trials [25–27], the remaining were retrospective analyses from observational registries (n = 113,229) [5,9,14–16,28–31]; there were no case control studies. Median count of stars from NOS was 6 (range 5 to 8). The observational registries involved one or more institutions from one country, whereas randomized controlled trials were international.
Two studies (n = 107,786) reported only in-hospital outcomes [9,14], for the remaining the median follow-up was 12 (range 6 to 36) months. Patients that met inclusion criteria and were analyzed represented from 4% to 75% of patients included in the original registries (Table 2). Only five studies reported the number of loss during follow-up [9,15,28,30,31].
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Table 2. Characteristics of patients and follow-up.
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Table 2 also shows patients characteristics. Median age was 64.1 years, most patients were male, the median prevalence of smokers was 30.8%, diabetes mellitus was present in 29.3% of patients, and previous history of MI in 36.9%. Eight studies excluded patients with prior CABG [5,9,14–16,29–31].
There was a small excess of three-vessel disease among MV PCI, and lower prevalence of total chronic occlusions and complex lesions (B2 or C as defined by AHA/ACC classification). Mean left ventricular ejection fraction was normal and similar between groups across six studies that reported it [5,9,25,26,28,29], and it was also preserved in most patients when the threshold value was described in the study [14–16,27,31].
Outcomes
The analyses of adjusted estimators suggest that there were no significant differences in mortality risk (HR 0.79; 95% CI 0.58 to 1.09; I2 67.9%), with moderate inconsistency (Fig 2). Also, there were no significant differences in the risk of death or MI (HR 0.90; 95% CI 0.69 to 1.17; I2 62.3%), revascularization (HR 0.76; 95% CI 0.55 to 1.05; I2 49.9%) or the combined outcome of death, MI or revascularization (HR 0.83; 95% CI 0.66 to 1.03; I2 70.8%). All analyses exhibited a moderate degree of inconsistency (Fig 3).
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Fig 2. Effects of MV PCI versus CV PCI on mortality.
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Fig 3. Effects of MV PCI versus CV PCI on secondary outcomes.
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In unadjusted analyses, MV PCI was associated with a statistically significant reduction in the risk of death (RR 0.90; 95% CI 0.82 to 0.99), without heterogeneity across studies (I2 0.0%). There were no statistically significant differences between revascularization strategies in the incidence of death or MI (RR 1.06; 95% CI 0.93 to 1.20; I2 1.9%), revascularization (RR 0.81; 95% CI 0.63 to 1.05; I2 68.0%) or the combined outcome of death, MI or revascularization (RR 0.88; 95% CI 0.77 to 1.02; I2 56.8%) (Fig 4).
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Fig 4. Unadjusted analyses of MV PCI versus CV PCI.
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Subgroup analyses
To explore potential sources of heterogeneity, subgroup analyses according to NOS, study designs, patient characteristics and utilization of DES were conducted (Figs 5–9). Analyzing separately the studies by their design (RCT post-hoc analysis versus Observational registries) the inconsistency of the analyses were reduced in terms of death or MI, revascularization and death, MI or revascularization (Fig 10); however, there was no variable that explained inconsistency across estimators of effect on mortality.
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Fig 5. Subgroup analyses by quality of study report assessed by Newcastle-Ottawa Scale.
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Fig 6. Subgroup analyses by follow-up.
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Fig 7. Subgroup analyses by DES use.
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Fig 8. Subgroup analyses by diabetes prevalence.
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Fig 9. Subgroup analyses by chronic occlusions prevalence.
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Fig 10. Subgroup analyses by studies design.
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Sensitivity analysis
Results were almost identical after correction of effect estimators presented as OR (Fig 11). After exclusion of studies that reported only in-hospital outcomes, mortality analysis suggested a benefit from MV PCI with a lower level of inconsistency (Fig 12).
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Fig 11. Sensitivity analyses with odds ratios transformation to risk ratios.
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Fig 12. Sensitivity analyses excluding studies with follow-up limited to initial hospitalization.
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Publication bias
Visual inspection of funnel plot suggested asymmetry among studies that had reported adjusted estimates of effect (Fig 13A), and the formal evaluation indicated the presence of publication bias (p = 0.097). Fig 13B shows funnel plot constructed with unadjusted effect estimates with no evidence of publication bias (p = 0.868); differences between both plots suggested differential reporting of adjusted analyses.
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Fig 13. Funnel plots of adjusted (13A) and unadjusted (13B) estimates.
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Discussion
The results of present meta-analysis, based on observational studies that compared MV PCI versus CV PCI among NSTE-ACS patients with multivessel disease, suggested that there were no significant differences between both revascularization strategies.
Current clinical practice guidelines for the management of NSTE-ACS indicate that MV PCI could be reasonable in patients undergoing coronary revascularization as part of the treatment strategy [2]. This recommendation is based on reports of studies suggesting that MV PCI is a safe intervention and that it reduces the need for revascularization procedures during follow up [6, 9, 16, 25, 31]. However, this meta-analysis does not confirm the reduction of future revascularization procedures during follow up. Furthermore, regarding safety data of MV PCI, is important to notice that, although in overall results showed no significant differences between both strategies in mortality, MI or revascularization risks, these results are heterogeneous and part of the heterogeneity is controlled with stratified analyses by study design, such that most rigorous data (those from post-hoc analyses of RCT) suggest an increase of death, MI or MACE risks with MV PCI. Hence, according these results, CV PCI should be the revascularization strategy preferred for most NSTE-ACS patients with multivessel disease undergoing PCI, excepting possibly those without a clearly identifiable culprit-vessel in whom a more extensive revascularization could be a better strategy.
Systematic monitoring for periprocedural MI might explain the results heterogeneity between observational registries and post-hoc analyses of RCT. Higher risk of MI after MV PCI has been related to distal embolization, side branch closure and stent thrombosis, which could be heightened after multiple stent deployment in a pro-inflammatory and pro-thrombotic environment [6,32].
The analyses have several limitations that should be considered at interpreting the results. First, this is a meta-analysis of observational studies and, although adjusted estimators of effect were used to minimize biases, some degree of residual confounding is possible [10]. In all studies, treatment groups were defined after PCI, such that patients in whom originally planned strategy was MV PCI, but received only one-vessel PCI because technical or anatomic factors were classified as CV PCI, which could bias results against CV PCI. Furthermore, most studies derived from analyses from larger datasets, leaving the possibility of selection bias. Finally, there is evidence of publication bias, with smaller studies suggesting more benefits for MV PCI.
In conclusion, the results of this meta-analysis suggests that routine MV PCI in NSTE-ACS patients with multivessel disease is not superior to CV PCI and, that there is evidence that it could be not equally as safe. Since, there is a high prevalence of multivessel disease among NSTE-ACS patients and the available evidence has multiple limitations, randomized controlled trials evaluating safety and effectiveness of MV PCI in this setting are needed.
Supporting Information
[Figure omitted. See PDF.]
S1 Data. Database for the mortality (main) analyses.
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(CSV)
S1 MOOSE Checklist. MOOSE Checklist.
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(DOCX)
Author Contributions
Conceived and designed the experiments: JM AM. Performed the experiments: JM. Analyzed the data: JM. Contributed reagents/materials/analysis tools: JM AM MDA GGVM CT. Wrote the paper: JM AM MDA GGVM CT.
Citation: Mariani J, Macchia A, De Abreu M, Gonzalez Villa Monte G, Tajer C (2016) Multivessel versus Single Vessel Angioplasty in Non-ST Elevation Acute Coronary Syndromes: A Systematic Review and Metaanalysis. PLoS ONE 11(2): e0148756. https://doi.org/10.1371/journal.pone.0148756
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Abstract
Background
Multivessel disease is common in acute coronary syndrome patients. However, if multivessel percutaneous coronary intervention is superior to culprit-vessel angioplasty has not been systematically addressed.
Methods
A metaanalysis was conducted including studies that compared multivessel angioplasty with culprit-vessel angioplasty among non-ST elevation ACS patients. Since all studies were observational adjusted estimates of effects were used. Pooled estimates of effects were computed using the generic inverse of variance with a random effects model.
Results
Twelve studies were included (n = 117,685). Median age was 64.1 years, most patients were male, 29.3% were diabetic and 36,9% had previous myocardial infarction. Median follow-up was 12 months. There were no significant differences in mortality risk (HR 0.79; 95% CI 0.58 to 1.09; I2 67.9%), with moderate inconsistency. Also, there were no significant differences in the risk of death or MI (HR 0.90; 95% CI 0.69 to 1.17; I2 62.3%), revascularization (HR 0.76; 95% CI 0.55 to 1.05; I2 49.9%) or in the combined incidence of death, myocardial infarction or revascularization (HR 0.83; 95% CI 0.66 to 1.03; I2 70.8%). All analyses exhibited a moderate degree of inconsistency. Subgroup analyses by design reduced the inconsistency of the analyses on death or myocardial infarction, revascularization and death, myocardial infarction or revascularization. There was evidence of publication bias (Egger’s test p = 0.097).
Conclusion
Routine multivessel angioplasty in non-ST elevation acute coronary syndrome patients with multivessel disease was not superior to culprit-vessel angioplasty. Randomized controlled trials comparing safety and effectiveness of both strategies in this setting are needed.
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