Introduction

Although several limitations have been overcome through recent advances in dedicated techniques, devices, and percutaneous coronary intervention (PCI) experience [1], chronic total occlusion (CTO)-PCI still has lower success and higher complication rates compared with non-CTO-PCI [2, 3]. Therefore, PCI for CTO lesions should be considered only when the potential benefits outweigh the risk.

For non-CTO lesions, improvements in ischemia and angina from revascularization could be much greater for high-risk patients with moderate-to-severe ischemia [4]. Similarly, identification of high-risk patients for CTO revascularization might be crucial for achieving clinical benefits after CTO-PCI.

In clinical practice, many physicians hesitate to perform PCI for CTO lesions in high-risk patients with reduced left ventricular systolic function (RLVSF) because of safety concerns and uncertain benefits. There are few data regarding outcome differences after CTO revascularization based on LVSF. Therefore, the differential prognostic effects of CTO revascularization on long-term survival in preserved LVSF (PLVSF) versus RLVSF patients were investigated in this study.

Methods

Study population

A total of 2736 patients diagnosed with CTO at Korea University Anam Hospital, Sejong General Hospital, and Samsung Medical Center between March 2008 and December 2014 were reviewed. The inclusion criteria were CTO lesions detected on diagnostic coronary angiography and symptomatic angina or positive functional ischemia. Exclusion criteria were prior coronary artery bypass graft surgery or unavailable initial echocardiographic data. Patients were classified into either the PLVSF or RLVSF group based on left ventricular ejection fraction (LVEF) above (PLVSF) or below (RLVSF) 50% [5]. In each group, patients were subdivided based on treatment: successful CTO revascularization (SCR) or optimal medical therapy (OMT). The study scheme is summarized in Fig. 1. Patients received antiplatelet therapy with aspirin, and patients who underwent previous PCI or had acute coronary syndrome at diagnosis took an additional P2Y12 inhibitor for at least six months. Duration of dual antiplatelet therapy duration was determined by the attending physician. Patients received anti-anginal and heart-failure medication when appropriate. Patients were treated with statins unless contraindicated or not tolerated.

Fig. 1
figure 1

Flowchart of CTO patient stratification according to LVSF from a multicenter registry. CABG coronary artery bypass graft; CTO chronic total occlusion; IPTW inverse probability of treatment weighting; LVSF left ventricular systolic function; MI myocardial infarction; OM optimal medical therapy; PLVSF preserved left ventricular systolic function; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Study endpoints and definitions

The primary endpoint was a composite of all-cause death or non-fatal myocardial infarction (MI). The secondary endpoints included all-cause death, cardiac death, non-cardiac death, and MI, which were defined according to the Academic Research Consortium (ARC)-2 classification [6]. CTO was defined as occlusion of the native coronary artery with Thrombolysis In Myocardial Infarction (TIMI) flow grade 0 for an estimated duration longer than three months [7]. Follow-up duration was defined as the interval from the first CTO diagnosis to the date of the last outpatient clinic visit or outcome of interest, whichever occurred first.

SCR was defined as final residual stenosis < 20% with TIMI flow grade 2 or 3 on the final fluoroscopic image after CTO revascularization. In patients treated with PCI, stenting or balloon angioplasty procedures were determined according to the operator’s discretion. Patients who experienced revascularization failure were included in the OMT group. Revascularization for non-CTO lesions was performed according to the physician’s discretion, while also following general PCI guidelines for coronary artery disease. LVEF was calculated from echocardiography using the biplane Simpson method.

Data collection and follow-up

Procedural and clinical outcome data were collected using a dedicated database from three medical-center registries. To ensure accurate assessment for clinical outcomes during the follow-up period, information was obtained from each hospital’s medical chart review or through telephone contact. Additional information was obtained from the National Population Registry of the Korean National Stationary Office with the use of a unique personal identification number. All outcomes of interest were adjudicated by board-certified cardiologists blinded to the study purpose. This study was approved by the Institutional Review Board of Korea University Anam Hospital (2019AN0041). The informed consent was waived. The study also complied with the Declaration of Helsinki.

Statistical analyses

Baseline patient demographics were analyzed using Student’s t test for continuous variables and the Chi square test or Fisher’s exact test for categorical variables as appropriate. Changes between baseline SYNTAX score and residual SYNTAX score in each SCR group in the PLVSF group and the RLVSF group were analyzed using the paired t test, respectively. Continuous variables are presented as mean ± standard deviations. Categorical variables are expressed as counts (percentages).

Propensity score was calculated from each subject using the logistic regression model including baseline covariates in the model. Age and the variables that were significantly different between the classified 2 groups were selected to calculate the propensity score. Inverse probability of treatment weighting (IPTW) were computed from the propensity score to control for confounding and selection bias and to adjust for significant differences in baseline characteristics between the SCR and OMT groups. Weights for patients receiving SCR were the inverse of the propensity score, and weights for patients receiving OMT were the inverse of (1-propensity score). An absolute standardized mean difference of < 10% for the measured covariate after IPTW adjustment indicated an appropriate balance between the two groups.

Event rates were estimated using Kaplan–Meier survival analysis, and hazard ratios (HR) with a 95% confidence interval (CI) were generated using Cox regression analysis. To determine the association between clinical characteristics and outcomes, multivariate Cox regression analyses were performed for the entire population. Cox regression models with tests for interaction were used to evaluate the consistency of treatment effects in subgroups. Survival differences between SCR and OMT in the PLVSF and RLVSF groups were compared with an interaction test using contrast weights [8]. A two-sided p value < 0.05 was considered statistically significant. All statistical analyses were performed using SAS 9.4 (SAS Institute Inc., Cary, NC, USA).

Results

Patients and lesion characteristics

Median follow-up duration of study population was 1138 days. Among a total of 2173 patients, 76.4% (n = 1661) had PLVSF (mean LVEF = 61%) and 23.6% (n = 512) had RLVSF (mean LVEF = 37%). Among the PLVSF patients, 1069 underwent SCR, and 592 were treated with OMT. Among the RLVSF patients, 272 underwent SCR, and 240 were treated with OMT (Fig. 1). OMT was usually the initial treatment of choice for CTO patients with RLVSF compared with PLVSF patients. When initial CTO-PCI failed, re-attempts were fewer in RLVSF patients than PLVSF patients. Consequently, OMT was more frequently selected as the final therapy option for CTO patients with RLVSF than with PLVSF (Fig. 2).

Fig. 2
figure 2

Distribution pattern differences in treatment assignment between patients with PLVSF and RLVSF. CTO chronic total occlusion; OMT optimal medical therapy; PCI percutaneous coronary intervention; PLVSF preserved left ventricular systolic function; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Baseline clinical and angiographic characteristics are summarized in Table 1. In patients with PLVSF, patients treated with SCR were younger (62.29 ± 11.18 vs. 64.07 ± 10.85 years, p = 0.0018), had a higher multi-vessel disease incidence (70.64% vs. 65.01%, p = 0.0186), and had a higher incidence of CTO lesions in the left anterior descending coronary artery (36.67% vs. 25.34%, p < 0.0001). Conversely, patients treated with OMT had lower SYNTAX scores (19.62 ± 8.61 vs. 17.34 ± 9.02, p < 0.0001) and histories of more frequent stroke, MI, and PCI. Patients treated with OMT tended to have higher J-CTO scores than SCR patients. The SYNTAX score decreased significantly after PCI in the SCR patients (Baseline 19.62 ± 8.61, Residual 6.23 ± 7.51, p < 0.001).

Table 1 Baseline clinical and angiographical characteristics of the study population

In patients with RLVSF, 18.1% had LVEF < 30%. Patients treated with SCR were younger (64.65 ± 11.43 vs. 68 ± 12.01 years, p = 0.0013) and had slightly higher LVEF and lower J-CTO scores than patients treated with OMT. Multivessel disease incidence was not different between patients treated with SCR and OMT. Similar to the PLVSF group patients, the SYNTAX score of SCR patients in the RLVSF group also decreased significantly after PCI (Baseline 23.38 ± 9.4, Residual 8.93 ± 9.14, p < 0.001).

Antiplatelet agents and statins were more frequently prescribed for patients treated with SCR, irrespective of LVSF, but prescription rates for beta blockers, calcium channel blockers, angiotensin converting enzyme inhibitors, and angiotensin II receptor blockers were similar between patients treated with SCR and OMT. The ratio of using either angiotensin converting enzyme inhibitors or angiotensin II receptor blockers was higher in the RLVSF group than in the PLVSF group. Different baseline demographics between patients treated with SCR and OMT in the PLVSF and RLVSF groups were adjusted for using IPTW for endpoint analysis (Online Resource 1).

Clinical outcomes between CTO patients with PLVSF and RLVSF according to treatment assignment

Clinical outcomes and IPTW-adjusted HRs for each endpoint are summarized in Table 2. In patients with PLVSF, the primary endpoint, composite all-cause death or non-fatal MI, occurred significantly less frequently in patients treated with SCR than with OMT (7.3% vs. 16.9%; HR 0.68; 95% CI 0.54–0.93; p = 0.0019; Fig. 3). The difference was mainly driven by a reduction in cardiac death (4.2% vs. 11.4%; HR 0.45; 95% CI 0.30–0.66; p < 0.0001), whereas incidences of MI and non-cardiac death were not different between patients treated with SCR and OMT (Fig. 4).

Table 2 IPTW-adjusted hazard ratios for clinical outcomes
Fig. 3
figure 3

Kaplan–Meier analysis of the cumulative incidence of primary endpoint according to treatment assignment in CTO patients with PLVSF and RLVSF. The panel represents the time-to-event Kaplan–Meier curves for the cumulative incidence of composite all-cause death or non-fatal MI in CTO patients with PLVSF and RLVSF, according to treatment assignment. Results were compared with an IPTW method to adjust for baseline covariates. CTO chronic total occlusion; HR hazard ratio; IPTW inverse probability of treatment weighting; MI myocardial infarction; OMT optimal medical therapy; PLVSF preserved left ventricular systolic function; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Fig. 4
figure 4

Kaplan–Meier analysis of the cumulative incidence of clinical outcomes according to treatment assignment in CTO patients with PLVSF and RLVSF. Panel a represents the time-to-event Kaplan–Meier curves for the cumulative incidence of all-cause death in CTO patients with PLVSF and RLVSF, according to treatment assignment. Panel b represents the cumulative incidence of non-fatal MI, according to treatment assignment. Panel c represents the cumulative incidence of cardiac death, according to treatment assignment. Panel d represents the cumulative incidence of non-cardiac death, according to treatment assignment. For all Panels (ad), results were compared with an IPTW method to adjust for baseline covariates. CTO chronic total occlusion; IPTW inverse probability of treatment weighting; MI myocardial infarction; OMT optimal medical therapy; PLVSF preserved left ventricular systolic function; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Similar to results for patients with PLVSF, patients with RLVSF had a significantly lower incidence of primary endpoint after treatment with SCR than with OMT (29.7% vs. 49.7%; HR 0.46; 95% CI 0.36–0.62; p < 0.0001; Fig. 3). The difference was mainly driven by a reduction in cardiac death (19.2% vs. 37.4%; HR 0.35; 95% CI 0.22–0.49; p < 0.0001); non-cardiac death and MI incidence was not different between the two groups (Fig. 4). Number needed to treat to save one life within 5 years was five in patients with RLVSF (95% CI, 0.48–0.86) and 10.5 in patients with PLVSF (95% CI, 0.54–0.92).

The survival benefit from SCR was greater for CTO patients with RLVSF than with PLVSF and increased significantly over time (p = 0.197, p = 0.048, and p = 0.036 at 1, 3, and 5 year, respectively; Fig. 5).

Fig. 5
figure 5

Difference in survival benefit of SCR between CTO patients with PLVSF and RLVSF. Cumulative incidence of all-cause death was compared according to treatment assignment, with an IPTW to adjust for baseline covariates. Survival probability differences with the use of a contrast test and NNT to save one life within 5 years were compared according to LVSF. The survival benefit from SCR between CTO patients with PLVSF and RLVSF was significantly different after three years and became more pronounced over time. CI confidence interval; CTO chronic total occlusion; HR hazard ratio; IPTW inverse probability of treatment weighting; LVSF left ventricular systolic function; NNT number needed to treat; OMT optimal medical therapy; PLVSF preserved left ventricular systolic function; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Interaction between treatment assignment and various subgroups

Although SCR was associated with a lower incidence of composite all-cause death or non-fatal MI than OMT, the interaction between the various subgroups and the beneficial effect of SCR over OMT was not significant, with the exception of the non-left anterior descending CTO subgroup (Fig. 6). The survival benefit of SCR was consistently observed in most subgroups.

Fig. 6
figure 6

Interaction between treatment assignment and various subgroups for primary endpoint. Shown are the results of a Cox proportion-hazards model that tested for an interaction between various subgroups and treatment assignment, with an IPTW to adjust for baseline covariates. CI confidence interval; CKD chronic kidney disease; CTO chronic total occlusion; DM diabetes mellitus; IPTW inverse probability of treatment weighting; LAD left anterior descending; OMT optimal medical therapy; RLVSF reduced left ventricular systolic function; SCR successful chronic total occlusion revascularization

Independent predictors of the primary endpoint for CTO patients

Online Resource 2 shows independent predictors of the primary endpoint based on IPTW-adjusted multivariable Cox regression analysis. In the overall study population, RLVSF (HR 3.285; 95% CI 2.753–3.919) and chronic kidney disease (HR 3.824; 95% CI 3.029–4.826) were strong independent risk factors for the primary endpoint, and SCR was an independent protective factor (HR 0.579; 95% CI 0.486–0.691) in both groups.

Clinical impact of CTO revascularization according to coronary anatomical features of CTO

Online Resource 3 shows the comparison of prognosis regarding primary endpoint according to the coronary anatomical location of CTO lesions of SCR patients in the PLVSF group and the RLVSF groups, respectively. As a result of the IPTW-corrected analysis, there was no difference in the prognosis according to the location of the coronary artery in the PLVSF group (panel a), but the prognosis of the left anterior descending CTO (HR 2.748; 95% CI 1.112–6.794; p = 0.0286) and the left circumflex CTO (HR 3.873; 95% CI 1.537–9.764; p = 0.0041) were worse when compared with the right coronary artery CTO in the RLVSF group, respectively (panel b).

Discussion

In this study, 2,173 CTO patients who were treated with either SCR or OMT and the differential prognostic effects of SCR over OMT according to LVSF status were analyzed. The major findings of this study are as follows: First, SCR yielded a significantly lower risk of composite all-cause death and non-fatal MI than OMT, regardless of LVSF status, mainly driven by a reduction in cardiac death. Second, the survival benefit of SCR was greater in patients with RLVSF than PLVSF, and the difference of survival benefit of SCR over OMT between the both groups increased significantly over time. Third, in the whole study population, a lower incidence of the primary endpoint in SCR-treated patients, compared with OMT-treated patients, was consistently observed among various subgroups except for the non-left anterior descending CTO subgroup. These findings indicate that patients with RLVSF should be actively treated with CTO revascularization because they might experience a greater benefit than patients with PLVSF. Fourth, among patients with SCR in the RLVSF group, CTO lesions of left anterior descending and left circumflex CTO showed poor prognosis than right coronary artery CTO, of which the left circumflex CTO had the worst prognosis. The complex anatomical features of left circumflex, such as poorer collaterals and limiting use of retrograde may have affected prognosis, as reported in previous study [9].

Debate over CTO revascularization for future clinical outcomes

Several mechanisms have been proposed to explain why patients who receive SCR experience greater survival benefits than patients who receive OMT. Sudden cardiac death incidence in OMT patients was reported to be five times greater (2.7% vs. 0.5%) than in SCR patients [10]. Several studies found that SCR improved LVEF and reduced the predisposition to ventricular arrhythmia [11,12,13]. Another possible explanation is that, in the context of MI, SCR offers protection from possible sudden occlusion in other vessels that provide collateral for the CTO vessel [14].

However, in recent randomized controlled trials, the DECISION-CTO (Drug-Eluting stent Implantation versus optimal Medical Treatment in patients with ChronIc Total OccluSION), EUROCTO (A Randomized Multicentre Trial to Evaluate the Utilization of Revascularization or Optimal Medical Therapy for the Treatment of Chronic Total Coronary Occlusions), and EXPLORE (Evaluating Xience and Left Ventricular Function in Percutaneous Coronary Intervention on Occlusions After ST-Elevation Myocardial Infarction) trials, a significant survival benefit of CTO-PCI was not found [15,16,17]. One possible explanation for the negative results is that PCI was implemented without considering risk severity based on the ischemic burden associated with CTO lesions. The effects of CTO revascularization between low-risk CTO lesions with mild ischemia and high-risk CTO lesions with moderate-to-severe ischemia are obviously different.

Effects of SCR in patients with RLVSF versus PLVSF

To date, data on CTO patients with RLVSF are limited because most CTO-related clinical studies excluded patients with RLVSF. Therefore, the number of patients with RLVSF among all CTO patients and their clinical outcomes after SCR are unknown.

RLVSF with CTO may represent a larger ischemic burden caused by CTO and relevant donor vessels than PLVSF if a considerable amount of myocardium is viable. Therefore, CTO patients with RLVSF who are found to have sufficient viable myocardium might receive greater benefit from SCR than patients with PLVSF.

Myocardial viability tests have been proposed as a key factor in the decision-making process concerning coronary revascularization procedures for ischemic heart failure patients, based on observational studies [18, 19]. However, these studies were limited by retrospective design, probable selection biases for revascularization, and inadequate adjustment for baseline comorbidities.

Although the present study did not include a myocardial viability test and did not demonstrate an improvement in LVEF after SCR, the survival benefit from SCR was much greater in patients with RLVSF than with PLVSF. Therefore, SCR should be actively promoted as a treatment option and the decision to pursue PCI for CTO revascularization should not be done solely on the basis of viability test results for patients with RLVSF. Given recent report that similar success rates and safety in elderly and young CTO patients might be achieved, SCR through PCI would be a preferred treatment option instead of coronary artery bypass graft especially for elder CTO patients with RLVSF [20].

Limitations

First, this study had inherent limitations associated with a retrospective study design. Although unbalanced factors were corrected using IPTW, completely eliminating effects of hidden factors on clinical outcomes was not possible. Second, because a viability test was not performed in patients with RLVSF, analysis of clinical outcome differences based on viability testing was not possible. Third, since two-dimensional echocardiography was not regularly performed in patients with RLVSF, analyzing clinical outcomes based on LVSF improvement was not available. Fourth, because patients with finally failed CTO-PCI were assigned to the OMT group, the OMT group might have had the worse results due to unfavorable influence of these particular patient subgroup. Also, OMT was not protocolized and left to the decision of the attending physician in present study. Medical and interventional treatment after the successful or failed CTO recanalization were inevitably different and this might interact with the endpoints of interest in this study. However, these finally failed CTO-PCI patients were assigned at a relatively similar rate to the PLVSF and RLVSF groups. Therefore, the negative effect on clinical outcomes of OMT between the PLSVF group and the RLVSF group is thought to be similar. Fifth, it was unable to assess the impact of implantable cardioverter defibrillator on clinical outcomes in the RLVSF group. Implantable cardioverter defibrillator implantation was not recommended for primary prevention in patients with LVEF < 35% in Korea at the time when the subjects of this study were collected. Sixth, we are lacking data on CTO crossing strategies, which might influence to clinical outcome.

Conclusion

SCR was associated with better survival benefit than OMT, mainly driven by a reduction in cardiac death in both PLVSF and RLVSF groups. The benefits were greater especially in patients with RLVSF than in those with PLVSF. The difference in survival benefit from SCR between PLVSF and RLVSF patients increased over time.