Coronary artery chronic total occlusion (CTO) is one of the most challenging obstacles faced by interventional cardiologists. Approximately one-third to one-half of the patients with significant coronary artery disease (CAD) on angiography have at least one CTO (1,2). Although collaterals are capable of maintaining myocardial viability at rest, they may fail to provide adequate blood flow during exercise, which can result in angina. Successful percutaneous coronary interventions (PCIs) of CTOs have been shown to improve the left ventricular (LV) systolic function, reduce angina, increase exercise capacity, and reduce the need for late bypass surgery (3–5).

An accurate assessment of LV function by determining the LV volumes and the ejection fraction (EF) is important in evaluating the prognoses of patients with CAD. Two-dimensional speckle tracking echocardiography (2D-STE) can assess the global LV function, and it is superior for EF measurements because it is angle-independent, less subject to artifacts, and easier to conduct than Doppler-derived tissue velocity imaging (6,7). Based on 2D-STE, automated function imaging is used to reflect the systolic LV function by assessment of the LV global longitudinal strain (GLS). Longitudinal tissue deformation is evaluated by frame-by-frame tracking of the individual speckles throughout the cardiac cycle. This imaging technique discriminates between active and passive myocardial motion and enables angle-independent quantification of myocardial deformation in two dimensions (8,9). 2D-STE is based on tracking the characteristic speckle patterns created by interference of ultrasound beams in the myocardium, and its accuracy has been confirmed using sonomicrometry and magnetic resonance imaging (MRI) as reference methods (10).

The aim of this study was to investigate the changes in the LV volumes, LVEF, and GLS of patients with CTO, before and one month after PCI, using novel echocardiographic methods.

Table 1 shows the baseline demographic, angiographic, and procedural characteristics of the study patients. The mean age of the patients was 58±9 years. There were no acute or subacute stent thrombosis. There was no death, acute MI, coronary perforation, emergency re-PCI, emergency coronary artery bypass graft surgery (CABG), or acute stroke during the periprocedural period. Pericardiocentesis was required for only one patient because of tamponade. The mean procedure time was 79±39 min, the fluoroscopy time was 34±19 min, and the amount of contrast was 492±174 ml. Contrast-induced nephropathy was developed in 14 (11%) patients, and one patient underwent hemodialysis.

Half of the patients (63 patients, 48.8%) suffered from angina pectoris (≥2 CCS) before the procedure, and the occurrence of angina pectoris decreased significantly after PCI. Compared with the measurements before the procedure, the LVEDV and LVESV decreased significantly (p = 0.001 and p<0.001, respectively) and the mean LVEF increased significantly (p<0.001) after the procedure. The SDI derived from RT3DE decreased significantly after successful revascularization (p<0.001). The GLS increased significantly one month after PCI (p<0.001) (Table 2). We found that the increase in the GLS was correlated with an improvement in the LVEF (r = 0.27, p = 0.02; Figure 1). The patients with an LVEF ≥50% displayed greater improvement in the GLS compared with the patients with an LVEF <50% (1.1±0.9 vs. 0.12±0.3, p<0.001). The patients with diabetes mellitus (DM) showed a lower degree of GLS improvement compared with the patients without DM (1.1±1.0 vs. 0.62±0.6, p = 0.07).

Figure 1.

Relationship between recovery of the global longitudinal strain (ΔGLS) and improvement of the left ventricular ejection fraction (ΔLVEF) during follow-up.

(0.03MB).

In this study, we used 2DSTE and RT3DE to determine that successful revascularization of CTO of the coronary arteries may improve the LV contractile function. We found that the improvement in the myocardial contractile function based on strain analysis seems to be more significant in the patients with a LVEF ≥50% and less significant in the patients with DM. To the best of our knowledge, this is the first study showing the benefit of revascularization of CTOs on LV function using 2DSTE and RT3DE.

LV systolic function is most commonly assessed by the LVEF using 2DE. The assessment of patients with CTO may be challenging with 2DE because many of these patients suffer from long-term myocardial ischemia or MI and develop aneurysmal formation or advanced ventricular remodeling. Strain and strain rate imaging using the 2D-STE method is a novel echocardiographic technique for the evaluation of regional and global myocardial function, is relatively free from angle dependency and the frame-rate limitations of tissue Doppler imaging, and enables calculations to be made more easily. The global LV contractile function, as assessed by 2D-STE, was shown to be superior to EF measurements by 2DE (6,7). RT3DE is the other new echocardiographic technique for calculating the actual LV volume based on the actual LV shape, rather than on geometrical assumptions. It has good reproducibility even in cases of heart cavity deformation or segmental wall motion abnormalities. It is more accurate than 2DE, and its accuracy approaches that of the gold standard, namely MRI (12,13).

Despite the presence of coronary collaterals, the majority of patients with a CTO show various degrees of LV dysfunction. The possibility of a functional recovery and its beneficial effect on survival are the rationale for the often technically demanding attempt to recanalize a CTO (3–5,14–18). Recovery of LV function in chronically ischemic myocardium depends on the presence of hibernating or stunned but viable myocardium (19). When reperfusion is acquired, the hibernating myocardium at least partially restores the contractile function, resulting in regional and global LV function recovery (20). Baks et al. showed the beneficial effect of successful CTO revascularization on the end-systolic and end-diastolic volumes. They showed that the extent of dysfunctional but viable myocardium before revascularization was related to an improvement in the end-systolic volume and LVEF (21). In the present study, we found a reduction in LV volumes; however, we used RT3DE, which is more robust than 2DE. Cheng et al. used contrast-enhanced MRI to demonstrate that successful CTO-PCI results in improved LV function and attenuated LV remodeling if the vessel patency is maintained (22). The improvements in LVEF and myocardial function in our study, based on 2DSTE and RT3DE, are consistent with the results of Cheng et al. The improvements in the LVEF and GLS observed in the current study may be a result of the recovered hibernating myocardium.

Multiple retrospective studies have shown the potential benefit of PCI in patients with CTO. Successful treatment improves anginal symptoms, exercise tolerance, and LV function. The prospective Total Occlusion Angioplasty Study (TOAST-GISE) showed that revascularization of a CTO is associated with relieved angina and reduces the 12-month incidence of cardiac death or MI and the need for CABG (5). Joyal et al. recently identified 13 observational studies comparing the outcomes after successful versus failed CTO recanalizations, showing that successful CTO recanalization was associated with a 44% reduction in mortality, a 78% reduction in the subsequent need for CABG, and a 55% reduction in residual or recurrent angina (23). In accordance with the above mentioned studies, successful revascularization of CTOs in our study resulted in a significant improvement in anginal symptoms. Approximately half of the patients did suffer from angina CCS 2 or greater before the procedure, and none of them had CCS 2 or greater after the procedure.

Numerous experimental studies have demonstrated that ischemia depresses the regional systolic function, resulting in severe systolic dyssynchrony, prolonged tension development in the ischemic regions, and impaired global relaxation (24,25). Bonow et al. reported that CAD was associated with dyssynchrony, which improved after mechanical revascularization (26). In the present study, the SDI derived by RT3DE, which is a marker of dyssynchrony, was improved one month after CTO revascularization. The improvement in dyssynchrony may be related to an improvement in the hibernating myocardium and in decreased LV volumes.

Endothelial dysfunction, structural changes of the microcirculation, and a negative influence on the development and prognosis of CAD are well-established features of patients with DM (27–29). Patients with DM have a greater extent of CAD and are prone to impaired clinical outcomes compared with nondiabetic patients (30–32). A previous observational study about CTO PCI in diabetics was performed by Safley et al. They reported that DM patients do not seem to have the same survival benefits from successful PCI of a CTO as patients without DM (33). In our study, we found relatively less improvement in the GLS in diabetic patients. It is still not clear why diabetics benefit less from PCI of a CTO, but we speculate that the extensive atherosclerosis and impaired microvascular circulation may explain the worse outcomes in this population.

Erdogan E contributed to the study design, data collection and interpretation, statistical analysis, manuscript preparation, and literature search. Akkaya M contributed to the study design, data collection and interpretation, and literature search. Bacaksiz A contributed to the data interpretation, manuscript preparation, and literature search. Tasal A, Sönmez O, Elbey MA, Kul S, Turfan M, Vatankulu MA, and Göktekin O contributed to the data collection and interpretation and statistical analysis.