Background
Chronic total occlusions (CTOs) are present in around 15% of patients with significant coronary artery disease and are associated with an adverse clinical outcome [
1]. Because of low technical success rates and an increased risk of procedural complications, patients with CTOs have historically been referred for surgery or offered medical treatment only. The introduction of drug-eluting stents, improved techniques and dedicated CTO devices have led to a marked increase in procedural success for percutaneous coronary intervention (PCI) for CTOs [
2].
Observational studies have reported that successful recanalisation of CTOs can improve angina and quality of life as well as left ventricular ejection fraction (LVEF) and survival [
3]. However, randomised controlled trials examining the outcome of CTO-PCI are limited and not definitive [
4‐
7].
Current international guidelines state that the treatment of CTOs may be considered analogous to the treatment of non-CTO lesions [
8,
9], which means that a CTO-PCI is indicated in patients with persistent symptoms despite optimal medical therapy (OMT) or in those with a large ischaemic CTO territory. In cases of reduced LVEF with regional wall motion abnormalities in the CTO territory, objective evidence of viability should be present.
Because of the complexity of the procedure and the increased risk of complications during CTO-PCI, it is essential that less experienced and evolving CTO centres perform regular quality analyses. We therefore performed an analysis to describe the first results of a dedicated CTO programme in a tertiary medical centre. In addition, we discuss the strategies employed to develop such a programme.
Methods
Development of a CTO programme
Our dedicated CTO team was initiated in 2014 by two interventional cardiologists (H.W. van der Werf and E. Lipšic), who have both performed more than 1000 PCI procedures in the last 5 years. The operators and participating catheterisation laboratory staff were trained by means of educational programmes and on-site proctorship of physicians (by established experts in CTO revascularisation). The CTO operators organised weekly meetings to determine the appropriateness of indications for CTO-PCI, necessary additional examinations and a procedural strategy for each patient. Every week 1 day was reserved for scheduling CTO cases by a 2-operator/case policy. Procedural guidelines were also established related to antithrombotic therapy, iodinated contrast exposure and ionising radiation exposure.
All patients in whom a CTO-PCI was attempted were registered for quality issues. The research complied with the Dutch law on Medical Research in Humans and local research guidelines.
Patients
The study population consisted of patients who underwent a PCI at the University Medical Centre Groningen in the period from January 2015 to December 2017.
All patients with a CTO treated by physicians of the newly developed CTO team were included in this study. Patients undergoing unplanned CTO procedures by other physicians were not included.
Procedural details
The indications for performing a CTO-PCI were persistent symptoms under OMT and reversible myocardial ischaemia/viability on non-invasive imaging.
We used bilateral arterial access routinely with a preference for (one) radial artery. At the start of the programme in 2015 mainly antegrade procedures were carried out. From January 2016, the hybrid algorithm (including retrograde wiring through collaterals or grafts and use of device-assisted dissection and re-entry) became common practice.
Local protocols and standard contrast reduction methods were used for the prevention of contrast-induced nephropathy. As radiation exposure is higher during CTO-PCI, the radiation dose was minimised by several additional methods. Extended radiation shields and drapes were used during procedures. Further, a low-dose fluoroscopy protocol was used and the frame rate per second was lowered to 7.5 instead of 10.
Adjunctive therapy included intravenous heparin during the procedure to achieve an activated clotting time (ACT) of 300–350 s during antegrade procedures and >350 s during retrograde procedures. ACT measurement was performed every 30 min. Acetylsalicylic acid was administered prior to the procedure and continued indefinitely. Clopidogrel was given with a loading dose of 600 mg before the start of the procedure and was continued at a dose of 75 mg for at least 12 months after stent implantation. Following uncomplicated PCI, patients were discharged home the same or the following day.
Data collection
At the start of the CTO programme all patients in whom a CTO-PCI was attempted were prospectively registered for quality issues. Baseline, angiographic, procedural and outcome data were collected and managed using REDCap (Research Electronic Data Capture) electronic data capture tools hosted at the University Medical Centre Groningen [
10].
Definitions
CTOs were defined as a lesion of a native coronary artery that exhibited Thrombolysis in Myocardial Infarction (TIMI) antegrade flow grade equal to 0 for at least 3 months. The J‑CTO (Japanese Multicentre CTO Registry) score was calculated as previously described [
11]. Occlusion length was estimated from the angiographic image using a bilateral arterial approach or the stent and balloon length as reference. Presence of calcification in the CTO segment was determined by fluoroscopy without contrast injection.
Antegrade wire escalation (AWE) was defined as antegrade wiring from true-to-true lumen with increasing guidewire tip loads and penetration force if needed. Subintimal tracking and re-entry and limited antegrade subintimal tracking techniques were defined as wire- and device-based antegrade dissection re-entry techniques. Any retrograde approach to the distal CTO cap is considered a retrograde procedure (including retrograde wire escalation (RWE) and dissection re-entry).
Peri-procedural complications included life-threatening and major bleeding (Bleeding Academic Research Consortium criteria), major cardiac complications (including sustained ventricular arrhythmia, coronary dissection, coronary perforation, septal haematoma, cardiac tamponade as well as intracoronary thrombus formation or air embolism) and access site complications.
Myocardial infarction, both in hospital and at 30-day follow-up, was considered to have occurred if at least two of the three following criteria were met: (1) prolonged chest pain ≥20 min, (2) enzyme changes (more than double the upper normal limits of creatine kinase (CK), CK-MB, or relative index), (3) ST-T-wave changes or new Q‑waves on serial electrocardiograms indicative of myocardial damage. Target vessel revascularisation (TVR) was defined as any repeat percutaneous intervention or surgical bypass of any segment of the target vessel. Planned second attempts at revascularisation of CTO lesions were not scored as TVR.
The primary endpoints of this study were technical and procedural success. Technical success was defined as successful CTO revascularisation with achievement of <30% residual diameter stenosis within the stented segment and restoration of TIMI flow grade 3 antegrade. Procedural success was defined as technical success with no procedural major cardiac adverse events. The secondary endpoints included the occurrence of peri-procedural and in-hospital complications, MI, TVR, and mortality at 30-day and 1‑year follow-up.
Statistical methods
Statistical analyses were performed using SPSS version 23 (Armonk, NY, USA: IBM Corp.) for Windows. A two-tailed probability value of <0.05 was considered statistically significant. Descriptive data are presented as numbers with percentage, as mean with standard deviation or as median with range. Comparisons across the first years of the CTO team were performed by the Pearson chi-square test for categorical variables, one-way ANOVA for normally distributed continuous variables and Kruskal-Wallis test for non-normally distributed continuous variables.
Discussion
We present the first results of a dedicated CTO programme in a tertiary medical centre. The main finding of this study is that during the first years of the programme the technical and procedural success rates were in accordance with current standards and tended to increase following implementation of the hybrid algorithm. During the same period the complexity of the lesions increased, with only a limited number of serious adverse cardiac events and complications.
To date only three randomised controlled trials have been published on CTO-PCI. The EuroCTO trial randomised 396 patients to OMT versus CTO-PCI and found a significant improvement in health status after CTO-PCI [
4]. The EXPLORER trial randomised 304 patients with ST-segment elevation MI and a CTO in a non-culprit vessel to CTO-PCI versus OMT and found no difference in the primary endpoint of LVEF improvement [
5]. The recently published IMPACTOR-CTO trial randomised 94 patients with an isolated CTO of the right coronary artery to CTO-PCI versus OMT. Patients with an unsuccessful CTO-PCI and those non-compliant with medical therapy were excluded from the primary analysis. After 12 months of follow-up CTO-PCI was associated with a significant reduction in ischaemic burden as measured by cardiac MRI [
6]. The results of the DECISION-CTO trial were recently published, and showed no clinical benefit of CTO-PCI over OMT [
7]. However, more methodological issues concerning this study were raised.
Because of the limited number of randomised studies, registries supply additional information on treatment safety and efficacy of CTO-PCI. Since the adoption of the hybrid approach and increased use of retrograde techniques, success rates have increased along with lesion complexity. Several studies have found current success rates between 70% and 85% [
2,
12‐
14]. In accordance with these registry results, we found an excellent rate of in-hospital major adverse cardiac events of less than 1%. Peri-procedural complications were present in around 10%. Although some complications were serious, the majority could be adequately solved during the index procedure without the need for emergency cardiac surgery. One-year follow-up showed excellent clinical outcome in our population. The TVR rate in the studied CTO-PCI population was even lower than the national average for all registered PCIs [
15]. With regard to the successful strategies used, AWE remained the predominant strategy during the first years. As AWE remains the basis and start of a CTO-PCI, increased experience and skills have also resulted in more success with AWE techniques.
Regarding the outcome in complex PCIs, it is well known that procedural success and complication rates are strongly dependent on technical skills, operator volume and the availability of dedicated staff and equipment. Current international guidelines emphasise these points, and supply several recommendations regarding training, regional collaboration and volume [
7,
8]. Further, they recommend that outcome data are reported by hospitals to national databases to allow outcome monitoring and benchmarking. However, no specific recommendations are given for CTO procedures. The recently published consensus document from the EuroCTO Club supplies more detailed information on centre/operator requirements and expertise in CTO-PCI [
16]. They state that centres and operators performing less than 30 CTO procedures annually should refer their patients to a more experienced operator or centre. Retrograde techniques should be reserved for experienced operators performing more than 50 CTO-PCIs per year. A minimum of 50 retrograde procedures might be advised before a cardiologist becomes an independent retrograde operator. These recommendations can be used to draft or extend existing national volume norms for complex PCI.
Our analysis showed that in a high-volume PCI centre it is possible to start a dedicated CTO programme which already fulfils the majority of these volume norms during the first years. Although still a relatively small-scale programme, we expect that with improved success rates, shorter procedure times and increasing numbers of referrals, an increase to a preferred minimum of 100 procedures per year being performed by the dedicated CTO team is most likely in the coming years. In our opinion, the possibility of a joint team from two PCI centres (e.g. one high- and one intermediate-volume) could also be considered.
Upcoming trials
In the coming years several large randomised clinical trials comparing OMT and CTO-PCI will be performed, e.g. the NOBLE-CTO multicentre trial, which will randomise 2000 patients to CTO-PCI or OMT with an option to cross over after 6 months (NCT03392415). The ISCHEMIC-CTO multicentre trial will randomise 1500 patients to CTO-PCI or OMT (NCT03563417). Also interesting is that a sham-controlled trial is underway: the SHINE CTO single-centre trial (NCT02784418), which will randomise 142 patients to CTO-PCI or a sham procedure.
Limitations of the study
This single-centre registry study of 179 patients undergoing CTO-PCI suffers from the limitations inherent to this particular study design. The incidence of MIs might be underestimated, as screening by cardiac markers was performed only on indication and not routinely after PCI. Unfortunately, no outcome data were available regarding reduction in ischaemia, improvement in LVEF and symptoms after CTO-PCI.