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iFR/FFR/IVUS Discordance and Clinical Implications: Results From the Prospective Left Main Physiology Registry
Abstract
Objectives. This study aimed to assess discordance between results of instantaneous wave-free ratio (iFR), fractional flow reserve (FFR), and intravascular ultrasound (IVUS) in intermediate left main coronary (LM) lesions, and its impact on clinical decision making and outcome. Methods. We enrolled 250 patients with a 40%-80% LM stenosis in a prospective, multicenter registry. These patients underwent both iFR and FFR measurements. Of these, 86 underwent IVUS and assessment of the minimal lumen area (MLA), with a 6 mm2 cutoff for significance. Results. Isolated LM disease was recognized in 95 patients (38.0%), while 155 patients (62.0%) had both LM disease and downstream disease. In 53.2% of iFR+ and 56.7% of FFR+ LM lesions, the measurement was positive in only one daughter vessel. iFR/FFR discordance occurred in 25.0% of patients with isolated LM disease and 36.2% of patients with concomitant downstream disease (P=.049). In patients with isolated LM disease, discordance was significantly more common in the left anterior descending artery and younger age was an independent predictor of iFR-/FFR+ discordance. iFR/MLA and FFR/MLA discordance occurred in 37.0% and 29.4%, respectively. Within 1 year of follow-up, major cardiac adverse events (MACE) occurred in 8.5% and 9.7% (P=.763) of patients whose LM lesion was deferred or revascularized, respectively. Discordance was not an independent predictor of MACE. Conclusions. Current methods of estimating LM lesion significance often yield discrepant findings, complicating therapeutic decision-making.
J INVASIVE CARDIOL 2023;35(5):E234-E247.
Key words: fractional flow reserve, instantaneous wave-free ratio, intravascular ultrasound, plaque rupture
Introduction
More than 80% of the coronary flow to the left ventricle passes through the left main coronary artery (LM).1 Plaque rupture in the LM often causes sudden death or results in large myocardial infarctions and cardiogenic shock with high mortality. 2 Patients with significant LM disease not revascularized by coronary artery bypass surgery (CABG) or percutaneous coronary intervention were found to have a poor prognosis.3
In patients with chronic coronary syndromes, revascularization is recommended for persistent invalidating ischemic symptoms and functionally significant lesions.4 In patients with a LM stenosis, inappropriate deferral of revascularization may impede symptom improvement and increase the risk of spontaneous, possibly fatal, adverse events, while inappropriate revascularization would unnecessarily expose patients to procedure-related risks and early bypass failure when CABG is chosen. 5
The European Society of Cardiology (ESC) guidelines recommend using fractional flow reserve (FFR) or instantaneous wave-free ratio (iFR) to demonstrate functional significance of intermediate-grade coronary stenoses.4 Randomized trials have shown that revascularization of functionally significant lesions improves outcomes while deferring non-significant lesions appears safe.1 For the evaluation of intermediate LM lesions, which are notoriously difficult to assess angiographically, the ESC endorsed both FFR and iFR with a class I recommendation.4 Intravascular ultrasound (IVUS) received a class IIa recommendation for this purpose.4 In general, a minimal lumen area (MLA) of ≤/>6 mm2 on IVUS is then used to decide on revascularization or deferral.1,4,6
The Prospective Left Main Physiology Registry (PHYNAL) registry was designed to assess prevalence and clinical importance of conflicting results of iFR, FFR, and IVUS in intermediate LM lesions.
Methods
Patient population. Between January 2019 and May 2021, 14 university and large community Belgian centers enrolled 250 consecutive patients with a LM lesion of intermediate severity, defined as a 40%-80% diameter stenosis on visual assessment of the angiogram. Patients with concomitant disease in the left anterior descending (LAD), circumflex (LCx), and/or right coronary artery were also included. The LM lesions had to be presumably stable. The study was approved by local ethics committees and all patients provided written informed consent.
Study procedure. The enrolled patients underwent both iFR and FFR measurements. IVUS use was at operator’s discretion, but recommended if the stenosis was >50%, iFR 0.90 to 0.93, or FFR 0.80 to 0.85.
iFR and FFR were measured with the Verrata pressure wire and associated software (Philips). All operators received training on best practices and systematic approaches. This included use of a guiding catheter, upfront intracoronary administration of nitrates, pressure equalization in the aorta, and final verification of absence of significant drift. First, the iFR was measured in both LAD and LCx. Thereafter, FFR measurements were performed in both vessels during intravenous administration of adenosine. If the intermediate branch was larger than LCx, measurements in the former were considered LCx measurements. iFR and FFR were always measured distally in LAD and LCx where the vessels where approximately 2 mm in diameter. In cases of downstream disease in LAD and/or LCx, additional proximal iFR measurements were performed 5 mm distal to the LM carina in both LAD and LCx (iFRPROX). In patients with an isolated LM lesion, the lesion was considered positive (significant) by iFR if the iFR was ≤0.89 in at least one daughter vessel and positive by FFR if the FFR was ≤0.80 in at least one daughter vessel. In patients with downstream disease, the LM lesion was considered positive by iFR if the iFRPROX was ≤0.89 in at least one daughter vessel. In those patients, the FFR measurements were not used to decide upon significance of the LM lesion. iFR/FFR discordance was assessed in all patients using the distal iFR and FFR measurements only.
IVUS was performed with the Refinity rotational device (Philips) and automated pullbacks at 0.5 mm/sec. A LM lesion with an MLA ≤6 mm2 was considered significant by IVUS. To analyze discordance between physiological and imaging parameters, the lowest iFR and FFR values were correlated with the MLA. For iFR, this analysis used the distal iFR value in patients with isolated LM disease and the iFRPROX value in patients with concomitant downstream disease. For the comparison with FFR, only the patients with isolated LM disease were considered.
After each step in the LM lesion assessment, the preferred therapeutic strategy was noted. The final treatment was determined by the treating physician and the Heart Team considering all relevant patient characteristics and patient preference. All angiographic images and physiological measurements were analyzed by two experienced operators together (PK, MC). IVUS images were analyzed by the “UMONS Cœur” core laboratory.
Study endpoints. This registry was designed with two primary aims. First, to examine the occurrence of discordance in iFR/FFR, iFR/MLA, and FFR/MLA results. Second, to determine the percentage of major adverse cardiac events (MACE), defined as a composite of death, nonfatal myocardial infarction (MI), and unplanned target lesion (LM) revascularization (TLR) at 1-, 2-, and 5-years follow-up. It was pre-specified to assess the outcomes of patients whose LM lesion was deferred based on a negative iFR. The study design and flowchart are presented in the supplemental appendix (Figure S1).
Statistical analysis. The statistical analysis was performed using IBM SPSS Statistics for Windows, version 27 (IBM Corp). Continuous variables are presented as mean ± standard deviation (SD) or as median with interquartile range. The Shapiro-Wilk test was used to test normality. Categorical variables are presented as counts and percentages. Continuous variables were compared using Student’s t or Mann-Whitney U-tests, and categorical variables using χ2 or Fisher’s exact tests, as appropriate. A logistic regression model was used for multivariate analysis to detect influencing factors on iFR/FFR discordance. Correlations between iFR/FFR and iFR/MLA were assessed using the Pearson test. A two-tailed P<.05 was considered statistically significant for all tests.
Results
Clinical features and patient demographics are presented in Table 1. Both iFR and FFR were measured in 250 patients, and 86 (34.4%) of these patients also underwent IVUS. Table 2 summarizes the results from the assessments by angiography, physiology, and IVUS.
As assessed by iFR, 24.8% (62/250) of the LM lesions were considered significant: 29.5% (28/95) of the patients with isolated LM disease and 21.9% (34/155) of the patients with downstream disease. As assessed by FFR, 31.6% (30/95) of the patients with isolated LM disease were considered significant.
The significance of the LM lesion as suggested by the physiological measurement often depended on the daughter branch in which the measurement was taken (Figure 1). In 53.2% of iFR-positive and 56.7% of FFR-positive LM lesions, the value was positive in only one daughter vessel. In those patients, that vessel was the LAD in 63.6% and 88.2% of cases, respectively.
FFR = fractional flow reserve; iFR = instantaneous wave-free ratio; LAD = left anterior descending artery; LCx = left circumflex artery; LM = left main coronary artery; iFRPROX = iFR measured 5 mm distal to LM carina; V = daughter vessel
*not applicable for FFR as FFR is influenced by downstream disease
iFR/FFR discordance. In Figure 2, we present the occurrence of iFR/FFR discordance per patient and vessel. In patients with isolated LM disease, the lowest iFR and FFR values showed a moderate correlation (Pearson r=0.553, P<.001), represented in Figure 3. In those patients, discordance was more frequent in LAD compared with LCx (16.8% vs 14.3%, P =.003). In a multivariate analysis, younger age was an independent predictor of iFR-/FFR+ discordance (P =.005).
FFR = fractional flow reserve; iFR = instantaneous wave- free ratio; LAD = left anterior descending artery; LCx = left circumflex artery; LM = left main coronary artery
The relationship between the lowest iFR and FFR is shown in a scatter plot for the patients with isolated LM disease (Pearson correlation coefficient r = 0.553; P <.001). For the patients who have also undergone IVUS, the relationship with the MLA is shown: red dots represent patients with an MLA £6 mm2, while patients with an MLA >6 mm2 are shown as green dots, and patients in whom IVUS was not performed are shown as blue dots. iFRLM = instantaneous wave-free ratio, left main; FFR = fractional flow reserve; iFR = instantaneous wave-free ratio; IVUS = intravascular ultrasound; LM = left main coronary artery; MLA = minimal lumen area
iFR/MLA and FFR/MLA discordance. The lowest iFR and MLA were poorly related (r=0.040, P=.063). iFR/MLA discordance occurred in 37.0% of patients (44.1% of patients with isolated LM disease). Minimal FFR and MLA were also poorly related in patients with isolated LM disease. Discordant values were found in 29.4%. The discordance between physiological parameters and MLA in patients with isolated disease is illustrated in Figure 3. No parameter emerged as an independent predictor of this type of discordance.
Impact on strategy. Figure 4 shows how adding iFR, FFR, or IVUS to angiography reclassified LM significance. Figure 5 shows how the treatment strategy changed based on physiological assessments and how the patient was ultimately treated. The decision to defer revascularization of the LM disease was consistent with the iFR in 91.5% of patients, while the decision to revascularize was consistent with the iFR in 64.4% of patients. The reasons why the iFR was overruled are stated in the online supplement. No intervention for LM disease was performed in 177 (70.8%) patients.
Depending on the tool one uses to assess the significance of an intermediate LM, the lesion is often classified differently.
∆ = reclassification percentage; angio = coronary angiogram; FFR = fractional flow reserve; iFR = instantaneous wave-free ratio at distal level in patients with isolated disease and at 5 mm distal to the LM carina in patients with downstream disease; LM = left main coronary artery; IVUS = intravascular ultrasound
Angio = coronary angiogram; CABG = coronary artery bypass grafting; FFR = fractional flow reserve; iFR = instantaneous wave-free ratio; LM = left main coronary artery; OMT = optimal medical therapy
One-year clinical outcomes. Patients whose LM lesion was deferred had similar one-year MACE rates compared with revascularized patients (Figure 6). However, 12 of the 22 events (54.5%) were deaths that could not be associated with a coronary event. Of the remaining 10 events, all of which occurred in deferred patients, 9 were TLRs, including 6 in patients with iFR/FFR discordance. Only 2 TLRs were performed for acute coronary syndrome (1 unstable angina, 1 MI). The presence of iFR/FFR/MLA discordance was not an independent predictor of MACE.
*The outcome was unknown in 1 deferred patient and 1 revascularized patient as they were lost to follow-up. †The one CD that occurred was not related to a coronary event (known cardiomyopathy and ventricular arrythmia).
CD = cardiac death; LM = left main coronary artery; MACE = major adverse cardiac events; NCD = non-cardiac death; TLR = target lesion
Discussion
In the PHYNAL study, intermediate-grade LM lesions were assessed using both the guideline-recommended physiological indices, iFR and FFR, and IVUS in selected patients. Three key findings emerged from this systematic approach.
1. Discordance is common and impacts clinical decision-making.
When taking measurements in both LAD and LCx into account, iFR/FFR discordance occurred in 25.0% of patients with isolated LM disease and significantly more frequently (36.2%) when downstream disease was present. Previously, discordance, has been reported in approximately 20% of non-LM lesions and explained by differences in hyperemic coronary flow velocity. 1,7,8 It was later found to be more common in proximal LAD and LM lesions (predominantly iFR-/FFR+ discordance) and this was attributed to higher hyperemic flows and pressure gradients (lower FFR values) across lesions supplying more myocardium.9,10 Subsequently, 3 observational studies focused on LM lesions. The first series included 80 patients and found iFR/FFR discordance in 18.7% of cases.11 Only 10.0% of patients had measurements in both LAD and LCx. It was not reported how many patients had downstream disease and how pressure measurements were taken and interpreted in such cases. The iLITRO-EPIC07 prospective registry enrolled 300 patients with a 25%-60% LM diameter stenosis.12 Severe lesions in LAD or LCx had to be treated with PCI before and patients with an indication for CABG, regardless of LM lesion significance, were excluded. More than 85% of patients underwent pressure measurements in both LAD and LCx. Discordance occurred in 20.3% of patients when measurements were performed in the LAD, compared with 13.6% when performed in the LCx. In PHYNAL, LM lesions with a 40%-80% diameter stenosis were enrolled. To reflect the challenges of real-life decision-making, patients with concomitant downstream disease were deliberately allowed. 96% of the patients had iFR and FFR measurements in both LAD and LCx. We also found that discordance was more frequent in LAD than in LCx: 16.8% and 14.3%, respectively (P=.003) in isolated LM disease and 23.0% and 18.2%, respectively (P -value non significant) in LM disease with additional downstream disease. Younger age was associated with iFR-/FFR+ discordance in patients with isolated LM disease, a finding probably related to preserved microvascular function in younger patients.13
We also found that MLAs measured with IVUS poorly correlated with iFR and FFR results. Discordance with a binary 6 mm2 MLA cut-off occurred in more than 30% of cases, a finding comparable to recent series in which IVUS was performed systematically. 12,14
The use of iFR or FFR assessments is known to alter initial angiogram-based treatment decisions in non-LM lesions by up to 40% and 48%, respectively, usually in favor of medical therapy. 15,16 Also in our study, iFR, FFR, and IVUS reclassified more than 40% of angiographic intermediate LM lesions from significant to non-significant and vice versa, resulting in a change in treatment plan.
2. Physiological assessment of LM lesions requires assessment of both daughter vessels and attention to downstream disease.
More than half of patients with a positive LM iFR or FFR had positive measurements in only one vessel (usually LAD). Thus, measuring in all major daughter vessels is important to avoid missing significant LM disease. Knowing that the physiological findings are only significant in one branch may also be particularly important when the patient is sent for surgery, as the bypass graft may fail on a branch in which the flow is not significantly impeded. 5,17
LM disease often involves the distal bifurcation and may extend to daughter vessels, affecting perfusion differently in each vessel. 1 Other factors may also play a role. The greater the mass of the perfused myocardium subtended by a stenosis, the more likely the stenosis will be functionally significant. 18 Because the LAD perfuses a greater mass of myocardium than the LCx, the same LM lesion may lower iFR and FFR more in LAD than in LCx. The distal segments of LAD and LCx, where the distal pressure measurements were performed in this study, are also exposed to different hydrostatic pressures. 19 In a supine patient, when the pressure wire sensor is placed in the distal LAD, it is located several centimeters higher than the coronary ostium, while it is located several centimeters lower than the ostium when the sensor is placed in distal LCx. This may result in measured pressures and iFR and FFR values that are lower in the distal LAD and higher in the distal LCx.19,20
Three out of 5 patients with LM disease also had downstream disease, which is consistent with real clinical practice but challenging for physiological assessments. 1 Downstream disease could potentially reduce flow, and especially hyperemic flow across a LM lesion, thereby decreasing the hyperemic pressure gradient across the LM lesion and increasing the FFR value. 1 iFR is measured at rest when flow is kept constant due to autoregulation and expected to be less affected by lesion interaction than FFR, provided the lesions are not so critical that the autoregulatory reserve is already depleted at rest. 1 iFR is therefore put forward as a technique to assess serial lesions individually. 21 Whether using an iFR value just distal to the LM lesion (iFRPROX in our study) in a case with downstream disease is sufficient to assess the significance of the LM lesion and safe to guide treatment remains to be proven. Our finding that iFR/FFR discordance at the distal level was significantly more frequent in the presence of downstream disease and evidence indicating that the significance of individual lesions in serial disease may still be underestimated with FFR, but also with iFR, call for additional outcome data.22
3. Short-term clinical outcomes
Observational data suggest that FFR and iFR can guide the decision to revascularize or defer LM lesions, although evidence for this is limited to 6 studies with FFR in 525 patients (of which only one used the 0.80 cut-off) and one partial retrospective study with iFR in 314 patients.23,24 In PHYNAL, the decision to defer the LM lesion was largely consistent with the iFR assessment and the 1-year outcomes of patients whose LM lesion was deferred were comparable to the outcomes of the revascularized patients.
Patients with concordant iFR and FFR positive LM lesions are likely to benefit from revascularization, while patients with concordant negative findings are unlikely to, although negative physiological findings alone are not sufficient to predict an event-free outcome.1 For LM lesions with discordant iFR/FFR results, the prognosis with or without revascularization is less clear. The prognosis was not worse in patients with deferred iFR/FFR discordant non-LM lesions in one study.25 In our study, cardiac events in the deferred group were uncommon. Six out of 9 TLRs occurred in patients with iFR/FFR discordance, but only 2 presented with an ACS. Awaiting further outcome data, one should closely monitor patients with a deferred LM lesion, especially if discordant physiological findings are obtained. In those patients, one might consider performing IVUS and deferring the LM lesion only when the MLA is above 6 mm2, as data from the LITRO and iLITRO-EPIC07 study then suggest acceptable outcomes.12,26
Study limitations. First, selection bias was likely present, as some operators may have been reluctant to invasively interrogate some intermediate LM lesions, especially in the presence of noninvasive evidence of ischemia, a fragile appearance, or significant bystander disease that favors surgery anyway. Overestimation of diameter stenosis by angiography may have resulted in inclusion of milder lesions.
Second, because of the material costs and lower estimated risk-benefit ratio in cases with highly abnormal or highly reassuring physiological findings, IVUS was performed only for lesion evaluation in patients with more borderline disease. This may explain the higher rates of discordance compared to physiological findings.
Third, patients with angiographically isolated LM disease may have had significant downstream disease that was not diagnosed because systematic iFR/FFR or IVUS pullback was not mandatory.
Fourth, iFRs at 5 mm from the LM carina may have been affected by disease and related flow disturbances at that level.
Finally, enrollment slowed down in some centers. As this was mainly attributable to local COVID-19 measures and/or change in provider of physiological hardware, we assume this did not affect our results.
Conclusions
In the PHYNAL study we found that current methods of estimating significance of LM lesions often yield contradictory findings, making the therapeutic decision-making challenging. Our study does not indicate a poor outcome in patients whose LM lesion is deferred, regardless of discordant physiological findings. Nevertheless, as available outcome data are still limited and physiology as a predictor of events is imperfect, patients with a deferred LM lesion require optimal medical treatment and careful follow-up.
Affiliations and Disclosures
From 1Department of Cardiology, Jessa Hospital, Hasselt, Belgium; 2Department of Medicine and Life Sciences, Hasselt University, Diepenbeek, Belgium; 3Department of Cardiology, Jan Yperman Ziekenhuis, Ypres, Belgium; 4Department of Cardiology, Centre Hospitalier Universitaire Ambroise Paré, Mons, Belgium; 5Department of Cardiology, Université de Mons, Mons, Belgium; 6Department of Cardiology, Ghent University Hospital, Ghent, Belgium; 7Department of Cardiovascular Medicine, University Hospitals Leuven, Leuven, Belgium; 8Department of Cardiovascular Sciences, Katholieke Universiteit Leuven, Leuven, Belgium; 9Department of Cardiology, Jolimont Hospital, La Louvière, Belgium; 10Department of Cardiology, Centrum voor Hart- en Vaatziekten, UZ Brussel, Jette, Belgium; 11Department of Cardiology, AZ Maria Middelares Gent, Ghent, Belgium; 12Department of Cardiology, AZ Sint-Lucas Gent, Ghent, Belgium; 13Department of Cardiology, Ziekenhuis Oost- Limburg, Genk, Belgium; 14Department of Cardiology, Hôpital de la Citadelle, Liège, Belgium; 15Department of Cardiology, Imelda Ziekenhuis, Bonheiden, Belgium; 16Department of Cardiology, CHU Saint Pierre, Brussels, Belgium; 17Department of Cardiology, AZ Sint-Maarten, Mechelen, Belgium; 18Department of Cardiology, Cliniques Universitaires Saint-Luc; 19IREC, University of Louvain, Brussels, Belgium; 20Department of Cardiology, Antwerp University Hospital, Antwerp, Belgium; 21Department of Cardiovascular Diseases, University of Antwerp, Antwerp, Belgium.
Disclosure: The authors have completed and returned the ICMJE Form for Disclosure of Potential Conflicts of Interest. Peter Kaert reports speaking fees from Philips, 2019, 2020. The remaining authors report no disclosures.
Manuscript accepted February 23, 2023.
Address for correspondence: Peter Kayaert, MD, Department of Cardiology, Jessa Hospital, Stadsomvaart 11, 3500 Hasselt, Belgium, peter.kayaert@jessazh.be; Steven Haine, MD, Department of Cardiology, Antwerp University Hospital, Antwerp, Belgium. Email: steven.haine@uza.be
References
1. Kayaert P, Coeman M, Gevaert S, De Pauw M, Haine S. Physiology-based revascularization of left main coronary artery disease. J Interv Cardiol. 2021:4218769. doi: 10.1155/2021/4218769
2. Yeoh J, Andrianopoulos N, Reid CM, et al. Long-term outcomes following percutaneous coronary intervention to an unprotected left main coronary artery in cardiogenic shock. Int J Cardiol. 2020;308:20-25. doi: 10.1016/j.ijcard.2020.03.005
3. Yusuf S, Zucker D, Peduzzi P, et al. Effect of coronary artery bypass graft surgery on survival: overview of 10-year results from randomised trials by the coronary artery bypass graft surgery trialists collaboration. Lancet. 1994;344:563-570. doi: 10.1016/s0140-6736(94)91963-1
4. Neumann F-J, Sousa-Uva M, Ahlsson A, et al. 2018 ESC/EACTS guidelines on myocardial revascularization. Eur Heart J. 2018:1-96. doi: 10.1093/eurheartj/ehy394
5. Wada T, Shiono Y, Kubo T, Honda K, et al. Impact of instantaneous wave-free ratio on graft failure after coronary artery bypass graft surgery. Int J Cardiol. 2021;324:23-29. doi: 10.1016/j.ijcard.2020.09.046
6. Kappetein AP, Serruys PW, Sabik JF, et al. Design and rationale for a randomised comparison of everolimus-eluting stents and coronary artery bypass graft surgery in selected patients with left main coronary artery disease: the EXCEL trial. EuroIntervention. 2016;12:861-872. doi: 10.4244/EIJV12I7A141
7. Jeremias A, Maehara A, Généreux P, et al. Multicenter core laboratory comparison of the instantaneous wave-free ratio and resting Pd/Pa with fractional flow reserve: the RESOLVE study. J Am Coll Cardiol. 2014;63:1253-1261.doi: 10.1016/j.jacc.2013.09.060
8. Cook CM, Jeremias A, Petraco R, et al. Fractional flow reserve/instantaneous wave-free ratio discordance in angiographically intermediate coronary stenoses: an analysis using doppler-derived coronary flow measurements. JACC Cardiovasc Interv. 2017;10:2514-2524. doi: 10.1016/j.jcin.2017.09.021
9. Kobayashi Y, Johnson NP, Berry C, et al. The influence of lesion location on the diagnostic accuracy of adenosine-free coronary pressure wire measurements. JACC Cardiovasc Interv. 2016;9:2390-2399. doi:10.1016/j.jcin.2016.08.041
10. Dérimay F, Johnson NP, Zimmermann FM, et al. Predictive factors of discordance between the instantaneous wave-free ratio and fractional flow reserve. Catheter Cardiovasc Interv. 2019:1-8. doi: 10.1002/ccd.28116
11. De Rosa S, Polimeni A, De Velli G, et al. Reliability of instantaneous wave-free Ratio (iFR) for the evaluation of left main coronary artery lesions. J Clin Med. 2019;8:E1143. doi: 10.3390/jcm8081143
12. Rodriguez-Leor O, de la Torre Hernandez JM, García Camarero T, et al. Instantaneous wave-free ratio for the assessment of intermediate left main coronary artery stenosis: correlations with FFR/IVUS and prognostic implications: the iLITRO - EPIC07 study. Circ Cardiovasc Interv. 2022;15:861-871. doi: 10.1161/CIRCINTERVENTIONS.122.012328
13. van de Hoef TP, Echavarria-Pinto M, Meuwissen M, et al. Contribution of age-related microvascular dysfunction to abnormal coronary hemodynamics in patients with ischemic heart disease. JACC Cardiovasc Interv. 2020;13:20-29. doi: 10.1016/j.jcin.2019.08.052
14. El Hajj SC, Toya T, Warisawa T, et al. Correlation of intravascular ultrasound and instantaneous wave-free ratio in patients with intermediate left main coronary artery disease. Circ Cardiovasc Interv. 2021; e009830. doi: 10.1161/CIRCINTERVENTIONS.120.009830
15. Nagaraja V, Mamas M, Mahmoudi M, et al. Change in angiogram-derived management strategy of patients with chest pain when some FFR data are available: how consistent is the effect? Cardiovasc Revasc Med. 2017;18:320-327. doi: 10.1016/j.carrev.2017.01.014
16. Andell P, Berntorp K, Christiansen EH, et al. Reclassification of treatment strategy with instantaneous wave-free ratio and fractional flow reserve: a substudy from the iFR-SWEDEHEART Trial. JACC Cardiovasc Interv. 2018;11:2084-2094. doi: 10.1016/j.jcin.2018.07.035
17. Ordiene R, Unikas R, Aldujeli A, et al. Instantaneous wave free ratio value impact on left internal mammary artery graft patency. Perfusion. 2022. Online ahead of print. doi: 10.1177/02676591221099808
18. Leone AM, Caterina AR De, Basile E, et al. Influence of the amount of myocardium subtended by a stenosis on fractional flow reserve. Circ Cardiovasc Interv. 2013:29-36. doi: 10.1161/CIRCINTERVENTIONS.112.971101
19. Härle T, Luz M, Meyer S, et al. Effect of Coronary Anatomy and hydrostatic pressure on intracoronary indices of stenosis severity. JACC Cardiovasc Interv. 2017;10:764-773. doi: 10.1016/j.jcin.2016.12.024
20. Üveges Á, Tar B, Jenei C, et al. The impact of hydrostatic pressure on the result of physiological measurements in various coronary segments. Int J Cardiovasc Imaging. 2021;37:5-14. doi: 10.1007/s10554-020-01971-w
21. Nijjer SS, Sen S, Petraco R, et al. Pre-angioplasty instantaneous wave-free ratio pullback provides virtual intervention and predicts hemodynamic outcome for serial lesions and diffuse coronary artery disease. JACC Cardiovasc Interv. 2014;7:1386–1396. doi: 10.1016/j.jcin.2014.06.015
22. Modi BN, Rahman H, Ryan M, et al. Comparison of fractional flow reserve, instantaneous wave-free ratio and a novel technique for assessing coronary arteries with serial lesions. EuroIntervention. 2021;16:577-583. doi: 10.4244/EIJ-D-19-00635
23. Mallidi J, Atreya AR, Cook J, et al. Long-term outcomes following fractional flow reserve-guided treatment of angiographically ambiguous left main coronary artery disease: a meta-analysis of prospective cohort studies. Catheter Cardiovasc Interv. 2015;86:12-18. doi: 10.1002/ccd.25894
24. Warisawa T, Cook CM, Rajkumar C, et al. Safety of revascularization deferral of left main stenosis based on instantaneous wave-free ratio evaluation. JACC Cardiovasc Interv. 2020;13:1655–1664. doi: 10.1016/j.jcin.2020.02.035
25. Lee JM, Shin ES, Nam CW, et al. Clinical outcomes according to fractional flow reserve or instantaneous wave-free ratio in deferred lesions. JACC Cardiovasc Interv. 2017;10:2502-2510. doi: 10.1016/j.jcin.2017.07.019
26. de la Torre Hernandez JM, Hernández Hernandez F, Alfonso F, et al. Prospective application of pre-defined intravascular ultrasound criteria for assessment of intermediate left main coronary artery lesions. J Am Coll Cardiol. 2011;58:351-358. doi: 10.1016/j.jacc.2011.02.064
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SUPPLEMENTAL APPENDIX
Study outline
- Study flowchart
Design of the ongoing Prospective Left Main Physiology Registry (PHYNAL) registry.
FFR = fractional flow reserve; iFR = instantaneous wave-free ratio; iFRPROX = iFR measured 5 mm distal to LM carina; LAD = left anterior descending artery; LCx = left circumflex artery; LM = left main coronary artery; V = daughter vessel
Enrollment continued until 200 patients are enrolled whose left main coronary artery (LM) treatment is being deferred. This was decided in view of an estimated number of fifty control angiographies within two years after enrollment in order to collect sufficient paired data to estimate the evolution of the angiographic and physiological parameters.
2. Subject selection
3. Observations
Primary observations
1. Percentage of LM lesions considered hemodynamically insignificant by instantaneous wave-free ratio (iFR) >0.89 but significant by fractional flow reserve (FFR) ≤0.80 or minimal lumen area (MLA) ≤6.0 mm2 as assessed by intravascular ultrasound (IVUS).
- Percentage of reclassification between significant and insignificant depending on the assessment technique used
- Percentage change of therapeutic plan, when the operator is asked to indicate his plan based on angiography, then based on iFR, FFR, and IVUS.
2. Safety endpoint. Percentage of major adverse cardiac events (MACE), defined as a composite of death, nonfatal myocardial infarction (MI), and unplanned target lesion (LM) revascularization (TLR) at 1,2, and 5-year follow-up. Percentage of MACE in the patient subpopulation where LM treatment was deferred based on iFR.
Secondary observations
Outcome related. Lesion progression at follow-up compared to baseline. If repeat coronary angiography is performed during follow-up, the evolution of the available physiological or imaging parameters can be studied: eg, evolution of iFR and FFR, plaque burden, and MLA.
Operator-indicated reasons why the revascularization strategy deviated from that suggested by the iFR result
In the deferred group, the decision to defer was consistent with the iFR in 162/177 patients (91.5%). In the remaining 15 patients the strategy was overruled for the following reasons:
- comorbidity impairing patient prognosis (n=2),
- borderline iFR+ and FFR+ and operator preference (n=4),
- iFR+/FFR- discordance and operator preference (n=1),
- iFR+/FFR- discordance with MLA > 6 mm2 and operator preference (n=3),
- iFR 0.89 in one daughter branch only (n=4),
- FFR 0.90 in one daughter branch and MLA > 6 mm2 (n=1).
In the revascularized group, the decision to revascularize was consistent with the iFR in 47/73 patients (64.4%). In the remaining 26 patients the strategy was overruled for the following reasons:
- concomitant multivessel disease (syntax score) (n=7),
- concomitant LAD disease (n=13),
- concomitant downstream disease and valvular disease (n=1),
- repetitive LM spasm and proven ischemia (n=1),
- iFR-/FFR+ discordance and operator preference (n=3),
- iFR-/FFR+ discordance and MLA < 6 mm2 (n=1)
