Original article
REC Interv Cardiol. 2021;3:175-181
Single or dual antiplatelet therapy after transcatheter aortic valve implantation. A meta-analysis of randomized controlled trials
Tratamiento antiagregante plaquetario único o doble tras implante percutáneo de válvula aórtica. Metanálisis de ensayos clínicos aleatorizados
aDepartment of Biomedical Sciences, Humanitas University, Pieve Emanuele, Milan, Italy bCardio Center, Humanitas Clinical and Research Center - IRCCS, Rozzano, Milan, Italy cServicio de Cardiología, Hospital Universitario y Politécnico La Fe, Valencia, Spain ◊J. Sanz-Sánchez, C. A. Pivato and P. P. Leone contributed equally to this work.
ABSTRACT
Introduction and objectives: Ultrasound renal denervation (uRDN) has emerged as an innovative therapeutic approach for the treatment of hypertension. However, its efficacy compared to medication remains uncertain. We aimed to assess the efficacy profile of uRDN vs sham groups focusing on its impact on daytime ambulatory blood pressure, 24-hour blood pressure, home blood pressure and office blood pressure.
Methods: We conducted a systematic search across Embase, PubMed, and Cochrane Library databases from their inception up 1 November 2024 to identify randomized controlled trials evaluating the efficacy of uRDN. Statistical analyses were performed using RevMan 6.3 software, utilizing the mean and standard deviation method to calculate mean differences with a 95% confidence interval (95%CI).
Results: A total of 4 studies were included in the final analysis with 642 patients. uRDN significantly reduced daytime ambulatory systolic blood pressure (SBP) (−5.12 mmHg; 95%CI, −6.07 to −4.16; P ≤ .00001), 24-h SBP (−4.87 mmHg; 95%CI, −6.53 to −3.21]; P ≤ .00001), office SBP (−5.03 mmHg; 95%CI, −6.27 to −3.79; P ≤ .00001) and showed a decrease in patient medication 6 months after the procedure.
Conclusions: Using uRDN leads to a lower blood pressure in patients within 2 months following the procedure. Additionally, after 6 months a significant decrease in drug use is observed.
This meta-analysis protocol was registered on PROSPERO on 7 July 2024 (CRD42024562852).
Keywords: Resistant hypertension. Ultrasound renal denervation. Systolic blood pressure. Diastolic blood pressure. Antihypertensive treatments.
RESUMEN
Introducción y objetivos: La denervación renal por ultrasonido (DRU) ha surgido como un enfoque terapéutico innovador para la hipertensión arterial resistente. Sin embargo, su eficacia en comparación con la medicación sigue siendo incierta. Nuestro objetivo fue evaluar la eficacia de la DRU frente a grupos simulados, con especial atención a su impacto sobre la presión arterial ambulatoria diurna, la presión arterial de 24 h, la presión arterial domiciliaria y la presión arterial en el consultorio.
Métodos: Se realizó una búsqueda sistemática en las bases de datos Embase, PubMed y Cochrane Library hasta el 1 de noviembre de 2024, para identificar ensayos controlados aleatorizados que evaluaran la efectividad de la DRU. Los análisis estadísticos se realizaron con el programa informático RevMan 6.3, utilizando la media y la desviación estándar para calcular las diferencias de medias con un intervalo de confianza del 95% (IC95%).
Resultados: En el análisis final se incluyeron cuatro estudios con 642 pacientes. La DRU redujo de manera significativa la presión arterial sistólica (PAS) ambulatoria diurna (−5,12 mmHg; IC95%, −6,07 a −4,16; p ≤ 0,00001), la PAS de 24 h (−4,87 mmHg; IC95%, −6,53 a −3,21; p ≤ 0,00001) y la PAS en la consulta (−5,03 mmHg; IC95%, −6,27 a −3,79; p ≤ 0,00001), y logró una disminución de la medicación de los pacientes a los 6 meses del procedimiento.
Conclusiones: El uso de DRU conlleva una reducción de la presión arterial a los 2 meses del procedimiento. Adicionalmente, transcurridos 6 meses se observó una disminución significativa del uso de medicación.
El protocolo de este metanálisis fue registrado en PROSPERO el 7 de julio de 2024 (CRD42024562852).
Palabras clave: Hipertensión resistente. Denervación renal por ultrasonido. Presión arterial sistólica. Presión arterial diastólica. Tratamiento antihipertensivo.
Abbreviations
BP: blood pressure. DBP: diastolic blood pressure. SBP: systolic blood pressure. RCT: randomized controlled trial. uRDN: ultrasound renal denervation.
INTRODUCTION
Hypertension is highly prevalent worldwide and well recognized as a major risk factor for cardiovascular, cerebrovascular, and renal complications.1 Despite the availability of numerous antihypertensive drugs that effectively mitigate hypertension-related organ damage,1,2 a substantial proportion of patients fail to attain adequate blood pressure (BP) control,3 which may be attributed to factors such as medication non-adherence or the presence of resistant hypertension,4,5 which is defined as the presence of uncontrolled BP of, at least, 130/80 mmHg despite the simultaneous prescription of, at least, 3 or 4 antihypertensive drugs of different classes, or controlled BP despite the prescription of, at least, 4 drugs, at the maximum tolerated doses, including a diuretic.6 The pathophysiology of hypertension is intricate and includes a diverse array of mechanisms, with sympathetic overdrive emerging as a pertinent factor in all forms of hypertension.7 Consequently, novel therapeutic approaches have emerged, including renal denervation (RDN), which aims to decrease renal sympathetic activity thereby reducing BP. RDN has drawn considerable attention as a guideline-recommended BP lowering treatment along with lifestyle changes and pharmacotherapy for patients with resistant hypertension.8,9 Recently, there has been growing consensus that RDN should also be considered for individuals whose hypertension is due to no therapeutic adherence.10-12 Early randomized controlled clinical trials yielded inconsistent findings on the efficacy profile of the intervention, with a substantial proportion of patients failing to respond across the trials.13,14 Potential explanations for the heterogeneous results include insufficient operator experience using the Symplicity Flex catheter (Medtronic, United States), the study participants’ baseline characteristics, and changes of antihypertensive medication.15 Subsequently, sham-controlled trials with better study designs, catheter technologies and procedural techniques have improved the BP-lowering safety and efficacy profile of RDN.16-18 Currently, various catheter systems are used for RDN, utilizing different technologies, such as radiofrequency-based systems like Symplicity Spyral (Medtronic, United States). Ultrasound-based catheters have also been developed, such as the Paradise (Recor Medical, United States), whose efficacy has been evaluated in multiple studies. Finally, there is a system based on alcohol-mediated RDN.19 Recently, the U.S. Food and Drug Administration (FDA) approved Medtronic Symplicity Spyral and Recor Paradise system as adjuvant therapies for the treatment of hypertension.20
The efficacy of the latter was evaluated in a multicenter, randomized, blinded and sham-controlled trial. Subsequently, it was determined in the REQUIRE RADIANCE-HTN SOLO,16 RADIANCE HTN TRIO17 and RADIANCE II,18 and REQUIRE21 trials. Results were heterogeneous between the RADIANCE and REQUIRE trials, which had limitations that may account for the varied results.10 Finally, uRDN was concluded to be safe for the treatment of hypertension, even in patients with resistant hypertension and poor medical adherence.19 The aim of this study is to conduct a systematic review and a meta-analysis to examine the antihypertensive efficacy of uRDN in patients with hypertension vs a sham group treatment.
METHODS
We conducted a systematic review and meta-analysis which strictly followed the clinical practice guidelines established by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement.22 Methodological procedures were conducted in full compliance with the Cochrane Handbook of Systematic Reviews and Meta-Analysis of Interventions. This meta-analysis protocol was registered on PROSPERO 7 July 2024, under protocol ID: CRD42024562852.
Criteria of the included studies
Inclusion criteria were established to identify relevant studies: patients with resistant hypertension and randomized controlled trials (RCTs) comparing uRDN with sham groups, which did not undergo uRDN; RCTs reporting office, daytime ambulatory, home and 24-h ambulatory BP changes from baseline were included. We excluded those underreporting, at least, 1 of the following outcomes of interest: changes in BP between baseline and, at least, a 2-month follow up. In addition, we excluded non-English publications, case-control studies, case reports, single arm studies, letters to the editors, basic science research, meta-analyses, and review articles.
Literature search strategy
We conducted a comprehensive search across PubMed, EMBASE, and COCHRANE, from their inception until 1 November 2024. Keywords and free-text terms were used to explore literature on hypertension, renal denervation, and ultrasound ablation. Detailed search information for each database is provided in the Search strategy section of the supplementary data.
Screening of literature search strategy
Initially, a comprehensive database search was conducted to compile all relevant records. Duplicate entries were, then, manually removed using Zotero software. Afterwards, references were screened by title and abstract. When necessary, a full-text review was performed to ensure relevance and accuracy. Two authors (C. J. Palomino-Ojeda and L. H. García-Mena) independently assessed each the inclusion and quality of each article. Discrepancies were resolved by a third author (J. M. Guerrero-Hernández). Additionally, references cited in the included studies were scrutinized and included if they fulfilled the eligibility criteria.
Data extraction
Data extraction was conducted using Excel spreadsheets to record the following information: a) baseline characteristics of the study population, b) summaries detailing the characteristics of the included studies, c) outcome measures, and d) domains evaluated for quality assessment.
Assessing the risk of bias
Randomized controlled trials were assessed using Version 2 of the Cochrane risk-of-bias tool for randomized trials (RoB 2)22,23 from the Cochrane Handbook of Systematic Reviews of Interventions. Our analysis included a funnel plot for the primary endpoint daytime ambulatory systolic blood pressure (SBP) shown in figure 1 of the supplementary data.
Figure 1. PRISMA flow diagram. RDN, renal denervation.
Outcome measures
BP changes were assessed by comparing baseline values and follow-up measurements taken, at least, 2 months later. The mean difference was analyzed using the mean and standard deviation.
Data analysis
The efficacy profile of uRDN vs the sham control was analyzed using continuous data to calculate the mean difference with its corresponding 95% confidence interval (95%CI).24 This analysis assessed BP changes across groups with an, at least, 2-month follow-up while evaluating their mean difference.
Furthermore, an examination was conducted to discern any variation among office BP, ambulatory daytime BP, 24-h ambulatory BP, nighttime ambulatory BP, and home BP outcomes in trials that reported these results. This was achieved by computing the mean and its associated standard deviation for the difference between the 2 outcomes. The validated Campbell calculator was used to convert the measures of dispersion from the outcomes in the REQUIRE trial for data analysis.24 The level of heterogeneity was assessed using the I2 statistic.
Sensitivity analyses were conducted using a random effects model to account for variability among studies.25 Subgroup analyses were predefined for first and second-generation RDN trials, with tests for interaction for the primary endpoint.
Assessment of heterogeneity
Heterogeneity among the included studies was assessed using Cochran’s Q statistic. Additionally, the I2 statistic was used to quantify the proportion of total variation attributed to heterogeneity, with values > 50% indicating high heterogeneity. All statistical analyses (including the calculation of standardized mean difference, relative risk, and mean difference) were performed using RevMan 6.3. software.22
RESULTS
Study selection
A total of 448 studies were identified across database searches. A total of 392 studies were screened after removing duplicate studies, 388 of which were excluded due to single-arm study (n = 6); publication in a language different than English (n = 1); case-control or case report studies and literature review (n = 140); basic scientific research (n = 24); editorial letter (n = 8); different type of RDN studies (n = 83); studies with ≤ 10 participants (n = 6); and does not compare intervention of interest (n = 120). Finally, 4 studies meet all inclusion criteria and were eligible for analysis. An analysis of 642 patients from the 4 selected articles was conducted as they met the inclusion criteria. The PRISMA flow diagram of the study selection process is shown in figure 1.
Study characteristics
The studies included in our analysis included a total of 4 RCTs published from 2018 through 2023.16-18,21 All studies used uRDN and a sham control group. Two studies were performed in the United States/Europe,16,17 1 study only in the United States18 and the rest in Japan and South Korea.21 The baseline characteristics of the included studies were analyzed and summarized in table 1. Characteristics of the entire patient population are shown in table 2.
Table 1. Baseline characteristics and following intervention of the included studies population.
| Reference | ||||||||
|---|---|---|---|---|---|---|---|---|
| RADIANCE HTN SOLO 201816 | RADIANCE-HTN TRIO 202117 | REQUIRE 202221 | RADIANCE II 202318 | |||||
| Group | uRDN | SHAM control | uRDN | SHAM control | uRDN | SHAM control | uRDN | SHAM control |
| N | 74 | 72 | 69 | 67 | 69 | 67 | 150 | 74 |
| Gender, female | 28 | 33 | 13 | 14 | 21 | 14 | 47 | 17 |
| Gender, male | 46 | 39 | 56 | 53 | 48 | 53 | 103 | 57 |
| Age, years, mean (SD) | 54.4 (10·2) | 53.8 (10·0) | 52.3 (7.5) | 52,8 (9.1) | 50.7 (11.4) | 55.6 (12.1) | 55.1 (9.9) | 54.9 (7.9) |
| Body mass index, mean (SD) | 29.9 (5.9) | 29.9 (5.0) | 32.8 (5.7) | 32.6 (5.4) | 29.5 (5.5) | 28.4 (4.5) | 30.1 (5.2) | 30.6 (5.2) |
| Abdominal obesity | 41 | 44 | 54 | 55 | – | – | 90 | 46 |
| GFR mL/min/1.73 m2 | 84.7 (16.2) | 83.2 (16.1) | 86 (25.2) | 82.2 (19.2) | 74.2 (16.2) | 69.6 (17.1) | 81.4 (14.4) | 82.3 (14.9) |
| GFR < 60 mL/min/1.73 m2 | 1 | 3 | 8 | 7 | 15 | 18 | 7 | 3 |
| Type 2 diabetes mellitus | 2 | 5 | 21 | 17 | 18 | 20 | 9 | 5 |
| Cardiovascular disease | – | – | 8 | 9 | 9 | 9 | 1 | – |
| Systolic BP at office screening, mm Hg | 142.6 (14.7) | 144.6 (15.9) | 161.9 (15.5) | 163.6 (16.8) | 157.6 (19.5) | 160.4 (14.9) | 155.8 (11.1) | 154.3 (10.6) |
| Diastolic BP at office screening, mm Hg | 92.3 (10.1) | Mean 93.6 (8.3) | 105.1 (11.6) | 103.3 (12.7) | 97.7 (16.6) | 95.3 (14.2) | 101.3 (6.7) | 99.1 (5.6) |
| HR at office screening, beats/min | 72 (12.1) | 72.6 (12.3) | 74.5 (11) | 77.6 (12.9) | 75.3 (10.8) | 71.5 (12.8) | 74.1 (12.0) | 73.6 (11.9) |
| Number of antihypertensive drugs at screening | 1: 33 2: 28 3: 1 | 1: 28 2: 27 3: 1 | 3: 27 4: 22 5: 20 | 3: 28 4: 24 5: 15 | 3: 32 4: 20 5: 17 | 3: 29 4: 23 5: 15 | 1: 52 2: 44 > 2: 0 | 1: 25 2: 25 > 2: 1 |
| Procedural time | 72.3 (23.3) | 38.2 (12.6) | 83.66 (22.71) | 41.33 (12.87) | 86.7 (54.0) | 40.2 (11.6) | 76.7 (25.2) | 43.9 (16.6) |
| Office systolic blood pressure at 2 months | 143.7 (16.7) | 149.7 (17.4) | 147.1 (20.3) | 152.1 (22) | – | – | 145.8 (15.9) | 151.2 (16.4) |
| Office diastolic blood pressure at 2 months | 94.2 (10.1) | 98 (10) | 96.6 (13.9) | 98.7 (13.8) | – | – | 96.0 (10.2) | 98.1 (11.2) |
| Daytime ambulatory systolic BP at 2 months | 141.9 (11.9) | 147.9 (13.3) | 141.0 (16.1) | 146.3 (18.8) | – | – | 135.6 (13) | 142.9 (10.5) |
| Daytime ambulatory diastolic BP at 2 months | 87.9 (7.1) | 90.9 (7.9) | 88.5 (11.6) | 90.7 (12.2) | – | – | 83.1 (7.6) | 87.0 (6.3) |
| 24-hour systolic BP at 2 months | 135.6 (11.4) | 140.7 (11.8) | 135.2 (16.0) | 140.5 (18.7) | – | – | 135.6 (13.0) | 142.9 (10.5) |
| 24-hour diastolic BP at 2 months | 83 (6.8) | 85.7 (7.1) | 83.6 (10.9) | 85.8 (12) | – | – | 83.1 (7.6) | 87.0 (6.3) |
| Home systolic BP at 2 months | 139.4 (11.7) | 146.6 (15.4) | 144.6 (18.2) | 149.9 (18.9) | – | – | 143.4 (12.3) | 148.8 (12.3) |
| Home diastolic BP at 2 months | 89.9 (7.8) | 93.3 (8.5) | 93.2 (14.7) | 96 (12.8) | – | – | 92.7 (7.4) | 95.5 (8.1) |
| Nighttime ambulatory systolic BP at 2 months | 125.6 (12.8) | 129.4 (13.1) | 126.3 (18.4) | 76.2 (12.2) | – | – | 125.5 (15.0) | 132.4 (12.2) |
| Nighttime ambulatory diastolic BP at 2 months | 74.8 (8.5) | 77.3 (8.5) | 131.9 (20.9) | 78.4 (13.2) | – | – | 75.1 (9.7) | 79.6 (7.5) |
|
BP, blood pressure; GFR, glomerular filtration rate; SD, standard deviation; uRDN, ultrasound renal denervation. |
||||||||
Table 2. Summary of included studies
| Study ID | Country | Study design | Total population | Compare interventions | Key findings |
|---|---|---|---|---|---|
| United States/Europe | RCT | 146 | uRDN vs SHAM control | Renal denervation resulted in a greater reduction in daytime ambulatory systolic blood pressure compared with a sham procedure | |
| United States/Europe | RCT | 136 | uRDN vs SHAM control | Renal denervation reduced daytime ambulatory systolic blood pressure more than the sham procedure | |
| Japan and South Korea | RCT | 136 | uRDN vs SHAM control | Is the first trial of ultrasound renal denervation in Asian patients with hypertension on antihypertensive therapy | |
| The study did not show a significant difference in ambulatory blood pressure reductions in treated patients with resistant hypertension | |||||
| United States | RCT | 224 | uRDN vs SHAM control | The primary efficacy outcome was the mean change in daytime ambulatory SBP at 2 months | |
| No major adverse events were reported in either group | |||||
|
RCT: randomized controlled trial; SBP, systolic blood pressure; uRDN: ultrasound renal denervation. |
|||||
In the analysis of 642 patients, the mean age was 54.15 years ± 9.95, 70.8% were men, and the mean body mass index was estimated at 30 kg/m2 ± 5.3. Regarding comorbidities, 15.1% had type 2 diabetes mellitus, and 5.6%, cardiovascular disease. The mean glomerular filtration rate (GFR) was estimated at 82.25 mL/min/1.73 m2 ± 16.2. In addition, 9.6% of patients had GFR levels < 60 mL/min/1.73 m2. Of note, eligibility criteria in all trials include an estimated GFR > 40 mL/min/1.73 m2. Two studies— the RADIANCE-HTN SOLO and the RADIANCE II—included patients on 1 to 3 antihypertensive drugs and were designed as “Off Med” studies, meaning patients underwent a washout period with no antihypertensive treatment for 4 weeks in the RADIANCE-HTN SOLO and 8 weeks in the RADIANCE II. Additionally, patients who experienced complications such as high BP were given antihypertensive escape therapy.26 On the other hand, the RADIANCE-HTN TRIO and REQUIRE trials included patients on 3 to 5 antihypertensive drugs and evaluated the uRDN in patients on concomitant antihypertensive therapy. However, only the RADIANCE-HTN TRIO trial standardized antihypertensive treatment over a 4-week regimen with a fixed-dose of 3 drugs in a single pill including amlodipine 10 mg; valsartan 160 mg (or olmesartan 40 mg); and hydrochlorothiazide 25 mg. Additionally, treatment adherence was assessed by mass spectrometry.21,27,28 Enrollment criteria were comparable across the analyzed studies. Similarly, exclusion criteria were consistent in all studies; however, the RADIANCE trials additionally excluded patients with anatomical variations or alterations in renal artery anatomy, as detected on renal computed tomography or magnetic resonance angiography.27 In all studies, patients were blinded prior to the uRDN procedure. Furthermore, in all RADIANCE trials, blinding was implemented after the washout period or after the patients completed the fixed-dose treatment.18,26,27
Daytime ambulatory blood pressure
Patients treated with uRDN for up to 2 months experience a significant reduction of −5.12 mmHg (95%CI, −6.07 to −4.17; P < .00001); I2 = 2%) in daytime ambulatory SBP vs the sham group. Similarly, ambulatory diastolic blood pressure (DBP) dropped down to −2.82 mmHg (95%CI, −3.43 to −2.21; P < .00001; I2 = 0%) in patients with uRDN vs the sham group (figure 2A).
Figure 2. Meta-analysis of the effect of uRDN on blood pressure va a sham control. A: difference in daytime ambulatory BP up to 2 months; B: difference in 24-hour BP up to 2 months; C: difference in office BP up to 2 months; and D: difference in home BP up to 2 months. Forest plots showing the mean difference and SD from random assignments between the uRDN and sham control groups. 95%CI, 95% confidence interval; BP, blood pressure; SD, standard deviation; uRDN, ultrasound renal denervation. The bibliographical references mentioned in this figure correspond to Azizi et al.,16-18 and Kario et al.21
24-hour ambulatory blood pressure
24-h BP was evaluated up to 2 months after uRDN. Analysis of SBP showed a significant reduction of −4.87 mmHg (95%CI, −6.53 to −3.21; P < .00001; I2 = 42%). Meanwhile, 24-h DBP dropped down to −2.55 mmHg (95%CI, −3.83 to −1.26; P < .00001; I2 = 62%) in patients on uRDN (figure 2B).
Office blood pressure
SBP dropped down to −5.03 mmHg after 2 months (95%CI, −6.27 to −3.79; P < .00001; I2 = 0%) in uRDN patients. DBP showed a significant decrease of −3.68 mmHg (95%CI, −4.57 to −2.78; P < .00001; I2 = 31%) with the uRDN intervention (figure 2C).
Home blood pressure
Analysis of home BP after 2 months showed a decrease in SBP of −5.47 mmHg (95%CI, −8.08 to −2.85; P < .0001; I2 = 75%), while DBP dropped down to −3.19 mmHg (95%CI, −4.63 to −1.75; P < .0001; I2 = 69%) in patients on uRDN (figure 2D).
Nighttime blood pressure
Nighttime BP was evaluated at the 2-month follow-up. We found that SBP dropped down to −3.99 mmHg (95%CI, −7.00 to −0.99; P = 0.009; I2 = 70%), while DBP dropped down to −2.30 mmHg (95%CI −4.03 to −0.56; P = .01; I2 = 64%) in patients on uRDN (figure 2 of the supplementary data).
Drugs 6 months after uRDN
Patient drugs 6 months after uRDN were only reported in the RADIANCE-HTN SOLO and RADIANCE-HTN TRIO clinical trials. Data analysis revealed that uRDN leads to using fewer antihypertensive drugs by −0.52 (95%CI, −0.91 to −0.13; P = 0.009; I2 = 69%) vs the sham control group (figure 3).
Figure 3. Patients on uRDN used less antihypertensive medication prescribed 6 months after the procedure vs the sham group. 95%CI, 95% confidence interval; BP, blood pressure; SD, standard deviation; uRDN, ultrasound renal denervation. The bibliographical references mentioned in this figure correspond to Azizi et al.16 and Azizi et al.17
Risk of bias assessment
Among the 4 studies included, the risk of bias remained consistent at a moderate level, which was attributed to the inability to blind the interventional cardiologist conducting the uRDN, although outcome assessors were blinded to the interventions performed. Studies were categorized as having moderate risk16-18,21 (table 3). Data on risk of bias can be found in table 1 of the supplementary data. In addition, the funnel plot of daytime ambulatory SBP (figure 1 of the supplementary data) showed a slight asymmetry, as points tend to concentrate towards the left side of the combined effect, which could suggest a possible publication bias. In addition, the points closer to the vertex represent studies with lower standard error due to a larger sample size. The heterogeneity of the funnel plot reflects variations in effects across studies. Plot points are within the funnel lines, but one of them towards the lower right seems further away from the rest, which could indicate a possible outlier or methodological or population differences.29
Table 3. Risk of bias summary for randomized studies (RoB 2)
| Trials | Risk of bias domains | |||||
|---|---|---|---|---|---|---|
| D1 | D2 | D3 | D4 | D5 | Overall | |
| RADIANCE HTN SOLO16 | Low | Low | Low | Low | Low | Low |
| RADIANCE HTN TRIO17 | Low | Low | Low | Low | Low | Low |
| REQUIRE21 | Low | Low | Low | Low | Low | Low |
| RADIANCE II18 | Some concerns | Low | Low | Low | Low | Some concerns |
|
D1: bias arising from the randomization process. D2: bias due to deviation from intended intervention. D3: bias due to missing outcome data. D4: bias in outcome measurement. D5: bias in selection of the reported result. |
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DISCUSSION
This meta-analysis includes data from 4 randomized controlled trials that evaluated the efficacy profile of uRDN in patients with true resistant hypertension and off-medication hypertensive patients vs a sham group. Antihypertensive efficacy was evaluated across different clinical settings such as 24-h ambulatory BP, home BP, office BP, and daytime BP. Our results demonstrated significant BP-lowering efficacy at the 2-month follow-up vs the sham procedure. Furthermore, at the 6-month follow-up, fewer antihypertensive drugs were prescribed to patients on uRDN vs those from the sham group. These results support the use of uRDN as an adjuvant therapy for hypertension and as a valuable option for reducing BP as well as the number of antihypertensive drugs.
Previous studies have demonstrated the safety profile of RDN for the treatment of resistant hypertension, such as the first-generation SIMPLICITY HTN trials.30 However, the SIMPLICITY HTN-3 study showed no differences in the 24-h BP reduction vs the sham group, casting doubts on the benefits of RDN.14 Subsequently, new catheters were developed for performing RDN, and standardized criteria were established for conducting RDN trials with a sham group.12,19 Currently, uRDN has emerged as a novel option as an adjuvant therapy treatment of hypertension. It is based on catheter systems, such as the TIVUS and Paradise systems, which utilize ultrasound energy for the thermal ablation of afferent and efferent renal nerves.19,31
Our results demonstrated a reduction in both SBP and DBP at the 2-month follow-up, with a more pronounced effect on SBP in patients on uRDN vs the sham control group. We observed a reduction of −5.12 mmHg in ambulatory SBP, −4.87 mmHg in 24-h SBP, −5.03 mmHg in office SBP, and −5.47 mmHg in home SBP. These findings are particularly relevant since SBP has turned out to be a strong predictor of future cardiovascular events and mortality, regardless of age in adults.32 The CI values for home BPS had the widest range. Furthermore, the RADIANCE HTN-SOLO trial demonstrated a wide CI in both office and home SBP. This observation is an opportunity for future trials to focus on patient training to standardize home BP measurement since day-to-day home BP has been proposed as a potential predictor of cardiovascular disease.33
Although the observed BP reduction may seem minimal and lack significant clinical relevance, it is important to note that these findings reflect the first 2 months of follow-up after uRDN initiation and literature reports that uRDN has a sustained long-term effect on lowering BP values. For example, the HTN RADIANCE-SOLO trial demonstrated that at the 36-month follow-up, office BP decreased 18/11 ± 15/9 mmHg.34 Related to this, previous studies have demonstrated that a 10 mmHg reduction in SBP is associated with a decrease in the relative risk (RR) of major cardiovascular events (RR, 0.80; 95%CI, 0.77-0.83), coronary heart disease (RR, 0.83; 95%CI, 0.78-0.88), stroke (RR, 0.73; 95%CI, 0.68-0.77), heart failure (RR, 0.72; 95%CI, 0.67-0.78), and a 13% reduction in all-cause mortality rate (RR, 0.87; 95%CI 0.84-0.91).2 However, it has recently been reported that even a 5 mmHg decrease is beneficial to reduce the risk of major cardiovascular events, estimating a hazard ratio (HR) of 0.91 (95%CI, 0.89-0.94) for individuals without previous cardiovascular disease and a HR of 0.89 (95%CI, 0.86-0.92) for those with previous cardiovascular disease.1 In addition, reduction of preventable major cardiovascular events by treating hypertension has a positive economic impact in reducing hospitalization expenses due to complications such as heart attack or stroke.35 Hypertension is a prevalent global health concern, and effective BP control is achieved in only 21% of patients.36 In the United States, individuals with hypertension are estimated to incur an additional $2500 to $3000 in annual expenses vs those without hypertension. Maintaining normal BP not only benefits patients but also supports the economic well-being of the entire health care system.37 In fact, studies evaluating the cost-effectiveness of long-term use of radiofrequency RDN have been conducted in the United States and the United Kingdom concluding that this procedure represents a cost-effective option for the treatment of uncontrolled and resistant hypertension, as its sustained BP-lowering effect favors the reduction of cardiovascular morbidity and mortality.38 Similarly, in Spain, an estimate was made of the impact of radiofrequency RDN on quality-adjusted life years, cardiac events, and patient-related lifetime costs. Radiofrequency RDN was found to reduce the risk of stroke (RR, 0.80), myocardial infarction (RR, 0.88), and heart failure (RR, 0.72) throughout a 10-year period, resulting in improved health outcomes and long-term cost savings. Results presented indicate that radiofrequency RDN is a cost-effective therapeutic option that should be taken into consideration in patients with uncontrolled hypertension, including resistant hypertension.39
In addition to the reduction in BP and the positive cost-effectiveness of uRDN, radiofrequency RDN has been demonstrated to be a safe procedure for the patients. The clinical trials that analyzed this meta-analysis found no safety differences between the treated and sham groups. Furthermore, few postoperative adverse events were reported. Most complications were associated with back pain, which was effectively and uneventfully managed.16-18,21 The long-term safety profile of the procedure has been consistently reported, with no adverse effects being reported from uRDN observed at the 1, 3-, and even 8-year follow-up.34,40,41
Our findings also demonstrated that, at the 6-month follow-up, patients on uRDN used fewer prescribed antihypertensive drugs, which suggests that treatment may potentially improve patient outcomes. However, this outcome was only evaluated in the RADIANCE HTN-TRIO and RADIANCE HTN-SOLO trials. In addition, at the 3-year follow-up the RADIANCE HTN-TRIO reported no differences in the number of drugs used by patients initially identified with uncontrolled hypertension, although they decreased office SBP by 10.8 mmHg.34 This is particularly noteworthy as non-adherence to therapy is a significant contributing factor to uncontrolled BP.42 However, the results suggest that the greatest benefit is observed in the maintenance of low BP levels rather than in the decrease in the number of antihypertensive drugs prescribed.
Of note, the I2 value of the outcomes evaluated showed that daytime SBP and DBP had low heterogeneity, while the 24-h SBP and DBP values had moderate-to-high heterogeneity. On the other hand, office SBP and DBP had low-to-moderate heterogeneity. Finally, home SBP and DBP, as well as nighttime SBP and DBP and drug intake had high heterogeneity. Variations in heterogeneity do not necessarily indicate that the results are not useful;43 possibly, the differences in the heterogeneity of the outcomes assessed is due to differences in the methodology of the studies contemplated in this meta-analysis, which will be discussed below.
Our analysis included the REQUIRE trial, which has certain limitations, such as the absence of a blinded design, a non-standardized uRDN intervention, and dose titration. These factors may have introduced bias, potentially explaining the lack of differences observed between the uRDN and sham groups. In addition, the inclusion criteria of the study did not consider the presence of anatomical variations in the renal arteries vs the RADIANCE trials in which an exclusion criterion is the presence of anatomical variations in renal arteries. This factor, along with therapeutic adherence, could impact the BP reduction results.21,28,44 Based on this perspective, the European Society of Cardiology (ESC) Council on Hypertension and the European Association of Percutaneous Cardiovascular Interventions (EAPCI) have established the characteristics that must be met by studies evaluating RDN with a sham control group to be considered as high quality: a) multicenter design; b) blinding of patients; c) ambulatory BP change as the primary enpoint; d) use of second-generation RDN systems.10 In this context, RADIANCE clinical trials are characterized by a rigorous methodological protocol, which required a 4- or 8-week stabilization of pharmacological therapy prior to randomization to either uRDN or a sham procedure.45,46 Furthermore, RADIANCE trials monitored therapeutic adherence and were designed to assess the effect of uRDN with and without antihypertensive treatment, minimizing the confounding effects.28,47
A key long-term challenge of the RADIANCE trials is to demonstrate sustained BP-lowering effects vs sham groups. Follow-up studies show that patients from the sham group required higher doses of antihypertensive drugs, while those on uRDN used fewer drugs. Although BP differences across groups decreased throughout time, uRDN patients consistently needed fewer prescriptions.26,27
Results from the RADIANCE trials demonstrate the efficacy profile of uRDN for the treatment of resistant hypertension and patients with poor therapeutic adherence, as observed in the off-study population. Additionally, the REQUIRE trial highlights the potential role of anatomical variations in determining patient suitability for uRDN, underscoring the importance of selecting appropriate criteria for patient selection. In addition, RDN has proven to be a safe procedure with a positive long-term cost-benefit ratio. The key question on uRDN may be: Which patient group would benefit most from uRDN, considering anatomical factors and therapeutic adherence?
Study limitations
To make the most out of the study results, it is important to consider its limitations: a) we only analyzed data from trials that used uRDN, which reduces the size of the population; b) data availability from the studies considered covered a short follow-up period, which limits the ability to determine the long-term antihypertensive efficacy of uRDN; c) differences in supervised drug adherence across the methodological designs limit their applicability to real-world settings; d) Since RCTs included patients with true resistant hypertension and off-med hypertension, the heterogeneous population limits the generalizability of the results to a specific hypertension subtype; and e) The funnel plot showed asymmetry, suggesting a possible publication bias, although results should be interpreted with caution because the funnel plot also indicates that there is a limited amount of data.
CONCLUSIONS
This meta-analysis demonstrates that uRDN treatment effectively reduces both SBP and DBP across various contexts, including 24-h, ambulatory, home and office BP at the initial 2-month follow-up in hypertensive patients (figure 4). Additionally, uRDN was associated with reduced antihypertensive drug use 6 months after the procedure. However, further research is needed to assess its long-term effects and identify the patient groups who may benefit the most.
Figure 4. Central illustration. Summary of the effect on the decrease in systolic and diastolic blood pressure in patients on uRDN compared with patients who received the sham procedure at the 2 months postoperative follow-up. uRDN, ultrasound renal denervation.
FUNDING
This manuscript did not receive financial support from any institution or funding agency for its preparation.
ETHICAL CONSIDERATIONS
The present meta-analysis was conducted based on previously published studies. As the study involved secondary data analysis, no new data was collected from human participants or animals, and the use of SAGER guidelines does not apply to this study. Therefore, ethical approval was deemed unnecessary. All included studies were reviewed in full compliance with ethical guidelines set forth by the respective institutions where the original studies were conducted. All authors state that the data used in this study were obtained exclusively from publicly accessible sources, and no confidential or proprietary information was utilized without appropriate authorization.
STATEMENT ON THE USE OF ARTIFICIAL INTELLIGENCE
During the preparation of this work the authors used ChatGPT-4o to review the document syntaxis and grammar. After using this tool/service, the authors reviewed and edited the content as needed and took full responsibility for the content of the published article.
AUTHORS’ CONTRIBUTIONS
J.M. Guerrero-Hernández: conceptualization, formal analysis, drafting, review and editing; C. J. Palomino-Ojeda: methodology, investigation, drafting, review and editing; L. H. García-Mena: methodology, formal analysis, writing, review and editing; Ó.Á. Vedia-Cruz: investigation; J. L. Maldonado-García: drafting, review and editing; I. J. Núñez-Gil: investigation, supervision and review; J. A. García-Donaire: review and supervision.
CONFLICTS OF INTEREST
I. J. Núñez-Gil served as a consultant for Medtronic and Recor Medical in the denervation field. J. A. García-Donaire served as consultant for Medtronic and Recor Medical in the denervation field. The rest of the authors declared no conflicts of interest whatsoever.
WHAT IS KNOWN ABOUT THE TOPIC?
- uRDN has emerged as a safe option for the treatment of resistant hypertension, and previous studies have observed greater efficacy in lowering BP vs a sham group.
WHAT DOES THIS STUDY ADD?
- Our results demonstrate that uRDN decreased 24-h, office, daytime and home SBP and DBP within the first 2 months after the procedural follow-up vs a sham group, and a decrease in the number of antihypertensive drugs at the 6-month follow-up. However, further long-term studies are required to confirm the benefit of uRDN.
SUPPLEMENTARY DATA
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ABSTRACT
Introduction and objectives: The prevalence of atrial fibrillation and the number of patients experiencing ischemic strokes despite oral anticoagulation (OAC) are both on the rise, which presents a significant challenge due to the absence of clear and uniform treatment recommendations for these patients. To date, there is no formal combination merging into a high anticoagulant efficacy profile while keeping a low bleeding risk. Transcatheter left atrial appendage occlusion (LAAO) in combination with OAC might provide a balance between safety and efficacy. The objective of this study is to evaluate whether, in ischemic stroke patients, despite anticoagulation, the combination of LAAO plus long-term anticoagulation—direct oral anticoagulants or vitamin K antagonist when indicated—is associated with a lower rate of recurrent cardioembolic events at 12 months vs the optimal medical therapy recommended by the neurologist.
Methods: A total of 380 patients with ischemic stroke despite OAC will be included. Patients will be randomized on a 1:1 ratio to receive the optimal medical therapy (control) or the combination of LAAO plus OAC or OAC. The primary endpoint of the study will be the occurrence of a cardioembolic event—ischemic stroke or arterial peripheral embolism—within the first 12 months after inclusion.
Conclusions: This study is one of the first randomized clinical trials to compare the LAAO plus OAC combination and optimal medical therapy in patients who have experienced ischemic strokes despite being on OAC. If results confirm the superiority of LAAO plus OAC, it could lead to a paradigm shift in treatment guidelines for these patients.
Keywords: Left atrial appendage occlusion. Recurrent stroke. Oral anticoagulation. Direct oral anticoagulation.
RESUMEN
Introducción y objetivos: La prevalencia de la fibrilación auricular y el número de pacientes que sufren ictus isquémicos a pesar de recibir anticoagulación oral (ACO) están aumentando. Este incremento representa un importante desafío debido a la ausencia de recomendaciones claras y uniformes sobre el tratamiento de estos pacientes. Hasta la fecha no existe una combinación que logre una alta eficacia anticoagulante manteniendo un bajo riesgo de hemorragia. La oclusión percutánea de la orejuela izquierda (OI) añadida a la ACO podría ofrecer un equilibrio entre eficacia y seguridad. El objetivo es evaluar si, en pacientes con ictus isquémico a pesar de recibir ACO, la combinación de oclusión de la OI y ACO a largo plazo (anticoagulantes orales de acción directa o bien antagonista de la vitamina K, cuando esté indicado) se asocia con una menor incidencia de eventos cardioembólicos recurrentes a los 12 meses, en comparación con el mejor tratamiento médico propuesto por el neurólogo.
Métodos: Se incluirán 380 pacientes con ictus isquémico a pesar de recibir ACO. Los pacientes se asignarán al azar en una proporción 1:1 al mejor tratamiento médico (grupo control) o a la combinación de oclusión de OI y ACO. El objetivo principal del estudio será la ocurrencia de un evento cardioembólico (ictus isquémico o embolia arterial periférica) dentro de los primeros 12 meses tras la inclusión.
Conclusiones: Este estudio es uno de los primeros ensayos clínicos aleatorizados que compara la combinación de oclusión de OI más ACO con el tratamiento médico óptimo en pacientes que han sufrido un ictus isquémico a pesar de estar recibiendo ACO. Si los resultados confirman la superioridad de la oclusión de OI más ACO, podría significar un cambio de paradigma en las guías de tratamiento para estos pacientes.
Palabras clave: Oclusión de la orejuela. Ictus recurrente. Anticoagulación oral. Anticoagulación oral directa.
Abbreviations AF: atrial fibrillation. DOAC: direct oral anticoagulants. LAA: left atrial appendage. LAAO: left atrial appendage occlusion. OAC: oral anticoagulation. VKA: Vitamin K antagonist.
INTRODUCTION
Atrial fibrillation (AF) increases with age and raises the risk of ischemic stroke, systemic embolism, and death, with stroke or transient ischemic attack (TIA) often being the initial presentation. 1,2 Oral anticoagulation (OAC) with direct OAC (DOAC) or vitamin K antagonists (VKA) is effective in reducing these risks.1,2 However, recent randomized clinical trials suggest a 1.0%–1.5% annual stroke rate in AF patients on OAC.3-5 Up to one-third of AF patients who develop ischemic stroke are on OAC at stroke onset, with 8.8% up to 20% being on DOAC,6-9 which poses a significant challenge for secondary prevention purpose. Additionally, these patients tend to be older and have more comorbidities, sometimes requiring off-label low-dose DOAC.7 The use of off-label low-dose DOAC, atrial enlargement, and increased AF burden further raises the risk of stroke despite OAC therapy, suggesting a possible association with advanced cardiac disease or inadequate anticoagulation.10,11
After an ischemic stroke—despite OAC—there are no clear guidelines on the management of OAC, such as switching drugs, targeting a higher international normalized ratio (INR) with AVK, or adding antiplatelet agents. Network meta-analyses show no differences in stroke risk across different DOAC. Observational studies also found no benefits in changing OAC, suggesting additional stroke mechanisms.7 Stroke workups should identify alternative embolisms or sources of thrombosis, such as large-vessel atherosclerosis or small-vessel disease, which may need specific antithrombotic strategies.7,9,10,12 Although adding antiplatelets may reduce platelet activation, it is associated with a higher bleeding risk.13 Therefore, the best secondary prevention for AF patients after stroke despite OAC remains unclear, highlighting the need for new treatments, including novel non-pharmacological approaches such as left atrial appendage occlusion (LAAO).
Recent data from the STR-OAC cohort—an international LAAO registry—showed promising findings in AF patients with stroke despite OAC. In this study, the LAAO cohort had a 2.2% per patient-year stroke rate vs the 9.8% reported in the non-LAAO cohort (HR, 0.33; 95%CI, 0.19-0.59).14 Despite this positive outcome, no RCTs have assessed the feasibility, safety and efficacy profile of using OAC plus LAAO as adjuvant therapy in this complex population. Herein, we propose oral anticoagulation alone vs oral anticoagulation plus left atrial appendage occlusion in stroke patients despite ongoing anticoagulation (ADD-LAAO trial). This is a pragmatic randomized controlled trial (RCT) designed to evaluate the superiority of a hybrid strategy combining transcatheter left atrial appendage occlusion (LAAO) and long-term continued oral anticoagulation (OAC)—either direct oral anticoagulants (DOAC) or VKA when clinically appropriate—vs medical management with OAC alone. The trial aims to assess the effectiveness of this approach in reducing recurrent ischemic stroke in patients with atrial fibrillation (AF) who have experienced an AF-related acute ischemic stroke despite being anticoagulated at the time of stroke onset.
METHODS
Study design
We conducted a multicenter randomized controlled trial with patients with a past medical history of ischemic stroke within the past 6 months despite OAC. A total of 6 teaching hospital centers are involved in this study. Eligible patients will be screened and included based on specific criteria (figure 1 illustrates the inclusion and exclusion criteria). In general, patients with stroke despite OAC will include the following data: those with VKA with correct or labile INR and those with DOAC with poor compliance. Poor compliance will be defined as missing a maximum of 1 day dose (1 pill for VKA and 2 for DOAC) over the past week before the index stroke. Poor compliant patients will be included as the risk of non-compliance is an inherent characteristic of OAC. In contrast, patients missing > 1 day dose over the past week before the index procedure will not be included as these patients cannot be considered anticoagulated. A crucial inclusion criterion for randomization purposes will be the absence of an absolute contraindication to OAC, as this population is considered a high-risk cohort for thrombotic events, and post-LAAO OAC discontinuation has been reported to increase thrombotic risk.15 The study flow diagram is shown in figure 2.
Figure 1. Inclusion and exclusion criteria. AF, atrial fibrillation; CT, computed tomography; DOAC, direct oral anticoagulant; Hb, hemoglobin; LAAO, left atrial appendage occlusion; NYHA, New York Heart Association; OAC, oral anticoagulation; PFO, patent foramen ovale; TEE, transesophageal echocardiogram; TIA, transient ischemic attack.
a Cardioembolic ischemic stroke definition: AF-related stroke after ruling out symptomatic ipsilateral great vessel/intracranial vascular disease, and small vessel disease and active endocarditis or neoplasm.
b > 1 dose per antagonist of vitamin K and > 2 doses per DOAC.
c > 50% lumen diameter narrowing on CT, magnetic resonance imaging, or transcranial Doppler with symptoms of ipsilateral transient or visual TIA.
d If general anesthesia is planned for the study procedure.
e If the patient needs CCTA and cannot undergo TEE.
f The active treatment group may confound the results of this trial.
Figure 2. Central illustration. Study protocol. CT, computed tomography; DOAC, direct oral anticoagulant; LAAO, left atrial appendage occlusion; OAC, oral anticoagulation; TEE, transesophageal echocardiogram.
Subject screening, enrollment, and randomization
Patients meeting all inclusion and no exclusion criteria will be approached for the study. Prior to inclusion, transesophageal echocardiography (TEE) or coronary computed computed tomography will rule out the presence intra-cardiac thrombus and assess the LAA anatomy. If suitable for LAAO, the study will be explained, and informed consent from the patients will be obtained. Upon consent, patients will be randomized on a 1:1 ratio to the interventional group—receiving LAAO and long-term OAC—or the control group, receiving the optimal medical therapy as decided by neurologists. The interventional procedure will occur within 2 weeks post-randomization. The optimal medical therapy may involve intensified antithrombotic therapy, switching OAC regimens, reinforcing drug compliance, or a combination of these strategies. Randomization will be managed online, allocating patients in groups of 10 to ensure balanced inclusion across both groups.
OAC strategies
The treating neurologist team will decide on the OAC strategy and dosage for the interventional and control groups. Any DOAC (apixaban, dabigatran, rivaroxaban, or edoxaban) will be accepted. DOAC dosages will be down titrated if the patient’s bleeding risk is high or per product label recommendations. In the interventional group, although DOAC is preferred to minimize bleeding risk,16 VKA will be allowed if necessary, such as for patients with mechanical cardiac valves. The protocol does not restrict other concomitant drugs; each will be assessed for additional hemorrhagic risk by the physician. The OAC duration will be indefinite in the 2 groups unless a new formal contraindication emerges, such as in cases of major bleeding. Furthermore, each situation will be managed individually by investigators at each center.
Interventional group
Patients from the interventional group will undergo LAAO following standard practice. ACO will be discontinued prior to the procedure per product label recommendations for DOAC, and with bridging therapy using low-molecular-weight heparin in patients with an indication for VKA. A prophylactic antibiotic—cephalosporin or vancomycin for beta-lactam allergy—will be administered 2 hour prior. Procedure will be performed under general anesthesia or deep sedation with TEE or intracardiac echocardiography guidance. The femoral vein will be used for vascular acces, followed by a transseptal puncture. A 100 IU/kg bolus of IV heparin will be administered to achieve an activated clotting time ≥ 250 seconds. Fluoroscopy and TEE or intracardiac echocardiography will guide the procedure, allowing for LAA measurement, catheter and device positioning, and early complication detection. Approved LAAO devices include Amulet (Abbott Medical, United States), Watchman FLX (Boston Scientific, United States), and LAmbre (Lifetech Scientific [Shenzhen] Co. Ltd., China). Six to 24 hours after the intervention, transthoracic echocardiography will check for any pericardial effusions or device embolizations that may have occurred. If no complications are found, the patient will be discharged the same or the next day (institution protocol). Anticoagulation therapy (DOAC at the same dose as before LAAO or VKA with the initial dose determined by the thrombosis clinic assessment) will be resumed the day after the procedure. No antiplatelet therapy will be added to anticoagulation therapy in the LAAO group.
Study endpoint and outcome definitions
The primary endpoint of the study is the occurrence of a cardioembolic event—ischemic stroke or peripheral arterial embolism— within the first 12 months after inclusion. Secondary endpoints include evaluating the safety and efficacy profile of the strategies and combining cardioembolic events (efficacy) and major bleeding (safety) within the same period. A stroke is defined as the sudden onset of a focal neurologic deficit consistent with a major cerebral artery territory, categorized as ischemic, hemorrhagic, or unspecified, and confirmed through imaging using computed tomography or magnetic resonance imaging. Systemic cardioembolic events are acute vascular occlusions in an extremity or organ, confirmed by imaging, surgery, or autopsy. Major bleeding will follow the Bleeding Academic Research Consortium (BARC) criteria for types 3 and 5.17
Additional endpoints will assess major and minor bleeding (using the BARC classification), all-cause and cardiovascular death, recurrent stroke severity (using the modified Rankin scale), procedural major adverse events in the interventional group, device-related thrombus, additional hospital admissions, and OAC compliance. All clinical events, including primary and secondary endpoints, will be independently allocated.
The success of the intervention is defined as the implantation of the LAAO device without major complications, such as death, stroke, or those requiring surgical or endovascular treatment.18 Procedural safety will be evaluated by including all clinical events within the first 7 after the intervention. Events will be defined following the Valve Academic Research Consortium (VARC) guidelines, including mortality, myocardial infarction, stroke, systemic embolism, major bleeding, and procedural complications.19 Major bleeding will follow the BARC criteria for types 3 and 5.17 A neurologist will independently grade disabling strokes with an m-RS score of ≥ 3.20 Device-related thrombus will be any thrombus > 1 mm on the LAAO device, and peri-device leaks will be classified by TEE jet width (> 3 mm being significant).21 Complete LAAO is defined as the absence of any leaks > 3 mm on the final TEE.22
Clinical and imaging follow-up
Patients will be followed for 12 months. Clinical visits with neurological assessment and modified Rankin scale evaluation will occur on months 3 and 12. A phone follow-up will be conducted on month 6. The interventional group will undergo post-LAAO additional imaging modalities. Two imaging modalities with TEE or coronary computed tomography angiography will assess device-related thrombus and peri-device leaks 3 (2-4 months) and 12 months (10-12 months) after the intervention. Additionally, standard blood tests, including complete blood count and renal function will be performed on the same day as the imaging modalities to detect hidden hemorrhagic events.
Sample size and statistical analysis
Sample size is determined based on observed event rates in major registries, with an estimated 10% rate of recurrent cardioembolic events in the control group and 2% in the interventional group within the first year. To detect an 8% difference between the 2 groups, with a 5% type I error and 90% power, 183 patients per group are needed for a total of 366. Accounting for potential dropouts (~5%), the study will include 380 patients. The primary analysis will be conducted following the intention-to-treat principle, making sure that all randomized patients are analyzed in the group they have been initially allocated to, regardless of protocol deviations, dropouts, or crossover. This approach will provide an unbiased estimation of the treatment effect under real-world conditions and preserve the benefits of randomization. If a patient from the interventional group experiences a primary endpoint prior to the procedure—as they will be on OAC treatment—they will be allocated to the interventional group. An interim analysis will be performed after including 50% of the population (190 patients), and the study will be stopped if significant differences are detected.
Categorical variables will be expressed as frequencies and compared using the chi-square or Fisher’s exact test. Continuous variables will be expressed as mean ± SD or median (IQR), using the Kolmogorov-Smirnov test for normality. Comparisons will use the Student’s t test or the Mann-Whitney U test. Composite endpoints will be assessed as a time-to-first event. Cumulative incidence will be evaluated using the Kaplan-Meier method and compared using the log-rank test, followed by Cox proportional hazards modeling. Treatment effects will be estimated with hazard ratios and 95% confidence intervals, with 2-sided P-values ≤ .05 considered statistically significant. Analyses will be performed using STATA (Version 14.0 (Stata Corp., United States). The trial has been registered on ClinicalTrials.gov, and the registry No. is pending registration approval.
Current study status
Study recruitment is set to commence. The study is expected to be completed in 23 months. The projected study timeline is shown in figure 3.
Figure 3. Projected study timeline.
DISCUSSION AND CLINICAL IMPLICATIONS
The current study is expected to have a significant impact on the scientific community, particularly in the fields of cardiology and neurology. As previously mentioned, the prevalence of AF and the number of patients experiencing ischemic strokes despite being OAC are on the rise,3-5 which presents a significant challenge due to the absence of clear and uniform treatment recommendations for these patients. Intensification of antithrombotic regimens in this population often leads to an elevated risk of major bleeding, especially among elderly and frail individuals.13 Therefore, assessing a novel therapeutic strategy that combines LAAO with DOAC is essential. LAAO targets the left atrial appendage, which is responsible for more than 90% of thrombus formation in non-valvular AF,16 potentially enhancing the efficacy of OAC while maintaining a lower bleeding risk with DOAC. Recent registries evaluating the LAAO + DOAC strategy have reported promising outcomes, demonstrating a significantly reduced rate of recurrent strokes and major bleeding vs optimal medical therapy alone.23-25 Given these encouraging preliminary data, the timing is ideal for a randomized controlled trial to evaluate this combined approach rigorously.
As far as we know, the proposed study is one of the first randomized clinical trials to compare LAAO + DOAC and optimal medical therapy, as determined by a neurologist, in patients who have experienced ischemic strokes despite being on OAC. The ELAPSE trial has also started recruitment with a similar design (NCT05976685). Should trial results confirm the superiority of the LAAO + DOAC strategy over current medical management protocols, our findings will contribute to a paradigm shift in the treatment guidelines for this patient cohort. Specifically, the LAAO + DOAC combo could offer a more effective and safer therapeutic option, addressing the unmet need for reducing stroke recurrence while minimizing bleeding risks, which could impact future clinical practice and guideline recommendations, ultimately improving patient outcomes in those with AF and a history of ischemic stroke. This trial successful completion and positive outcomes can potentially establish a new standard of care, thus significantly impacting clinical practice and patient quality of life alike in this high-risk population.
To achieve these goals, the centers participating in this study have been carefully selected based on their annual volume of candidates for LAAO and their expertise in managing these procedures. These centers are recognized as referral centers for both LAAO and stroke code management. Although randomizing 380 patients across 6 hospitals within a reasonable timeframe may appear challenging, we have implemented measures to streamline the process. Dedicated teams for the early identification of eligible patients and standardized follow-up strategies have been established to facilitate recruitment.
We recognize that this is an ambitious undertaking; however, the study design and the cumulative experience of participant centers provide confidence in achieving the goals set within the anticipated timeline. If successful, this trial has the potential to establish a new standard of care, significantly impacting clinical practice and improving the quality of life of this high-risk population.
FUNDING
This work has been funded by a grant from Fundació La Marató de TV3.
ETHICAL CONSIDERATIONS
The study is being conducted following the recommendations outlined in the Declaration of Helsinki on clinical research, has been approved by Hospital Clinic de Barcelona Research Ethics Committee, and endorsed by the remaining ethics committees of all participant centers. Informed consent acceptance and signature are required prior to performing any elective procedures for the study of the non-culprit lesions. Potential sex and gender biases are considered.
STATEMENT ON THE USE OF ARTIFICIAL INTELLIGENCE
No artificial intelligence was used in the drafting of this manuscript.
AUTHORS’ CONTRIBUTIONS
X. Freixa and E. Flores-Umanzor drafted this document. The remaining signatories reviewed the document and made changes at their discretion. All the authors revised and approved the final version of the manuscript.
CONFLICTS OF INTEREST
I. Cruz-Gonzalez and X. Freixa are proctors from Abbott Medical, Boston Scientific and Lifetech. R. Estevez-Loureiro and D. Arzamendi are proctors from Abbott Medical, Boston Scientific. L. Nombela- Franco is a proctor from Abbott Medical. The rest of the authors declared no conflicts of interest whatsoever.
WHAT IS KNOWN ABOUT THE TOPIC?
- AF is increasingly prevalent, contributing to a growing number of patients experiencing ischemic strokes despite being on OAC.
- These cases represent a therapeutic dilemma, as current treatment guidelines lack clear recommendations for patients who experience recurrent ischemic events despite adequate anticoagulation.
- Existing anticoagulation strategies alone may not sufficiently prevent strokes while maintaining an acceptable bleeding risk.
- LAAO is a promising intervention that could complement anticoagulation, potentially enhancing stroke prevention while limiting bleeding complications.
- However, the safety and efficacy profile of LAAO + OAC in this high-risk population has not been rigorously evaluated in randomized clinical trials.
WHAT DOES THIS STUDY ADD?
- This study will be one of the first randomized clinical trials to assess whether LAAO + long-term OAC improves outcomes vs optimal medical therapy in patients with AF who experience ischemic stroke despite anticoagulation.
- Comparing LAAO + OAC to standard care will provide critical evidence on the potential for reducing recurrent cardioembolic events within 12 months.
- If the study confirms the benefit of this combination strategy, it could establish a new treatment paradigm for this high-risk population, filling a critical gap of the current clinical practice guidelines.
- The results could guide individualized treatment approaches balancing stroke prevention and bleeding risk.
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3. Connolly SJ, Ezekowitz MD, Yusuf S, et al. Dabigatran versus warfarin in patients with atrial fibrillation. N Engl J Med. 2009;361:1139-1151.
4. Giugliano RP, Ruff CT, Braunwald E, et al. Edoxaban versus warfarin in patients with atrial fibrillation. N Engl J Med. 2013;369:2093-2104.
5. Granger CB, Alexander JH, McMurray JJ, et al. Apixaban versus warfarin in patients with atrial fibrillation. N Engl J Med. 2011;365:981-992.
6. Xian Y, O'Brien EC, Liang L, et al. Association of Preceding Antithrombotic Treatment With Acute Ischemic Stroke Severity and In-Hospital Outcomes Among Patients With Atrial Fibrillation. JAMA. 2017;317:1057-1067.
7. Seiffge DJ, De Marchis GM, Koga M, et al. Ischemic Stroke despite Oral Anticoagulant Therapy in Patients with Atrial Fibrillation. Ann Neurol. 2020;87:677-687.
8. Meinel TR, Branca M, De Marchis GM, et al. Prior Anticoagulation in Patients with Ischemic Stroke and Atrial Fibrillation. Ann Neurol. 2021;89:42-53.
9. Yaghi S, Henninger N, Giles JA, et al. Ischaemic stroke on anticoagulation therapy and early recurrence in acute cardioembolic stroke:the IAC study. J Neurol Neurosurg Psychiatry. 2021;92:1062-1067.
10. Paciaroni M, Agnelli G, Caso V, et al. Causes and Risk Factors of Cerebral Ischemic Events in Patients With Atrial Fibrillation Treated With Non-Vitamin K Antagonist Oral Anticoagulants for Stroke Prevention. Stroke. 2019;50:2168-2174.
11. Stretz C, Wu TY, Wilson D, et al. Ischaemic stroke in anticoagulated patients with atrial fibrillation. J Neurol Neurosurg Psychiatry. 2021;92:1164-1172.
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13. Yasuda S, Kaikita K, Akao M, et al. Antithrombotic Therapy for Atrial Fibrillation with Stable Coronary Disease. N Engl J Med. 2019;381:1103-1113.
14. Maarse M, Seiffge D, Fierro N, et al. Left atrial appendage occlusion versus standard of care in patients with atrial fibrillation and a prior thrombo-embolic event despite oral anticoagulant therapy:a propensity score matched comparison. Eur Heart J. 2022;43(Supplement_2).
15. Osmancik P, Herman D, Neuzil P, et al. 4-Year Outcomes After Left Atrial Appendage Closure Versus Nonwarfarin Oral Anticoagulation for Atrial Fibrillation. J Am Coll Cardiol. 2022;79:1-14.
16. Anduaga I, Affronti A, Cepas-Guillén P, et al. Non-Pharmacological Stroke Prevention in Atrial Fibrillation. J Clin Med. 2023;12:5524.
17. Mehran R, Rao SV, Bhatt DL, et al. Standardized bleeding definitions for cardiovascular clinical trials:a consensus report from the Bleeding Academic Research Consortium. Circulation. 2011;123:2736-2747.
18. Tzikas A, Holmes DR, Jr., Gafoor S, et al. Percutaneous left atrial appendage occlusion:the Munich consensus document on definitions, endpoints, and data collection requirements for clinical studies. Europace. 2017;19:4-15.
19. Kappetein AP, Head SJ, Généreux P, et al. Updated standardized endpoint definitions for transcatheter aortic valve implantation:the Valve Academic Research Consortium-2 consensus document. J Am Coll Cardiol. 2012;60:1438-1454.
20. Banks JL, Marotta CA. Outcomes validity and reliability of the modified Rankin scale:implications for stroke clinical trials:a literature review and synthesis. Stroke. 2007;38:1091-1096.
21. Price MJ, Ellis CR, Nielsen-Kudsk JE, et al. Peridevice Leak After Transcatheter Left Atrial Appendage Occlusion:An Analysis of the Amulet IDE Trial. JACC Cardiovasc Interv. 2022;15:2127-2138.
22. Glikson M, Wolff R, Hindricks G, et al. EHRA/EAPCI expert consensus statement on catheter-based left atrial appendage occlusion - an update. Europace. 2020;22:184.
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ABSTRACT
Introduction and objectives: The use of coronary physiology is essential to guide revascularization in patients with stable coronary artery disease. However, some patients without significant angiographic coronary artery disease will experience cardiovascular events at the follow-up. This study aims to determine the prognostic value of the global plaque volume (GPV) in patients with stable coronary artery disease without functionally significant lesions at a 5-year follow-up.
Methods: We conducted a multicenter, observational, and retrospective cohort study with a 5-year follow-up. A total of 277 patients without significant coronary artery disease treated with coronary angiography in 2015 due to suspected stable coronary artery disease were included in the study. The 3 coronary territories were assessed using quantitative flow ratio, calculating the GPV by determining the difference between the luminal volume and the vessel theoretical reference volume.
Results: The mean GPV was 170.5 mm3. A total of 116 patients (42.7%) experienced major adverse cardiovascular events (MACE) at the follow-up, including cardiac death (11%), myocardial infarction (2.6%), and unexpected hospital admissions (38.1%). Patients with MACE had a significantly higher GPV (231.6 mm3 vs 111.8 mm3; P < .001). The optimal GPV cut-off point for predicting events was 44 mm3. Furthermore, in the multivariate analysis conducted, plaque volume, diabetes, hypertension, age, dyslipidemia, smoking, age, and GPV > 44 mm3 turned out to be independent predictors of MACE.
Conclusions: GPV, calculated from the three-dimensional reconstruction of the coronary tree, is an independent predictor of events in patients with stable coronary artery disease without significant lesions. A GPV > 44 mm3 is an optimal cut-off point for predicting events.
Keywords: Coronary artery disease. Coronary atherosclerosis. Coronary angiography. Global plaque volume. Coronary physiology. Quantitative flow ratio.
RESUMEN
Introducción y objetivos: La fisiología coronaria es fundamental para guiar la revascularización en los pacientes con enfermedad coronaria estable. Sin embargo, algunos pacientes sin enfermedad coronaria significativa en la angiografía presentarán eventos cardiovasculares posteriormente. Este estudio pretende determinar el valor pronóstico del volumen global de placa (VGP) en pacientes con enfermedad coronaria estable sin lesiones funcionalmente significativas durante 5 años de seguimiento.
Métodos: Se realizó un estudio observacional multicéntrico de cohortes retrospectivo con seguimiento a 5 años, que incluyó 277 pacientes sin enfermedad coronaria significativa intervenidos mediante coronariografía en 2015 por sospecha de enfermedad coronaria estable. Se evaluaron los 3 territorios coronarios mediante el cociente de flujo cuantitativo, calculando el VGP como la diferencia entre el volumen luminal y el volumen teórico de referencia del vaso.
Resultados: El VGP medio fue de 170,5 mm3. Durante el seguimiento, 116 pacientes (42,7%) presentaron eventos cardiovasculares mayores (MACE), que incluyeron muerte de causa cardiaca (11%), infarto de miocardio (2,6%) y hospitalizaciones no programadas (38,1%). Los pacientes con MACE tenían un VGP significativamente mayor (231,6 frente a 111,8 mm3, p < 0,001). El punto de corte óptimo del VGP para predecir eventos fue de 44 mm3. En el análisis multivariado, que consideró volumen de placa, diabetes, hipertensión, edad, dislipemia y tabaquismo, la edad y un VGP > 44 mm3 fueron predictores independientes de MACE.
Conclusiones: El VGP calculado mediante reconstrucción tridimensional del árbol coronario es un predictor independiente de eventos en pacientes con enfermedad coronaria estable sin lesiones significativas. Un VGP > 44 mm3 es el punto de corte óptimo para predecir eventos.
Palabras clave: Enfermedad coronaria. Ateroesclerosis coronaria. Angiografía coronaria. Volumen global de placa. Fisiología coronaria. Cociente de flujo cuantitativo.
Abbreviations
GPV: global plaque volume. MACE: major adverse cardiovascular events. QFR: quantitative flow ratio. ROC: receiver operating characteristic curve.
INTRODUCTION
Coronary artery disease is the leading cause of mortality worldwide.1 Despite the safety involved in deferring invasive treatment in patients with stable coronary artery disease without functionally significant lesions,2 a percentage of patients experience cardiovascular events at the long-term follow-up.3 It has been reported that cardiovascular events not only depend on the degree of coronary obstruction assessed by intracoronary physiology4-5 but also on the global atherosclerotic burden and its vulnerability assessed by intracoronary imaging modalities.6-8
The new era of coronary physiology is based on predicting fractional flow reserve by reconstructing the coronary tree using angiography and computational fluid dynamics.9-10 Estimating quantitative flow ratio (QFR) is the most validated method of the ones currently available.
QFR—which predicts fractional flow reserve10-11—has proven to be a better tool than angiography alone to guide the need for lesion revascularization12 and shown long-term prognostic value13. Furthermore, it provides quantitative information out of the 3D reconstruction of the coronary tree, including minimum diameter and area, reference diameters, luminal volume, and atherosclerotic plaque volume in the studied vessel. However, the prognostic value of this quantitative analysis has not been sufficiently studied.
The main aim of this study was to determine the prognostic value of global plaque volume (GPV) in patients with stable coronary artery disease without functionally significant lesions at a 5-year follow-up.
METHODS
We conducted a retrospective observational study on a cohort of patients from 6 tertiary referral centers.
Study population
Patients who underwent coronary angiography from January through December 2015 for suspected stable coronary artery disease were included. Each participant center retrospectively enrolled all patients who underwent coronary angiography for suspected stable coronary artery disease and met the inclusion criteria. Patients with chronic total coronary occlusions, prior coronary artery bypass graft surgery, or inadequate angiographic quality for analysis were excluded. Additionally, patients whose angiographic analysis revealed a positive QFR study (< 0.80) in any coronary territory were excluded. The principal investigator conducted a retrospective follow-up at each center within the next 5 years following the index procedure. Baseline and procedural characteristics, and events at the follow-up were collected by local investigators. The study fully complied the good clinical practice principles and regulations set forth in the Declaration of Helsinki for research with human subjects. The study protocol was approved by the ethics committee of the reference hospital (Hospital Clínico Universitario de Valladolid) and the institutional review boards, including informed consent obtained from participants or, alternatively, approval for retrospective data analysis under ethical committee supervision.
Angiographic analysis
A blinded angiographic analysis of diagnostic coronary angiograms was performed by trained analysts at a centralized imaging unit (Icicorelab, Valladolid) using specialized software (QAngio XA 3D QFR, Medis Medical Imaging System, The Netherlands). A 3D reconstruction of the 3 major coronary vessels was performed using 2 different projections with > 25° of separation. For the right and left circumflex coronary arteries, the proximal marker was manually placed at the vessel ostium, while for the left anterior descending coronary artery, it was placed at the left main coronary artery ostium. The distal marker was placed at the end of the coronary artery. Plaque volume was estimated by calculating the difference between the theoretical reference vessel volume in the absence of atherosclerotic disease and the estimated vessel volume in angiography using QFR software via quantitative analysis. Reference diameters, minimum diameter, and minimum area were obtained for each vessel. Considering contrast flow through the coronary tree, QFR was calculated according to FAVOR II standards for the physiological significance of coronary lesions. Patients with functionally significant disease (QFR < 0.80) were excluded.
Statistical analysis
Categorical variables are expressed as totals and percentages, and continuous ones as means and standard deviations. GPV was estimated as the sum of plaque volume across 3 coronary territories.
The primary endpoint—major adverse cardiovascular events (MACE)—was a composite of cardiac death, acute myocardial infarction, or all-cause unplanned hospital admission.
An optimal GPV cutoff as a predictor of MACE was determined using the receiver operating characteristic (ROC) curve as the value with the maximum Youden index. Multivariate logistic regression models were used to calculate the odds ratio and 95% confidence interval as independent predictors for MACE. Variables with P < .20 in the univariate analysis were included in the multivariate model as covariates.
Event-free survival was compared using Kaplan-Meier and Mantel-Haenszel analyses. All probability values were two-tailed, and P < .05 was considered statistically significant. Statistical analysis was performed using Stata (16.1, StataCorp, College Station, United States).
RESULTS
Descriptive population analysis
A total of 803 patients were evaluated for inclusion in the registry, 122 of whom (15.2%) were excluded due to chronic occlusions in ≥ 1 coronary territory, 17 (2.12%) due to previous surgical myocardial revascularization, and 159 (19.2%) due to inadequate angiographic analysis in, at least, 1 coronary territory. Among the remaining patients, 228 (45.1%) had significant coronary artery disease (QFR < 0.80) in, at least, 1 coronary territory, which left a final cohort of 277 patients. Patient flowchart is shown in figure 1.
Figure 1. Flowchart of the patient selection process for inclusion in the study. CABG, coronary artery bypass graft; CTO, chronic total coronary occlusion; QFR, quantitative flow ratio.
The mean age of the population was 65.8 years (most were hypertensive [74.4%] men [66.1%]). Table 1 illustrates the baseline characteristics of the population. The median follow-up was 69 months, during which time 5 patients were lost to follow-up.
Table 1. Baseline characteristics of the included population
| Variable | n/mean | Proportion/SD |
|---|---|---|
| Female Sex | 94 | 33.9% |
| Hypertension | 206 | 74.3% |
| Diabetes mellitus | 106 | 38.2% |
| Dyslipidemia | 188 | 67.9% |
| Smoking | 121 | 43.7% |
| Chronic kidney disease | 21 | 7.6% |
| Peripheral arterial disease | 14 | 5.1% |
| Previous ischemic heart disease | 105 | 37.9% |
| Age (years) | 65.8 | 12.2 |
| Weight (kg) | 78.0 | 15.0 |
| Height (cm) | 156.2 | 36.8 |
| Left ventricular ejection fraction (%) | 57.4 | 9.3 |
|
SD, standard deviation. |
||
Angiographic analysis
Mean plaque volume in the study population was 170.5 mm3 (± 16.5); mean QFR was 0.95. Table 2 illustrates the overall means from the angiographic analysis according to the coronary territory studied. Plaque volume was independently analyzed for each coronary territory and was significantly higher in the right (243 mm3) vs the left anterior descending (161.4 mm3) and left circumflex coronary arteries (172.9 mm3). Data on this analysis by coronary territories are shown in table 1 and figure 1 of the supplementary data.
Table 2. Characteristics of the angiographic analysis performed in the 3 coronary territories using quantitative flow ratio
| Variable | Mean | SD | 95%CI |
|---|---|---|---|
| QFR | 0.95 | 0.37 | 0.95-0.96 |
| Length | 76.99 | 13.21 | 75.22-78.77 |
| Proximal diameter | 3.18 | 0.47 | 3.11-3.24 |
| Distal diameter | 1.99 | 0.34 | 1.95-2.04 |
| Reference diameter | 2.69 | 0.42 | 2.58-2.70 |
| Minimum lumen diameter | 1.76 | 0.34 | 1.72-1.81 |
| Percent diameter stenosis | 33.81 | 6.44 | 32.95-34.68 |
| Stenosis area (%) | 38.72 | 9.59 | 37.43-40.01 |
| Minimum lumen area | 3.53 | 1.30 | 3.35-3.70 |
| Lumen volume | 295.5 | 242.25 | 262.83-328.12 |
| Plaque volume | 170.54 | 240.24 | 138.17-202.91 |
|
SD, standard deviation; 95%CI, 95% confidence interval; QFR, quantitative flow ratio. |
|||
Prognostic value of global plaque volume
The primary event (MACE) occurred in 116 patients, which amounts to 42.7% of the cohort at the follow-up. Among these patients, 11% died, 2.6% suffered an acute myocardial infarction, and 38.1% required unplanned hospitalization. Patients who developed MACE had a significantly higher GPV (231.6 vs 111.8 mm3; P < .001), as well as those with a higher mortality rate (255.2 mm3 vs 154.3 mm3; P = .04) or unplanned hospitalizations (235.0 mm3 vs 125.4 mm3; P < .001). However, there were no significant differences in patients who experienced acute myocardial infarction (235.1 mm3 vs 169.3 mm3; P = .51).
The optimal GPV cutoff to predict events was set at 44 mm3 based on ROC curve analysis (sensitivity, 64%; specificity, 65.8%; LR+, 1.9; LR–, 0.6).
Table 3 illustrates the study of the main determinants of the primary event. Variables with a significance level of P < .10 were included in the multivariate analysis. In the final model, age and GPV were independent predictors. A GPV > 44 mm3 was associated with a 2.8-fold higher risk of events at the follow-up (figure 2).
Table 3. Uni- and multivariate analysis of determinants of the main event
| Determinants of the main event | Univariate analysis | Multivariate analysis | ||
|---|---|---|---|---|
| OR | 95%CI | OR | 95%CI | |
| Sex, female | 1.09 | 0.66-1.81 | ||
| Age* | 1.03 | 1.01-1.10 | 1.03 | 1.00-1.07 |
| Hypertension* | 2.26 | 1.26-4.07 | 1.70 | 0.82-3.53 |
| Diabetes mellitus | 1.18 | 0.72-1.93 | ||
| Dyslipidemia | 1.04 | 0.62-1.73 | ||
| Smoking | 1.01 | 0.72-1.42 | ||
| Chronic kidney disease | 1.00 | 0.41-2.46 | ||
| Peripheral arterial disease | 1.37 | 0.47-4.01 | ||
| Previous ischemic heart disease* | 1.52 | 0.93-2.50 | 1.46 | 0.80-2.68 |
| LVEF | 0.98 | 0.96-1.01 | ||
| GPV (> 44 mm3)* | 1.93 | 1.17-3.18 | 2.80 | 1.51-5.21 |
| Reference vessel diameter* | 2.20 | 1.12-4.35 | 1.62 | 0.75-3.50 |
|
* P values < .10 were included in the multivariate analysis. 95%CI, 95% confidence interval; GPV, global plaque volume; LVEF, left ventricular ejection fraction; OR, odds ratio. |
||||
Figure 2. Kaplan-Meier curve showing the patients’ event-free survival based on their global plaque volume.
DISCUSSION
The main finding of this study is that GPV quantification emerged as an independent prognostic factor in patients without functionally significant coronary artery disease, which demonstrated that those with a higher GPV experienced more events at the follow-up. The optimal GPV cutoff for event prediction was set at 44 mm3. This study emphasizes the importance of anatomically characterizing coronary arteries without significant lesions.
Despite the absence of significant coronary artery obstructions, some patients still experience events during follow-up.14 In patients with a negative QFR functional study, it has been reported that the 5-year rate of events—cardiac death, target vessel myocardial infarction—is 11.6%,3 similar to our findings, where mortality rate was 11% and acute myocardial infarction occurred in 2.6% of patients. Determining the difference between the actual vessel diameter and the estimated diameter obtained through 3D reconstruction from QFR-based angiography has been used in other studies.15 This estimation—previously derived from coronary computed tomography16-17—has demonstrated the prognostic significance of plaque volume differences between normal and non-obstructive coronary arteries. These differences have also been confirmed using invasive imaging modalities such as intravascular ultrasound.18 Although angiography-derived percent luminal stenosis shows poor concordance with myocardial ischemia,19 a greater degree of coronary stenosis (percent diameter stenosis > 50%) is associated with a higher event rate at the 2-year follow-up in patients without functionally significant coronary lesions.20 The present study takes a step further into the minimally invasive characterization of atherosclerotic burden using easy-to-implement 3D coronary tree reconstruction technology as an independent prognostic factor in patients without functionally significant coronary lesions. In this regard, this study is consistent with recent studies which demonstrated that subclinical atherosclerosis burden—measured by vascular ultrasound for carotid plaque quantification and computed tomography for coronary calcium scoring—in asymptomatic individuals is independently associated with all-cause mortality.21
Based on these findings, GPV measurement enables the identification of patients who, despite having no significant coronary lesions, are at risk of developing events within the next 5 years, allowing for intensified treatment and cardiovascular risk factor control. However, this study has limitations, including its retrospective design for patient inclusion and recruitment, the use of indirect methods—such as QFR—to estimate plaque volume, and the inability of this method to describe plaque characteristics, or potential lipid plaque vulnerability. Of note, the estimated plaque volume in each coronary artery was not specifically correlated with events in that territory but rather with overall adverse cardiovascular events. Therefore, further studies are needed to confirm or refute this hypothesis.
CONCLUSIONS
Plaque volume, calculated by 3D coronary tree reconstruction, is an independent predictor of events in patients with suspected stable ischemic heart disease without significant coronary artery disease. The optimal GPV cutoff for event prediction is 44 mm3.
FUNDING
C. Cortés received funding through the Río Hortega contract CM22/00168 and Miguel Servet CP24/00128 from Instituto de Salud Carlos III (Madrid, Spain).
ETHICAL CONSIDERATIONS
The present study was conducted in full compliance with clinical practice guidelines set forth in the Declaration of Helsinki for clinical research and was approved by the ethics committees of the reference hospital (Hospital Clínico Universitario de Valladolid) and other participant centers. Possible sex- and gender-related biases were also considered.
DECLARATION ON THE USE OF ARTIFICIAL INTELLIGENCE
No artificial intelligence was used in the writing of this text.
AUTHORS’ CONTRIBUTIONS
C. Cortés and J. Ruiz-Ruiz participated in study design, data analysis, manuscript drafting, and critical review. C. Fernández and M. García participated in data collection and result analysis. F. Rivero and R. López-Palop assisted in data collection. S. Blasco and A. Freites contributed to statistical analysis. L. Scorpiglione and M. Rosario Ortas Nadal collaborated in data interpretation. O. Jiménez participated in manuscript preparation and initial review. J.A. San Román Calvar and I.J. Amat-Santos conducted the final review and approved the version for publication.
CONFLICTS OF INTEREST
None declared.
WHAT IS KNOWN ABOUT THE TOPIC?
- Global plaque volume has already been identified as an independent risk factor for the occurrence of new coronary events at the follow-up of patients without significant coronary lesions. However, this risk was determined using coronary computed tomography and imaging modalities such as intravascular ultrasound.
WHAT DOES THIS STUDY ADD?
- This article is the first study to only use the patient’s own angiography and minimally invasive coronary physiology techniques, such as quantitative flow ratio to determine plaque volume and its relationship with major cardiovascular events at a 5-year follow-up in patients without significant coronary artery disease. This approach simplifies the implementation of this technique and enhances prevention strategies for patients at higher risk of cardiovascular events.
SUPPLEMENTARY DATA
REFERENCES
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2. Zimmermann FM, Ferrara A, Johnson NP, et al. Deferral vs. of percutaneous coronary intervention of functionally non-significant coronary stenosis:15-year follow-up of the DEFER trial. Eur Heart J. 2015;36:3182-3188.
3. Kuramitsu S, Matsuo H, Shinozaki T, et al. Five-Year Outcomes After Fractional Flow Reserve-Based Deferral of Revascularization in Chronic Coronary Syndrome:Final Results From the J-CONFIRM Registry. Circ Cardiovasc Interv. 2022;15:E011387.
4. De Bruyne B, Pijls NHJ, Kalesan B, et al. Fractional flow reserve-guided PCI versus medical therapy in stable coronary disease. N Engl J Med. 2012;367:991-1001.
5. Ciccarelli G, Barbato E, Toth GG, et al. Angiography versus hemodynamics to predict the natural history of coronary stenoses:Fractional flow reserve versus angiography in multivessel evaluation 2 substudy. Circulation. 2018;137:1475-1485.
6. Mortensen MB, Dzaye O, Steffensen FH, et al. Impact of Plaque Burden Versus Stenosis on Ischemic Events in Patients With Coronary Atherosclerosis. J Am Coll Cardiol. 2020;76:2803-2813.
7. Shan P, Mintz GS, McPherson JA, et al. Usefulness of Coronary Atheroma Burden to Predict Cardiovascular Events in Patients Presenting With Acute Coronary Syndromes (from the PROSPECT Study). Am J Cardiol. 2015;116:1672-1677.
8. Prati F, Romagnoli E, Gatto L, et al. Relationship between coronary plaque morphology of the left anterior descending artery and 12 months clinical outcome:the CLIMA study. Eur Heart J. 2020;41:383-391.
9. Tu S, Westra J, Yang J, et al. Diagnostic Accuracy of Fast Computational Approaches to Derive Fractional Flow Reserve From Diagnostic Coronary Angiography:The International Multicenter FAVOR Pilot Study. JACC Cardiovasc Interv. 2016;9:2024-2035.
10. Westra J, Andersen BK, Campo G, et al. Diagnostic Performance of In?Procedure Angiography?Derived Quantitative Flow Reserve Compared to Pressure?Derived Fractional Flow Reserve:The FAVOR II Europe?Japan Study. J Am Heart Assoc. 2018;7:009603.
11. Cortés C, Carrasco-Moraleja M, Aparisi A, et al. Quantitative flow ratio —Meta-analysis and systematic review. Catheter Cardiovasc Interv. 2021;97:807-814.
12. Xu B, Tu S, Song L, et al. Angiographic quantitative flow ratio-guided coronary intervention (FAVOR III China):a multicentre, randomised, sham-controlled trial. Lancet. 2021;398:2149-2159.
13. Cortés C, Fernández-Corredoira PM, Liu L, et al. Long-term prognostic value of quantitative-flow-ratio-concordant revascularization in stable coronary artery disease. Int J Cardiol. 2023;389:131176.
14. Wang TKM, Oh THT, Samaranayake CB, et al. The utility of a “non-significant“coronary angiogram. Int J Clin Pract. 2015;69:1465-1472.
15. Kolozsvári R, Tar B, Lugosi P, et al. Plaque volume derived from three-dimensional reconstruction of coronary angiography predicts the fractional flow reserve. Int J Cardiol. 2012;160:140-144.
16. Huang FY, Huang BT, Lv WY, et al. The Prognosis of Patients With Nonobstructive Coronary Artery Disease Versus Normal Arteries Determined by Invasive Coronary Angiography or Computed Tomography Coronary Angiography:A Systematic Review. Medicine (Baltimore). 2016;95:3117.
17. Khajouei AS, Adibi A, Maghsodi Z, Nejati M, Behjati M. Prognostic value of normal and non-obstructive coronary artery disease based on CT angiography findings. A 12 month follow up study. J Cardiovasc Thorac Res. 2019;11:318-321.
18. Lee JM, Choi KH, Koo BK, et al. Prognostic Implications of Plaque Characteristics and Stenosis Severity in Patients With Coronary Artery Disease. J Am Coll Cardiol. 2019;73:2413-2424.
19. Tebaldi M, Biscaglia S, Fineschi M, et al. Evolving Routine Standards in Invasive Hemodynamic Assessment of Coronary Stenosis. JACC Cardiovasc Interv. 2018;11:1482-1491.
20. Ciccarelli G, Barbato E, Toth GG, et al. Angiography versus hemodynamics to predict the natural history of coronary stenoses:Fractional flow reserve versus angiography in multivessel evaluation 2 substudy. Circulation. 2018;137:1475-1485.
21. Fuster V, García-Álvarez A, Devesa A, et al. Influence of Subclinical Atherosclerosis Burden and Progression on Mortality. J Am Coll Cardiol. 2024;84:1391-1403.
ABSTRACT
Introduction and objectives: Infective endocarditis (IE) is a rare but serious complication in patients with aortic valve stenosis undergoing transcatheter aortic valve implantation (TAVI). The spread of this technique to lower risk patients means that this complication may increase. The objective of this study was to analyze the incidence and mortality of IE in TAVI patients vs patients undergoing surgical aortic valve replacement (SAVR).
Methods: We conducted an observational, single-center, retrospective cohort study that included all cases of IE diagnosed consecutively in a Spanish reference center from 2008 through 2022 in patients with TAVI vs SAVR.
Results: The study included a total of 10 cases of IE in 778 patients treated with TAVI, with an incidence rate of 0.09/100 patients/year vs an incidence rate of 0.12/100 patients/year in surgical bioprostheses with 24 cases in 1457 patients (P = .64) (median follow-up of 49 months (p25-p75: 29-108). Clinical features were very similar, with 50% of TAVI patients having cardiac complications vs 33% of SAVR patients (P = .33). Although 40% of the patients from the TAVI group had a surgical indication for IE and 50% for SAVR, P = .49), only half of them underwent surgery in both groups (20% TAVI vs 25% SAVR; P = .93). No differences were reported in the 1-year mortality rate (30% TAVI vs 29% SAVR; P = .56).
Conclusions: The incidence rate of IE in this long series of TAVI patients was low and despite the worse clinical profile of TAVI patients, no significant mortality differences were found compared with the group of patients with surgical bioprosthesis.
Keywords: Infectious endocarditis. Aortic stenosis. Surgical aortic valve replacement. Transcatheter aortic valve implantation.
RESUMEN
Introducción y objetivos: La endocarditis infecciosa (EI) es una complicación infrecuente, pero grave, en los pacientes con estenosis valvular aórtica que han recibido un implante percutáneo de válvula aórtica (TAVI). La extensión de esta técnica a pacientes de menor riesgo hace que esta complicación pueda aumentar. El objetivo del estudio fue analizar la incidencia y la mortalidad de la EI en pacientes con TAVI en comparación con la EI en pacientes con recambio valvular aórtico (RVAo).
Métodos: Estudio observacional, unicéntrico, retrospectivo de cohortes, que incluyó todos los casos de EI diagnosticados de manera consecutiva en un centro español de referencia, desde 2008 hasta 2022, en pacientes con TAVI, y se compararon con las EI en pacientes con RVAo.
Resultados: Hubo 10 casos de EI en 778 pacientes tratados con TAVI, con una tasa de incidencia de 0,09/100 pacientes/año, frente a 24 casos en 1.457 pacientes con RVAo, con una tasa de incidencia de 0,12/100 pacientes/año (p = 0,64), en una mediana de seguimiento de 49 meses (p25-p75: 29-108). Los pacientes con TAVI eran mayores, tenían más diabetes mellitus y un EuroSCORE mayor. El microorganismo más frecuente fue el enterococo (30% TAVI frente a 33% RVAo; p = 0,89). La evolución clínica fue muy similar, con un 50% de pacientes con TAVI que tuvieron una complicación cardiaca frente al 33% de los pacientes con RVAo (p = 0,33). En el grupo de TAVI, el 40% tuvieron indicación quirúrgica por la EI, frente al 50% en el grupo de RVAo (p = 0,49), pero solo la mitad fueron intervenidos en ambos grupos (20% TAVI frente a 25% RVAo; p = 0,93). No hubo diferencias en la mortalidad al año (30% TAVI frente a 29% RVAo; p = 0,56).
Conclusiones: La incidencia de EI en esta serie de pacientes con TAVI fue baja, y pese a un peor perfil clínico en los pacientes con TAVI, no se encontraron diferencias significativas en la mortalidad con el grupo de pacientes con RVAo.
Palabras clave: Endocarditis infecciosa. Estenosis aórtica. Recambio valvular aórtico. Implante percutáneo de válvula aórtica.
Abbreviations
IE: infectious endocarditis. SAVR: surgical aortic valve replacement. TAVI: transcatheter aortic valve implantation.
INTRODUCTION
Transcatheter aortic valve implantation (TAVI) revolutionized the treatment of severe aortic valve stenosis over the past decade.1,2 Furthermore, in recent years, there has been a clear preference for TAVI over surgical techniques regarding the treatment of this valvular heart disease, with an increasing number of patients, including low surgical risk ones.3 Although post-TAVI infective endocarditis (IE) is a rare complication reported in 1% up to 6% of patients, it is often associated with grim clinical outcomes and high mortality rates despite diagnostic1,2 and therapeutic4 advances. Complications are expected to rise exponentially as the number of TAVIs continues to rise at a constant rate in our setting as well.5
Few studies have compared the incidence of IE on TAVI and surgical aortic valve replacement (SAVR). However, randomized clinical trials have shown similar annual incidences of IE after SAVR and TAVI.6,7 Due to the strict patient selection of such studies, the results obtained in each center during the routine clinical practice may vary, and few studies like this using dedicated databases have been conducted. A multicenter study8 revealed the characteristics of IE on TAVI vs SAVR and the outcomes of a large patient cohort, yet it did not analyze the incidence of IE. Assessing the outcomes of this severe complication at each center should be a priority due to its potential impact on decision-making for the heart team.3
The aim of the present study was to analyze both the incidence and mortality rates of IE on TAVI vs SAVR patients from a tertiary teaching hospital in a long series of patients with severe aortic stenosis.
METHODS
Study design and population
We conducted an observational, single-center, retrospective study of a prospective cohort including all cases of IE in symptomatic patients with severe aortic valve stenosis treated with TAVI or SAVR using a biological prosthetic valve, diagnosed, and followed at a tertiary teaching referral hospital by an endocarditis team from January 2008 through December 2022.
Endpoints and definitions
The primary endpoint of the study was to analyze the overall incidence and mortality rates of IE on TAVI at our center. Secondary endpoint was to compare both rates in patients with IE on TAVI and SAVR during the same period. Another secondary endpoint was to study the number of patients who underwent surgery for IE in both groups. IE was diagnosed using the Duke criteria9 or the 2015 European Society of Cardiology modified criteria10 depending on the time of diagnosis in the study period. Cases of IE in TAVI patients during this period were identified, and their characteristics were compared with those of IE in SAVR patients.
Follow-up
Follow-up events were defined based on the criteria established by the Valve Academic Research Consortium-2.11 All complications, need for surgery, and mortality at the follow-up were recorded. IE-related cardiac complications included decompensated heart failure, fistula, prosthetic dehiscence, abscess, and complete atrioventricular block. Systemic complications included acute kidney failure, sepsis, embolism, and disorders of the central nervous system. Early IE was defined as that occurring within the first year after TAVI or surgery based on European recommendations.10 Since 1987, a prospective protocol for inclusion and follow-up of all IE cases has been in place at our center, with a systematic registry including in-person visits, at least, annually for all patients, as well as phone consultations when needed.
Statistical analysis
Qualitative data are expressed as percentages, and continuous data as mean and standard deviation or median [interquartile range], depending on whether they follow a normal distribution. Inter-group comparisons were drawn using the chi-square test or Fisher’s exact test for qualitative variables, and the Student’s t-test or Mann-Whitney U test for continuous variables, as appropriate. Time-to-event analyses for all-cause mortality were conducted using Kaplan-Meier curves. All tests were two-sided, and P values < .05 were considered statistically significant. Statistical analyses were performed with SPSS software (version 24; IBM Corp, Armonk, NY, United States).
RESULTS
Study population and incidence rate
During the study period, a total of 778 patients successfully underwent TAVI, 70% of them with self-expanding valves. After a median follow-up of 49 months (p25-p75, 29–108 months), 10 cases of IE were eventually diagnosed, which amounts to an overall incidence rate of 1.29% (an incidence rate of 0.09/100 patient-years). Twenty-four of the 1457 patients treated with surgical bioprostheses were diagnosed with IE for an overall incidence rate of 1.64% (an incidence rate of 0.12/100 patient-years). The hazard ratio for the IE incidence rate between the 2 groups was 0.75 (95% confidence interval, 0.36–1.57). The incidence rate of IE on TAVI remained stable throughout the study period, as did the incidence of IE on surgical bioprostheses. Four of the 10 IE cases in TAVI occurred between 2008 and 2015—incidence of 1.21%—and 6 between 2016 and 2022 (incidence of 1.33%). The incidence rates of IE on surgical bioprostheses for the same periods were 1.62% and 1.67%, respectively. Clinical characteristics, treatment, and mortality rates were also similar across periods in both IE groups.
Characteristics of IE in TAVI and SAVR
Approximately half of the cases reported in both groups turned out to be early IE: 5 of the 10 TAVI IE cases and 11 of the 24 cases described on surgical bioprostheses occurred within the first year after implantation (50% TAVI and 46% SAVR; P = .56). The remaining cases were late prosthetic IE (table 1). Among TAVI IE cases, the 5 early ones were diagnosed 2, 4, 6, 8, and 11 months after implantation, while the 5 late ones were diagnosed within years 2 (3 cases) and 3 (2 cases). Among the IE reported on surgical bioprostheses, early cases were diagnosed within the first 2 months (2 cases), between months 3 and 6 (3 cases), and between months 6 and 12 (5 cases) after surgery. Regarding late cases, 5 occurred in year 2, 4 in year 3, and 4 > 3 years after surgery.
Table 1. Baseline characteristics of patients with infectious endocarditis after transcatheter aortic valve implantation or surgical aortic valve replacement
| Baseline characteristics | Total (n = 34) | TAVI (n = 10) | SAVR (n = 24) | P |
|---|---|---|---|---|
| Age (years) | 67 (53-81) | 76 (67-85) | 63 (49-77) | .001 |
| Female | 13 (38%) | 4 (40%) | 9 (37%) | .594 |
| Hypertension | 28 (82%) | 10 (100%) | 18 (75%) | .100 |
| Type 2 diabetes mellitus | 14 (41%) | 7 (70%) | 7 (29%) | .034 |
| COPD | 8 (33%) | 3 (30%) | 5 (21%) | .435 |
| CKD (GFR < 60) | 12 (35%) | 3 (30%) | 9 (38%) | .498 |
| Atrial fibrillation | 17 (50%) | 7 (70%) | 10 (42%) | .129 |
| Ischemic heart disease | 4 (12%) | 1 (10%) | 3 (12%) | .666 |
| Functional class II/III | 18 (53%) | 6 (60%) | 12 (50%) | .488 |
| EuroSCORE II | 7.41 ± 4.1 | 3.6 ± 2.8 | .007 | |
|
CKD, chronic kidney disease; COPD, chronic obstructive pulmonary disease; GFR, glomerular filtration rate; SAVR, surgical aortic valve replacement; TAVI, transcatheter aortic valve implantation. |
||||
A possible source of infection different from implantation or surgery was identified in 2 of the 10 TAVI IE cases (20%) and in 2 of the 24 surgical bioprostheses. IE cases (8.3%). Only 1 of the early IE cases was associated with a possible infection source: a colonoscopy in a TAVI IE patient due to Enterococcus. None of the SAVR IE cases had an identified source, with implantation or the perioperative period being regarded as the probable sources of infection in the remaining patients. Among late IE cases, 1 TAVI IE case was associated with a dental procedure—despite proper antibiotic prophylaxis—and 2 SAVR IE cases with an upper gastrointestinal endoscopy and a dental visit, respectively. These patients’ clinical characteristics are shown in table 1. TAVI patients were older, with a median [interquartile range] age of 76 years [67–85] vs 63 years [49–77] of those treated with surgical bioprostheses (P < .001) and had higher rates of diabetes (70% vs 29%; P = .034). However, there were no significant differences in sex, other comorbidities, or symptoms. As expected, the TAVI group had a significantly higher EuroSCORE II vs the SAVR group (table 1). The profile of causative pathogens was very similar between the 2 groups (table 2). Enterococci were the pathogens most widely identified, followed by coagulase-negative staphylococci and Staphylococcus aureus, also with no significant differences being reported between the 2 groups. In 17% of SAVR patients and 20% of TAVI patients, the causative agent could not be identified (figure 1). Diagnostic echocardiographic findings of IE were also very similar between the 2 groups: transthoracic echocardiography identified IE only in half of the TAVI cases vs 37% of the cases treated with surgical bioprostheses (
Table 2. Microbiological profile of the most common microorganisms and diagnostic lesions in the echocardiogram of patients with infectious endocarditis after transcatheter aortic valve implantation or surgical aortic valve replacement
| Microbiological profile and echocardiogram | Total (n = 34) | TAVI (n = 10) | SAVR (n = 24) | P |
|---|---|---|---|---|
| Early IE (< 1 year) | 16 (47%) | 5 (50%) | 11 (46%) | .560 |
| Microorganism | ||||
| Enterococcus | 11 (32%) | 3 (30%) | 8 (33%) | .891 |
| Staphylococcus epidermidis | 9 (26%) | 3 (30%) | 6 (25%) | .819 |
| Staphylococcus aureus | 4 (12%) | 1 (10%) | 3 (12%) | .854 |
| Other/Unknown | 10 (29%) | 3 (30%) | 7 (29%) | .153 |
| Lesion in echocardiogram | ||||
| TTE | 14 (41%) | 5 (50%) | 9 (37%) | .382 |
| TEE | 26 (76%) | 10 (100%) | 16 (67%) | .101 |
|
IE, infectious endocarditis; TEE, transesophageal echocardiogram; TTE, transthoracic echocardiogram; SAVR, surgical aortic valve replacement; TAVI, transcatheter aortic valve implantation. |
||||
Disease progression
The course of the disease was similar in the 2 groups (table 3). Half of the TAVI group experienced cardiac complications, as did one-third of the SAVR group, without any significant differences being reported. Half of the patients had a surgical indication due to IE (40% in the TAVI group vs 50% in the SAVR group; P = .49), but among those, only 20% of the TAVI group and 25% of the SAVR group eventually underwent surgery (P = .93) (table 3). The in- hospital mortality rate was similar (20% in the TAVI group vs 25% in the SAVR group; P = .51), without any significant differences being reported in the 1-year mortality rate, which remained high—at approximately 30%—in both groups (table 3, figure 1, and figure 3).
Table 3. Complications, rate of surgical procedures, and 1-year mortality rate in patients with infectious endocarditis after transcatheter aortic valve implantation or surgical aortic valve replacement
| Complications and mortality | Total (n = 34) | TAVI (n = 10) | SAVR (n = 24) | P |
|---|---|---|---|---|
| Cardiac complications | 13 (38%) | 5 (50%) | 8 (33%) | .329 |
| Systemic complications | 15 (44%) | 2 (20%) | 13 (54%) | .072 |
| Indication for surgery | 16 (47%) | 4 (40%) | 12 (50%) | .491 |
| Surgery performed | 8 (23%) | 2 (20%) | 6 (25%) | .932 |
| Surgery not performed | 26 (77%) | 8 (80%) | 18 (75%) | .909 |
| 1-year mortality | 10 (29%) | 3 (30%) | 7 (29%) | .562 |
| In-hospital mortality | 8 (24%) | 2 (20%) | 6 (25%) | .512 |
|
SAVR, surgical aortic valve replacement; TAVI, transcatheter aortic valve implantation. |
||||
Figure 1. Infective endocarditis (IE) after transcatheter aortic valve implantation in a cohort of 778 patients vs a cohort of patients with surgical bioprostheses-related IE. SAVR, surgical aortic valve replacement; TAVI, transcatheter aortic valve implantation; TEE, transesophageal echocardiography; TTE, transthoracic echocardiography.
Figure 2. Transesophageal echocardiogram showing a large vegetation on the leaflets of a transcatheter aortic valve (arrows).
Figure 3. Kaplan-Meier curves showing the 1-year mortality rate in patients with infective endocarditis after transcatheter aortic valve implantation (TAVI) or surgical aortic valve replacement (SAVR).
DISCUSSION
The main finding of our study was that the incidence rate of IE on TAVI is low in our setting and similar to that of surgical aortic bioprostheses, despite being patients with higher surgical risk, older age, and more comorbidities. These results are similar to those reported in the literature (1% up to 6%);4 however, more recent large TAVI trials suggest lower rates. The PARTNER 3 trial reported annual rates of 0.2%,1 and similarly, the low-risk Evolut study2 found incidence rates of 0.1% and 0.2% at 30 days and 1 year, respectivelu, which is more consistent with our rates. Studies directly comparing the incidence of IE after SAVR and TAVI are scarce, and some have produced contradictory results.7,12 However, most observational studies based on large national databases and randomized clinical trials have found no statistically significant differences on this regard,6,13,14 even though TAVI patients are older and generally have more comorbidities, which is consistent with our results. There were also no differences in our study regarding early IE incidence (50%), which was similar in both groups, although slightly lower for IE on TAVI vs what has been reported by the literature (rates up to 64%.)15 However, a multicenter study conducted in Spain found a higher rate of early IE in TAVI vs SAVR patients (78.1% vs 39.3%; P = .001), which is significantly higher than that described in our series for the TAVI group.16 This could be explained by the different antibiotic prophylaxis regimens and procedures used at each center.
Secondly, another relevant finding from our study is that enterococci were the main cause of IE in both patient groups, which is consistent with the literature on TAVI-related IE17,18 but not on surgical bioprostheses-related IE, of which S. aureus is usually the main microorganism involved. These differences are difficult to explain, as the increase in enterococcal incidence as a causal agent in TAVI is primarily associated with older patient age and transfemoral access but still would not explain why it is also the most common pathogen in SAVR-related IE.4 Compared with a multicenter Spanish series of similar characteristics to ours,16 there are some differences: the most common causative microorganism of IE—in both TAVI and SAVR— was Staphylococcus epidermidis, followed by enterococci— less frequent than in our series—and thirdly, S. aureus. These differences could be explained by varying antibiotic prophylaxis regimens used in different settings, underscoring the critical importance of understanding the most common microorganisms involved in prosthetic IE, in general, to apply the most appropriate and effective prophylaxis regimen.
Another noteworthy aspect of this study is that echocardiographic lesions diagnostic of IE could be identified in 100% of TAVI- related IE cases vs 67% of SAVR-related IE cases in surgical prostheses. This contrasts sharply with most reports, which indicate that the combined sensitivity rate of transthoracic and transesophageal echocardiography was 67.8% in TAVI patients, 73% in SAVR patients, and nearly 90% in native valves.19 However, a very recent study comparing patients with IE after TAVI or SAVR confirmed that vegetations were identified via echocardiogram in up to 82% of the TAVI group, more in line with our findings and significantly higher than the diagnostic rate of IE reported in surgical prostheses (62.5%; P < .001).8 Our results also differ from those reported in the literature in that most lesions found via echocardiography were vegetations, whereas other authors, such as Salaun et al.,20 reported vegetations in only 5 out of 11 cases diagnosed with TAVI-related IE, with the remaining cases being atypical lesions.
Lastly, this study also highlights the course of the disease, with a 1-year mortality rate of 30%, which is lower than that reported in other published studies (between 33% and 66%).4,12,21-23 The in-hospital mortality rate was also lower than that reported in other studies, such as the international multicenter registry of post-TAVI endocarditis21 (36% vs 20% in our series) and much lower than the Spanish multicenter trial (35%).16 These differences may be due to the wide variability in patient characteristics across studies. Of note, there were no significant differences in mortality when comparing surgical bioprostheses-related IE, unlike other series reporting lower mortality for the latter vs TAVI-related IE.23 However, a study published by Panagides et al.,8 comparing early and 1-year mortality in IE after TAVI and SAVR using propensity score matching found no significant differences between the 2. In our series, only 20% of TAVI patients with a surgical indication underwent surgery, which is consistent with other studies where surgical rates were similar to ours, with optimal medical therapy being the most common strategy.4,12,16,22,23 Some studies found no improvement in prognosis for these patients undergoing surgery, with similar mortality rates associated with optimal medical therapy,24 while a meta-analysis published by Tinica et al.25 showed that the surgical strategy was significantly superior to conservative therapy. In any case, given the lack of strong evidence, the treatment strategy for TAVI-related IE remains unclear, even if the presence of complications warrants surgical indication, and decisions should be based on local expertise.
Study limitations
Our study has the inherent limitations of its observational design, with data collected over many years, during which diagnostic criteria for IE, valve types—towards better technical models—and procedural approaches—towards less invasive methods—have evolved. The small number of IE cases in the 2 groups means results should be interpreted with caution. As this is a crude analysis, the presence of confounding bias cannot be ruled out; nevertheless, data show real-life outcomes. Additionally, patients with mechanical valves were not included, so results cannot be extrapolated to this group.
CONCLUSIONS
In our setting, TAVI-related IE has a low overall incidence rate, with no significant differences vs SAVR-related IE, despite involving older and more comorbid patients. Regarding the causative microorganism of IE—both in surgical and percutaneous surgical bioprostheses—enterococci were the most common pathogen. There were no differences in mortality between the 2 types of aortic valves, and treatment for IE was predominantly conservative.
FUNDING
None declared.
ETHICAL CONSIDERATIONS
The study was conducted in full compliance with the Declaration of Helsinki and approved by the Clinical Research Ethics Committee at the beginning of the registry in 1987. However, for patients with TAVI or SAVR, all participants signed an informed consent form authorizing the collection and analysis of their data for research purposes. Since this was an observational study, patient treatment was not impacted. For this new registry analysis, approval was obtained from our center ethics committee. Data were handled completely anonymously in full compliance with the provisions of Organic Law 3/2018 of the Spanish Data Protection Authority.
STATEMENT ON THE USE OF ARTIFICIAL INTELLIGENCE
No artificial intelligence was used in the development of this work.
AUTHORS’ CONTRIBUTIONS
A. Roldán participated in data collection and analysis. C. Urbano participated in data collection and analysis. N. Aguayo participated in patient identification, data collection, and analysis. M. Crespín, J. López, and J.C. Castillo participated in the conception of the article and its interpretation. R. González contributed to statistical analysis and result interpretation. D. Mesa and M. Ruiz contributed to data processing, analysis and result interpretation, and collaborated in the revision and preparation of the manuscript for publication. J. Perea, I. Gallo, J. Suárez de Lezo, and S. Ojeda participated in the conception of the work, helped gather patient information, and provided guidance on literature review and manuscript drafting. M. Pan and M. Anguita supervised all stages of manuscript drafting, from conception, data collection, and result interpretation, to revision, correction, and preparation of the article for submission.
CONFLICTS OF INTEREST
S. Ojeda is an associate editor of REC: Interventional Cardiology. The journal’s editorial procedure to ensure impartial handling of the manuscript has been followed. The remaining authors declared no conflicts of interest whatsoever.
WHAT IS KNOWN ABOUT THE TOPIC?
- TAVI-related IE is a rare complication associated with high morbidity and mortality rates. Few studies have compared TAVI- and SAVR-related IE; however, despite sometimes contradictory results, published data generally show similar figures for incidence and mortality. Given the expansion of TAVI indications in recent years to younger and lower-risk patients, it is essential to understand outcomes in different settings.
WHAT DOES THIS STUDY ADD?
- Understanding the reality of a reference center in the management of aortic stenosis using different techniques, such as TAVI and SAVR with surgical bioprosthesis—particularly regarding incidence and mortality rates in a large patient series—is essential for selecting the most appropriate treatment. The low incidence of IE in this study, along with mortality rates consistent with or lower than those published in the literature, helps the heart team make appropriate decisions. Finally, identifying the most common pathogens causing IE in our setting is critical for establishing the most effective prophylactic protocols.
REFERENCES
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2. Mack MJ, Leon MB, Thourani VH, et al. PARTNER 3 Investigators. Transcatheter Aortic-Valve Replacement with a Balloon-Expandable Valve in Low-Risk Patients. N Engl J Med. 2019;380:1695-1705.
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6. Summers MR, Leon MB, Smith CR, et al. Prosthetic valve endocarditis after TAVR and SAVR. Circulation. 2019;140:1984-1994.
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14. Moriyama N, Laakso T, Biancari F, et al. Prosthetic valve endocarditis after transcatheter or surgical aortic valve replacement with a bioprosthesis:results from the FinnValve registry. EuroIntervention. 2019;15:e500-e507.
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16. Jerónimo A, Olmos C, Zulet P, et al. Clinical characteristics and outcomes of aortic prosthetic valve endocarditis:comparison between transcatheter and surgical bioprostheses. Infection. 2024. https://doi.org/10.1007/s15010-024-02302-0.
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ABSTRACT
Introduction and objectives: Because of the potential need for permanent pacemaker implantation, patients are frequently monitored for days after transcatheter aortic valve implantation (TAVI), particularly when using self-expanding valves. We sought to determine whether the appearance and management of conduction disturbances after TAVI can be improved by combining the cusp overlap projection (COP) and a rapid atrial pacing (RAP) protocol to detect the need for pacemaker implantation.
Methods: We consecutively studied a total of 273 patients who underwent TAVI with self-expanding valves from 2018 through 2022 (134 undergoing standard implantations and 139 COP + RAP). Assessment included the 90-day follow-up.
Results: Complete heart block was reported in 25.4% and 14.4% in the standard-of-care and COP + RAP group, with a marked decrease in transient atrioventricular block (12.8% vs 2.9%, respectively; P = .007). The absence of the Wenckebach phenomenon during RAP had a negative predictive value of 97% (95%CI, 91-99) for pacemaker implantation at the follow-up, which significantly decreased the need for 24-hour temporary pacemaker monitoring in the COP + RAP group (91.8% vs 28.1%; P < .0001) and the median [IQR] length of stay (5.0 [4-8] days vs 2.0 [1-4] days; P < .0001). At the 90-day follow-up, COP + RAP reduced pacemaker implantation (OR, 0.48; 95%CI, 0.24-0.92; P = .031), as well as the risk of infection-related readmissions significantly (OR, 0.35; 95%CI, 0.12-0.89; P = .036).
Conclusions: The combination of COP + RAP during self-expanding TAVI improves postoperative screening for conduction disturbances, thus reducing the need for cardiac rhythm monitoring, and the length stay. The COP + RAP strategy improves the short-term clinical outcomes of self-expanding TAVI due to fewer infection-related readmissions.
Keywords: Transcatheter aortic valve implantation. Pacemaker. Cusp overlap. Rapid atrial pacing
RESUMEN
Introducción y objetivos: La necesidad de marcapasos definitivo obliga a la monitorización posprocedimiento tras el implante percutáneo de válvula aórtica (TAVI), especialmente con válvula autoexpandible. El objetivo fue determinar si la aparición y el tratamiento de los trastornos de la conducción tras el TAVI se pueden mejorar combinando la proyección de superposición de cúspides (SC) con un protocolo de sobreestimulación auricular rápida (SAR).
Métodos: Se incluyeron 273 pacientes intervenidos de TAVI entre 2018 y 2022 con válvulas autoexpandibles, 134 con implante estándar y 139 combinando SC y SAR (SC+SAR), con seguimiento a 90 días.
Resultados: El bloqueo completo ocurrió en el 25,4% del grupo estándar y en el 14,4% del grupo SC+SAR, con una reducción significativa del bloqueo transitorio (12,8% frente a 2,9%, p = 0,007). La ausencia de fenómeno de Wenckebach durante la SAR tuvo un valor predictivo negativo del 97% (IC95%, 91-99) para marcapasos en el seguimiento. Esto redujo la necesidad de vigilancia durante 24 horas con marcapasos temporal en el grupo SC+SAR (91,8% frente a 28,1%, p < 0,0001) y la mediana de hospitalización (5,0 [4-8] frente a 2,0 [1-4] días, p < 0,0001). En el seguimiento a 90 días, la combinación SC+SAR redujo la necesidad de marcapa- sos (OR = 0,48; IC95%, 0,24-0,92; p = 0,031). Este grupo presentó una reducción significativa en los reingresos por infecciones (OR = 0,35; IC95%, 0,12-0,89; p = 0,036).
Conclusiones: La combinación SC+SAR en el TAVI con válvula autoexpandible mejora la estratificación del riesgo de alteraciones de la conducción posprocedimiento, reduciendo la necesidad de vigilancia y la estancia hospitalaria. Esta estrategia mejora los resultados a corto plazo, con una reducción de los reingresos relacionados con infecciones.
Palabras clave: Implante percutáneo de válvula aórtica. Marcapasos. Superposición de cúspides. Sobreestimulación auricular rápida.
Abbreviations:
AV: atrioventricular. COP: cusp-overlap projection. LBBB: left bundle branch block. PPI: permanent pacemaker implantation. RAP: rapid atrial pacing. TAVI: transcatheter aortic valve implantation.
INTRODUCTION
Transcatheter aortic valve implantation (TAVI) has become an established option for symptomatic severe aortic stenosis across risk groups.1,2 The implantation technique is moving towards a less invasive procedure with shorter hospitalizations.3,4 Because the length of hospital-stay has been related to major adverse cardiovascular events during follow-up,5 optimizing the procedure remains a concern. Different studies have demonstrated that patients can be safely discharged 72 and even 48 hours after TAVI, and various protocols with a minimalist approach have been described so far, mainly with balloon-expandable valves.6-9 Nevertheless, the potential need for a permanent pacemaker implantation (PPI) frequently prolongs hospital admissions for the purpose of rhythm monitorization after TAVI.10,11 This issue is particularly relevant for self-expanding valves,12-14 since the rate of PPI is highest amongst these models and most early-discharge strategies have been reported for balloon-expandable prostheses.9,15
The rate of PPI can be reduced by guiding TAVI by the cusp-overlap projection (COP) to isolate the non-coronary cusp and better control prothesis implantation depth.16,17 In addition, sequential rapid atrial pacing (RAP) after deployment has been proposed to screen for atrioventricular (AV) conduction disorders.18 However, the effect of combining both preventive and diagnostic techniques on clinical outcomes after self-expanding TAVIs remains unknown. Therefore, the present study was designed to determine whether compared to conventional care, the combined use of COP and RAP can improve the management of conduction disturbances and the early outcomes after self-expandable TAVI procedures.
METHODS
Study population
This is a one-center retrospective analysis of consecutive patients who underwent transfemoral self-expandable TAVI between January 2018 to January 2022. All patients had symptomatic severe aortic stenosis and were deemed eligible for TAVI by a multidisciplinary heart team. We included all transfemoral cases irrespectively of surgical risk. From this cohort, we selected patients in sinus rhythm undergoing a self-expandable prothesis implantation procedure. We excluded patients with permanent atrial fibrillation or permanent pacemakers, and patients who did not undergo follow-up in our center. Procedures performed before 2018 were excluded from our analysis to test our hypothesis on a homogeneously contemporary series.
The institutional Ethics Committee approved the study, and all subjects provided written informed consent.
TAVI procedure
Pre-TAVI workup included baseline electrocardiogram (ECG), transthoracic echocardiography, coronary and peripheral angiography, as well as computed tomography. Implanting technique was standard among operators, following the conventional “minimal approach” previously described3,4,19: all invasive lines were minimized, and procedures were performed under minimal sedation and local anesthesia. Femoral access was obtained using ultrasound guidance and double percutaneous vascular closure (Perclose, Abbott, MN, United States) was placed before non-fractionated heparin administration. During the procedure, all patients received a temporary pacemaker via femoral venous access using a balloon-tipped bipolar catheter (5 French, Arrow, Teleflex, USA) positioned in the right ventricular apex. Pre and post valvular dilation during the intervention were performed according to the operator’s judgement. After implantation, a supravalvular angiography was routinely performed to check for paravalvular leak. At the end of the procedure, an angiography of the main vascular access was performed on all patients to verify arteriotomy closure success as well as ilio-femoral vessel integrity. Until May 2020 (standard-of-care cohort), the temporary pacemaker was kept for 24 hours with monitorization in the cardiac intensive care unit, with later transfer to the cardiology ward. Permanent pacemaker was implanted in the presence of persistent or new-onset complete or high degree AV block.
Since June 2020, the procedure was modified to routinely include: a) COP during valve deployment to assess implantation depth, and b) RAP at the end of the procedure in the absence of complete AV block, at rates of 70 to 120 beats/min (or until pacing-induced Wenckebach heart block was observed) in 10 beats/min increments for a total of 20 beats at each increment.18 In patients with persistent complete AV block, permanent pacemaker was placed in the same day. In the absence of immediate complications, patients were transferred to a standard monitored ward bed minimizing ICCU stay unless clinically needed, and temporary pacemaker surveillance was only maintained for 24 hours in the presence of Wenckebach phenomenon or in patients with AV block until permanent pacemaker was implanted. Final determination of patient discharge was based on patient’s characteristics and clinical status by the referring physician.
Follow-up
After implantation, assessment included ECG, echocardiogram, in-hospital, and 90-day clinical follow-up. All patients’ clinical, procedural, in-hospital information, and follow-up data were collected from the electronic medical records.
Study endpoints
The primary safety and efficacy outcomes were complete AV block after implantation with COP and the diagnostic performance of RAP added to COP in self-expandable valves.
The secondary endpoints included the length of hospitalization following TAVI and the composite major adverse cardiovascular events, defined as cardiovascular mortality, PPI, rehospitalization for heart failure decompensation, stroke, and major bleeding and vascular complications occurring 90 days after hospital discharge. In addition, rehospitalizations for healthcare-associated infections within the same period were analyzed separately.
Statistical analysis
Categorical variables are presented as counts (percentages) and were compared using the chi-square test. Continuous variables were tested for normality of distribution by using the Shapiro-Wilk test. According to their distribution, continuous variables are expressed as mean ± standard deviation or median values with interquartile range [IQR], and were compared using Student t test, ANOVA or Wilcoxon test, as appropriate. For the multivariate analysis, we first selected baseline variables that showed a significant association with the outcome (P < .2) and performed single logistic regression. Variables with a P-value < .05 were entered into a multiple logistic regression analysis. Odds ratios (OR) were calculated using uni and multivariate logistic regression, along with 95% confidence intervals. Statistical analyses were conducted using RStudio 4.1.20 P-values < .05 were considered significant.
RESULTS
Baseline characteristics
A total of 273 patients met the inclusion criteria for the analysis. Among them, 134 underwent standard implantations, and 139 underwent the combined use of COP and RAP (COP+RAP) (figure 1). Mean patient age was 81 ± 7 years old and 51.3% were female, with similar prevalence of cardiovascular risk factors and comorbidities between groups. Patients in the standard-of-care group showed a worse NYHA functional class, and there were no differences in the surgical risk (table 1). Both cohorts presented similar rates of conduction disturbances at baseline. The mean transvalvular pressure gradient by ultrasound was 47 [41-58] mm Hg with no significant differences on baseline findings between groups. The COP+RAP group showed a higher valvular calcium score (2429 [1577-3557] Agatston units) and larger left ventricular outflow tract and annular perimeters (P = .006 and P = .04 respectively) (table 1).
Figure 1. Patient flow chart. AF, atrial fibrillation; COP, cusp-overlap projection; RAP, rapid atrial pacing TAVI, transcatheter aortic valve implantation.
Table 1. Demographics, baseline electrocardiographic and imaging characteristics
| Variables | Standard of care (n = 134) | COP + RAP (n = 139) | P value |
|---|---|---|---|
| Female gender | 71 (53.0) | 69 (49.6) | .66 |
| Age (years old) | 81 [76-85] | 81 [75-85] | .77 |
| Hypertension | 112 (83.6) | 08 (77.7) | .28 |
| Diabetes | 47 (35.1) | 52 (37.4) | .78 |
| BMI | 27.2 [24.5-30.4] | 27.5 [25.0-30.0] | .99 |
| Betablockers | 31 (23.1) | 40 (28.8) | .36 |
| Ischemic heart disease | 37 (27.6) | 39 (28.1) | 1.00 |
| HF decompensation within 12 months | 34 (25.4) | 43 (30.9) | .38 |
| Baseline GFR (mL/min) | 61 [43-79] | 54 [40-75] | .12 |
| Prior stroke/TIA | 15 (11.2) | 8 (5.8) | .16 |
| Active neoplasia | 11 (8.2) | 10 (7.2) | .93 |
| NYHA functional class III-IV | 87 (64.9) | 63 (45.3) | < .001 |
| Syncope | 11 (8.2) | 11 (7.9) | 1.00 |
| EuroSCORE II | 2.80 [1.80-4.40] | 3.20 [1.70-5.15] | .63 |
| Electrocardiographic variables | |||
| Baseline PR interval length (ms) | 180 [160-200] | 172 [150-200] | .21 |
| First degree atrioventricular block | 21 (15.9) | 27 (19.4) | .63 |
| Paroxysmal atrial fibrillation | 16 (11.9) | 19 (13.7) | .8 |
| QRS length (ms) | 100 [90-120] | 97 [90-112] | .11 |
| Left bundle branch block | 14 (10.4) | 9 (6.5) | .27 |
| Right bundle branch block | 17 (12.7) | 18 (12.9) | 1.00 |
| Echocardiographic variables | |||
| Left ventricular ejection fraction (%) | 60 [55-60] | 60 [57-63] | .51 |
| Interventricular septum thickness (mm) | 13 [11-14] | 13 [12-14] | .56 |
| Aortic valve peak gradient (mmHg) | 77 [69-92] | 74 [65-94] | .27 |
| Aortic valve mean gradient (mmHg) | 48 [42-58] | 46 [41-58] | .39 |
| III-IV aortic regurgitation | 21 (15.7) | 24 (17.3) | .56 |
| Aortic calcium score (AU) | 2110 [1455-3495] | 2586 [1682-3590] | .31 |
| Annular perimeter (mm) | 74 [69-80] | 77 [71-3] | .04 |
| LVOT perimeter (mm) | 72.0 [67.0-77.2] | 74.0 [71.0-83.0] | .006 |
|
BMI, body mass index; GFR, glomerular filtration rate; HF, heart failure; LVOT, left ventricular outflow tract; MI, myocardial infarction; NYHA, New York Heart Association; TIA, transient ischemic attack. Data are expressed as no. (%) or median [interquartile range]. |
|||
Procedure and in-hospital outcomes
Procedural details are listed in table 2. All patients underwent TAVI under conscious anesthesia, with more frequent use of midazolam and fentanyl in the COP+RAP cohort in place of dexmedetomidine (P < .001). Also, in line with current recommendations for self- expandable valves, the rate of predilation was significantly higher in the COP+RAP group (P < .001).
The occurrence of intraprocedural conductance disorders was lower with COP in the COP+RAP group (25.8% vs 14.4%; P = .007; OR, 0.49; 95%CI, 0.27-0.91; P = .026) mainly due to a reduction in temporary complete AV block (table 2), whereas rates of new-onset first degree AV block and atrioventricular block (LBBB) remained similar between groups. Same day permanent pacemaker was implanted in 16 patients of the COP+RAP group with persistent AV block. RAP revealed Wenckebach phenomenon at a median stimulation rate of 115 bpm in 24 patients and allowed to reduce the need for temporary pacemaker surveillance from 91.8 % in the standard-of-care group to 28.1 % of the cases in the COP+RAP group (P < .001). Among the patients in the COP+RAP cohort who did not develop Wenckebach phenomenon (n = 98/122, 80.3%), permanent pacemaker was required in only 3% of patients (OR, 0.16; 95%CI, 0.03-0.76; P = .02; negative predictive value = 97%; 95%CI, 91-99%. Patients with pacing-induced Wenckebach had a higher risk of PPI during admission (OR, 6.33; 95%CI, 1.30-34.29; P = .021; positive predictive value 79% 95%CI, 58-93%).
Table 2. Procedural characteristics, electrocardiographic and imaging outcomes
| Variables | Standard of care (n = 134) | COP + RAP (n = 139) | P value |
|---|---|---|---|
| Procedure | |||
| Pre-dilatation | 22 (16.4) | 72 (51.8) | < .001 |
| Post-dilatation | 37 (27.6) | 30 (21.6) | .31 |
| Bicuspid | 9 (6.7) | 15 (10.8) | .33 |
| Valve-in-valve | 7 (5.2) | 9 (6.5) | .85 |
| Prothesis type | < .001 | ||
| Evolut Pro | 93 (69.4) | 71 (51.1) | |
| Portico/Navitor | 41 (30.6) | 68 (48.9) | |
| Procedure time (min) | 88 [70-104] | 80 [65-100] | .18 |
| Temporary pacemaker surveillance 24 hours, n (%) | 123 (91.8) | 39 (28.1) | < .001 |
| ICCU surveillance | 115 (88.5) | 32 (23) | < .001 |
| Post procedure electrocardiogram | |||
| Intraprocedural complete AV block | .007 | ||
| Persistent | 17 (12.8) | 16 (11.5) | |
| Transient | 17 (12.8) | 4 (2.9) | |
| Post PR interval length (ms) | 200 [160-232] | 187 [160-220] | .33 |
| Post QRS length (ms) | 120 [100-150] | 127 [100-150] | .93 |
| De novo 1st degree AV block (N = 242) | 24 (21.8) | 25 (18.9) | .69 |
| De novo left bundle branch block | 40 (29.9) | 39 (28.3) | .88 |
| De novo atrial fibrillation, n (%) | 13 (9.7) | 7 (5.0) | .21 |
| Post-procedure echocardiography | |||
| Left ventricular ejection fraction (%) | 60 [60-64] | 60.0 [60-60] | .65 |
| Aortic valve mean gradient (mmHg) | 9 [6-12] | 8 [6-12] | .83 |
| Moderate residual AR | 3 (2.3) | 1 (0.7) | .32 |
|
AR, aortic regurgitation; AV, atrioventricular; ICCU, intensive cardiac care unit. Data are expressed as no. (%) or median [interquartile range]. |
|||
Incidence of AV block and timing of PPI after TAVI is shown in figure 2. Delayed AV block (developed > 48 hours after TAVI) during admission occurred in 8.2% patients in the standard group and 3.6% of the COP+RAP group (P = .14) mostly in the presence of new-onset LBBB (68% of the cases). Adding both maneuvers did not impact the procedure length or led to adverse events, with a low and similar rate of in-hospital complications among groups (table 3). Additionally, reduction of the implantation depth did not lead to a higher rate of residual significant aortic regurgitation (P = .32).
Figure 2. Immediate complete AVB and on-admission permanent pacemaker implantation trends. Upper: intraprocedure cusp-overlap projection and Wenckebach phenomenon during atrial pacing. Midd: comparison of immediate AVB in standard and protocol groups. Bottom: trend in pacemaker implantation during admission. AVB, atrioventricular block; COP, cusp-overlap projection; RAP, rapid atrial pacing TAVI, transcatheter aortic valve implantation.
Table 3. Immediate, and short-term outcomes
| Variables | Standard of care (n = 134) | COP + RAP (n = 139) | P value |
|---|---|---|---|
| In-hospital | |||
| Pacemaker on admission | 35 (26.1) | 23 (16.5) | .07 |
| Acute kidney failure | 11 (8.2) | 6 (4.3) | .29 |
| Stroke | 2 (1.5) | 1 (0.7) | .62 |
| Severe bleeding | 6 (4.5) | 3 (2.2) | .33 |
| Major vascular complication | 7 (5.2) | 4 (2.9) | .21 |
| Hospitalization length (days) | 5 [4-8] | 2 [1-4] | < .001 |
| Discharge within 48 hours | 10 (7.5) | 79 (56.8) | < .001 |
| 90 days follow-up | |||
| Pacemaker cumulative incidence | 39 (29.1) | 26 (18.7) | .049 |
| HF admission | 12 (9.1) | 7 (5.0) | .29 |
| Stroke/TIA | 4 (3.0) | 2 (1.4) | .44 |
| Major bleeding | 7 (5.3) | 2 (1.4) | .09 |
| Major vascular complication | 5 (3.8) | 2 (1.4) | .22 |
| Cardiovascular death | 2 (1.5) | 1 (0.7) | .62 |
| Composite MACE at 90 days | 27 (20.1) | 14 (10.1) | .031 |
| Infection-related readmission | 14 (10.6) | 5 (3.6) | .04 |
|
HF, heart failure; MACE, major adverse cardiac event; TIA, transient ischemic attack. Data are expressed as no. (%) or median [interquartile range]. |
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The reduction of stay in the intensive care unit along with the lower rate of 24-hour temporary pacemaker surveillance, significantly decreased the length of hospitalization in the COP+ RAP cohort (−3.0 [−2.5 to −3.5] days, P < .0001), enabling to discharge patients within 48 hours in 56.8% of the cases compared to 7.5% in the standard-of-care group (P < .001).
90-day outcomes
At 90-days, the cumulative rate of PPI in the COP+RAP cohort persisted lower than in the standard-of-care group (29.5% vs 18.7%; P = .049). Of all 65 pacemaker implantations, 58 (89%) occurred during the index admission and 7 (11%) following hospital discharge. Among the 3 patients from the COP+RAP requiring late PPI, 2 developed with new-onset LBBB (QRS width 127 and 136 ms respectively), and both had displayed Wenckebach phenomenon at 120 bpm. They were monitored with temporary pacemaker for 24 hours without events but developed high degree AV block within 48 hours after discharge (day 4 after TAVI). The third patient had new-onset first degree AV block (PR interval 240 ms), Wenckebach phenomenon at 120 bpm and narrow QRS (118 ms) but developed high-degree AV block at day 55. No patients with a negative RAP test required late PPI. The univariate logistic analysis of potential baseline and procedural factors of PPI after TAVI is reported in table 4. Interestingly, differences in sedation, predilation, valve model (P = .98) and bicuspid valves (P = .71) did not influence the risk of PPI after TAVI. In the multivariate analysis, prior 1st degree AV block, baseline right bundle branch block, prosthesis posdilation and new-onset LBBB were associated with PPI. The combination of COP with RAP decreased the need of PPI on a 90-day follow-up (OR, 0.48; 95%CI, 0.24-0.92; P = .031) (figure 3).
Figure 3. Odds plot of multivariate analysis of 90-day permanent pacemaker implantation predictors. 95%CI, 95% confidence interval; AVB, atrioventricular block; COP, cusp-overlap projection; LBBB, left bundle branch block; PPI, permanent pacemaker implantation; RAP, rapid atrial pacing; RBBB, right bundle branch block.
Table 4. Main factors associated with PPI after TAVI: unadjusted logistic regression analysis of PPI predictors at 90 days
| Variables | OR (95%CI) | P value |
|---|---|---|
| Age | 0.99 (0.93-1.03) | .93 |
| Betablockers | 0.92 (0.47-1.72) | .80 |
| Baseline 1st degree AVB | 3.65 (1.88-7.10) | < .001 |
| Baseline RBBB | 6.91 (3.28-15.02) | < .001 |
| Baseline LBBB | 0.90 (0.29-1.38) | .84 |
| Annulus perimeter | 1.00 (0.99-1.01) | .74 |
| LVOT perimeter | 1.05 (0.98-1.05) | .34 |
| Sedation | 1.54 (0.88-2.71) | .13 |
| Pre-dilatation | 0.87 (0.47-1.56) | .64 |
| Post-dilatation | 1.83 (0.98-3.36) | .05 |
| New-onset 1st degree AVB | 1.46 (0.65-3.08) | .34 |
| New-onset LBBB | 1.65 (0.90-2.97) | .09 |
| COP + RAP | 0.55 (0.31-0.96) | .04 |
|
AVB, atrioventricular block; COP, cusp overlap projection; LBBB, left bundle-branch block; RAP, rapid atrial pacing; RBBB, right bundle-branch block. |
||
The COP+RAP group presented a significantly lower percentage of the secondary composite endpoint than the standard-of-care cohort (20.1% vs 10.1%; P = .031). The rates of HF readmission, and mortality were low and similar across groups during the follow-up period (table 3). None of the 3 deaths during follow-up were due to rhythm disturbances. At 90 days, there was a reduction in the number of readmissions due to admission-related infections in the COP+RAP cohort (OR, 0.35; 95%CI, 0.12-0.89 P = .036) (figure 4), with an 8.6 % reduction in the odds of infection for each day of reduced hospitalization (OR, 0.91; 95%CI, 0.85-0.99; P = .023). The most common were urinary (47.4%) and respiratory (42.1%) infections. None of the patients presented infections related to PPI.
Figure 4. Central illustration. Main immediate and short-term findings of combining cusp-overlap projection and rapid atrial pacing when implanting self- expandable valves. OR, odds ratio; TAVI, transcatheter aortic valve implantation.
DISCUSSION
In the present study we demonstrate that combining the COP with RAP, COP reduces the risk of complete AV block after self- expanding TAVI and negative RAP after implantation adequately dismiss underlying AV conduction disturbances requiring PPI.
This strategy reduces the need of temporary PPI and the appearance of late onset AV block, and safely allows an early discharge in sinus rhythm patients receiving a self-expandable valve. Reducing hospital stays lead to a significant reduction in admission-related infections at short-term follow-up (figure 4).
A minimalistic approach in TAVI has become progressively relevant as a way of simplifying the intervention and promoting early recovery.4,6-8 Multiple studies have shown that early discharge after TAVI is possible, preserving the high standards of effectiveness, patient safety and outcomes.3,9,21 However, most of these studies included highly selected patients, with a predominance of balloon-expandable valves, and might not be representative in the current TAVI scenario. Evidence at the beginning of minimalistic TAVI inception found self-expanding prothesis to be a predictor for rhythm disturbances and delayed discharge.5,6 Since their risk of AV conduction disturbances remain in the range of 5% to 30% even with contemporary transcatheter heart valves10,12-14 and there is no appropriate way to assess the risk of AV block development, self-expandable valves have been underrepresented in early discharge protocols so far.3,7,22,23
Postimplantation conduction disturbances remains one of the current weaknesses in TAVI, and great heterogeneity of recommendations persist regarding their management.24,25 In this regard, the aim of our study was to minimize the appearance and improve the assessment of conduction disturbances without increasing invasiveness in patients receiving self-expandable valves, by combining 2 well-described maneuvers.
Guiding the procedure using the COP has already been established as an effective method to guide implantation depth.16,17 Isolating the non-coronary cusp allows a better identification of the most inferior point of the aortic annulus, leading to a higher (more aortic) valve positioning, which in turn reduces the risk of post-TAVI conduction disturbances. Various observational studies have described the COP technique in distinct types of self-expandable valves,15-17,26 and highlighted its potential benefits in decreasing the PPI rate in the Evolut (Medtronic, United States) and the Portico (Abbott Structural Heart, United States) valves.27 In line with these studies, in our cohort, COP significantly decreased the emergence of intra-procedural transient and late onset ( > 48 hours) high-grade AV block irrespectively of the self-expandable valve type, with no noticeable impact on the rate of new-onset LBBB, that remained around 29% in both cohorts.
After implantation, current consensus documents recommend temporary pacemaker surveillance for at least 24 hours. Further management depends on baseline intra-procedure, and post-procedure conduction disturbances,25,28 that can result in longer duration of temporary pacemaker placement or prolonged inpatient rhythm monitoring. In this context RAP, emerges as an easy and interesting strategy to discriminate which patients may require monitoring. Since its publication in 2020,18 different works have recognized the underuse of this technique, although is an important component of routine electrophysiological studies to “stress” the AV conduction.10 It has the limitation of assessing specifically at the level of the atrio-His interval but seems to be a good indicator of patients with underlying conduction disorders with a described strong negative predictive value for PPI in the absence of Wenckebach phenomenon. In our study, the rate of Wenckebach phenomenon during dynamic atrial stimulation was 19.8% and showed a moderate positive predictive value. However, most importantly, the absence of RAP-induced AV block displayed a very high negative predictive value of PPI during follow-up. These results are in agreement with the previous report of RAP on balloon-expandable valves,18 showing adequate reliability of AV Wenckebach testing over delayed conduction disturbances immediately at the end of the procedure in self-expandable valves. The improvement in valve deployment and risk stratification of AV conduction disturbances allowed us to reduce temporary pacemaker surveillance in 63.1% of cases, with less late-onset high-degree AV block and no impact in procedure length or complications, leading to early recovery and minimizing functional decline. Moreover, although early discharge protocols described so far have focused on demonstrating safety, it should be noted that in our simplified protocol cohort there was a significant reduction in the healthcare-related infection readmission rate at 90 days. The reduction in the incidence of admission-related respiratory and urinary infections was likely attributable to the shortened length of hospitalization, that has been associated with adverse events.5 Observed differences in major adverse cardiovascular events, although significant, should be interpreted cautiously, as part of the findings might be a result of technological advances and cumulative expertise.
The adequacy of these combined maneuvers was patent in the multivariate analysis and in the maintained differences in PPI rate at a 90-day follow-up. Nevertheless, special caution should be recommended in patients developing persistent LBBB after TAVI, as it was a predictor of delayed AV block and PPI. These patients would probably benefit from longer monitoring, and in the presence of new-onset LBBB or Wenckebach-induced phenomenon, a formal electrophysiological study or continuous ECG monitoring might have the potential to risk-stratify patients with unclear indications of PPI following TAVI.29-31
Limitations
This is a single-center study with a modest sample size and an observational design; therefore, there is an inherent potential bias due to patient selection. First, both cohorts are not contemporary, which may introduce bias related to technological advancements or increased operator experience over time. Second, RAP is restricted to patients in sinus rhythm, and the cutoff of 120 beats/min for maximum RAP rate was selected according to previous literature but may be insufficient as low risk patients tend to be young and might request testing at higher heart rates. Also, RAP stresses the AV conduction at the atrio-His level, and therefore our results might not properly assess patients with broadened QRS, as high-grade conduction block occurs at the His-Ventricular segment.18,30,31 Third, our protocol has the inconvenience of requiring temporary pacemaker so it can be moved to the atrium at the end of the procedure, which is not feasible in procedures performing pacing through the left ventricular wire. However, we believe it might be a safe and efficient way to risk-stratify patients immediately after the procedure. Finally, our study was focused on patients in sinus rhythm and self-expanding prothesis and therefore the results and conclusions should be interpreted in this context.
CONCLUSIONS
Combining COP during deployment with RAP immediately after TAVI diminishes the incidence of postprocedural AV block and improves the screening of underlying atrio-His conduction disturbances in patients receiving a self-expandable valve. In turn, this allows to reduce the length of temporary pacemaker surveillance and admission days, with differences in PPI rate maintained at a 90-day follow-up. Optimizing strategies of care after TAVI has a significant impact at short-term, driven by a significant reduction in readmissions due to infections.
FUNDING
M. Tamargo was partially supported by grants from the Fundación para la Investigación Biomédica Gregorio Marañón, Spain, and Rio Hortega CM20/00054 from the Instituto de Salud Carlos III, Spain. J. Bermejo was partially supported by INT22/00025 from the Instituto de Salud Carlos III, Spain.
ETHICAL CONSIDERATIONS
The institutional Ethics Committee approved the study, and all subjects provided written informed consent. This manuscript complies with the guidelines of the SAGER guidelines, and possible gender and/or age differences have been taken into account, without significant differences being observed.
STATEMENT ON THE USE OF ARTIFICIAL INTELLIGENCE
No artificial intelligence has been used in the development of this paper.
AUTHORS’ CONTRIBUTIONS
All authors comply with the international characteristics of authorship of scientific articles. Conception and design: M. Tamargo, J. García Carreño, E. Gutiérrez, J. Bermejo, F. Fernández-Avilés. Data collection: M. Tamargo, M. Huanca, E. Ludeña, J. García Carreño. Analysis: M. Tamargo E. Gutiérrez, J. Bermejo. The manuscript was reviewed and approved by all authors.
CONFLICTS OF INTEREST
Nothing to disclose.
WHAT IS KNOWN ABOUT THE TOPIC?
- The potential need of PPI after TAVI frequently prolongs hospital admissions for the purpose of rhythm monitorization.
- Self-expandable valves relate to higher rates of PPI, and thereby have been usually excluded from early-discharge protocols in TAVI.
WHAT DOES THIS STUDY ADD?
- The present study demonstrates that combining COP with RAP leads to a better risk stratification of conduction disturbances after TAVI and a reduction of hospitalization length, with a lower permanent pacemaker rate at 90-day follow-up.
- This seems to significantly impact post-TAVI care in short-term admission-related infections.
- Further research regarding risk factors for events and protocolization of early discharge for an optimal management of TAVI patients is still required.
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Editorials
Original articles
Editorials
Infective endocarditis in surgical versus transcatheter aortic valve implantation. Same incidence and same prognosis?
aServicio de Cardiología, Hospital Clínico Universitario de Valladolid, Instituto de Ciencias del Corazón (ICICOR), Valladolid, Spain
bCentro de Investigación Biomédica en Red de Enfermedades Cardiovasculares (CIBERCV), Spain
Original articles
Debate
Debate: Intravascular imaging in percutaneous revascularization procedures
For a more widespread approach
aServicio de Cardiología, Consorcio Hospital General Universitario de Valencia, Valencia, Spain
bServicio de Cardiología, Hospital QuironSalud Valencia, Valencia, Spain
For an optimized and still selective approach
aServicio de Cardiología, Hospital del Mar, Barcelona, Spain
bCentro de Investigación Biomédica en Red de Enfermedades Cardiovasculares (CIBERCV), Spain
