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Comparison of high-power single-ring isolation and box isolation in elderly patients with persistent atrial fibrillation

BMC Geriatrics volume 25, Article number: 344 (2025) Cite this article

Abstract

Background

This study evaluated the superiority of single-ring isolation (SRI) over box isolation using high power in elderly patients with persistent atrial fibrillation (PeAF).

Methods

We retrospectively studied elderly patients with PeAF who underwent primary catheter ablation. The patients were divided into the SRI group and the posterior box isolation (BOXI) group. Basic characteristics, procedural variables, complications and atrial arrhythmia recurrence rates were collected.

Results

Forty-five pairs of patients in the two groups were matched by 1:1 PSM. Compared with that in the BOXI group, the total procedure time in the SRI group was not significantly different (P = 0.340). However, there were significant reductions in the total ablation time, ring ablation lesions and number of lesions on the posterior wall in patients who underwent SRI compared to those who underwent BOXI (all P < 0.001). The cardiac troponin level in the SRI group was significantly lower (P = 0.023). There were significantly fewer mismatched three-dimensional mapping models and mismatched models per patient due to pain-induced movement in the SRI group (all P < 0.05). The questionnaires revealed that the pain score was significantly lower in the SRI group than in the BOXI group (P < 0.001). In addition, significantly fewer patients with SRI than with BOXI experienced gastrointestinal symptoms after the procedure (15.56% vs. 37.78%, P = 0.017). K‒M analysis revealed no significant difference in atrial arrhythmia-free survival at 12 months between the SRI and BOXI patients (P > 0.05).

Conclusions

High-power SRI is safe and feasible and may be superior to the BOXI for experience of elderly patients with PeAF.

Peer Review reports

Introduction

Pulmonary vein isolation (PVI) is the cornerstone for atrial fibrillation (AF) catheter ablation based on the crucial observation of electrical triggers of AF in the pulmonary veins (PVs) [1]. However, PVI alone seems insufficient, with lower rates of long-term success for nonparoxysmal AF, and further modification of the atrial substrate may be necessary [2]. Electrical isolation of the posterior wall (PW) is an important aspect of the management of persistent AF (PeAF) by electrophysiologists [3], which not only reduces the critical mass for the maintenance of AF but also decreases the number of rotors and multiple wavelets in the anterior wall, inferior wall and left atrium (LA) appendages during PeAF [4]. Posterior box isolation (BOXI) or single-ring isolation (SRI) can be applied to electrically isolate the PW. A recent study revealed that posterior BOXI for patients with PeAF resulted in significant left atrial reverse remodelling with a high rate of clinical success [5]. However, the available evidence suggests that BOX ablation can also cause damage to the oesophagus or vagal branches of the stomach [6, 7] and even catastrophic complications, such as atrio-oesophageal fistula [8,9,10,11].

SRIs are carried out based on physiological principles to electrically isolate the posterior LA and PVs. This approach limits the amount of ablation in the posterior LA, shortens the ablation time and has the potential to reduce collateral damage to the oesophagus, preventing the formation of atrial oesophageal fistula [12, 13]. Recently, high power (HP, 40–50 W) has been shown to create continuous and transmural lesions and has been demonstrated to be safe and effective in terms of clinical outcomes and lesion markers compared to conventional ablation with low power [14]. However, BOX ablation with HP still causes intractable intraoperative pain and oesophageal and vagal branch injury, especially in elderly patients, due to their greater susceptibility to gastroesophageal reflux disease.

To date, the efficacy of SRI ablation with a power of 40–45 W in elderly patients with PeAF remains unknown. Therefore, the aim of this study was to determine the feasibility and safety of SRI with inferior line sparing at high power for elderly patients with PeAF.

Materials and methods

Study population

A total of 501 consecutive patients with drug-refractory and symptomatic AF were retrospectively enrolled in this study. The patients were admitted to our centre and received first-time RFCA for AF from October 2017 to February 2023 at Wujin People’s Hospital. The exclusion criteria included (1) age < 65 years; (2) paroxysmal atrial fibrillation; (3) a history of RFCA for AF; (4) other RFCA strategies; (5) duration of atrial fibrillation > 10 years; (6) left atrial diameter (LAD) > 56 mm; and (7) lack of essential data.

The enrolled patients were divided into the BOXI group and the SRI group according to the ablation approach used to treat AF. In the SRI group, patient enrollment primarily occurred between December 2021 and January 2023. During this period, the SRI procedure for all eligible patients with PeAF were consistently performed by two experienced electrophysiologists of our centre.

Our study protocol was performed in accordance with the Helsinki Declaration and was approved by the Ethics Committee of Wujin Hospital Affiliated with Jiangsu University (2023-SR-055).

Variables and definitions

Basic characteristics, including sex, age, body mass index (BMI), history of hypertension, type 2 diabetes mellitus (T2DM), coronary artery disease (CAD), ischaemic stroke, left atrium diameter (LAD), left ventricular ejection fraction (LVEF), and CHA2DS2-VASc score, were collected from the electronic medical records of all included patients. Variables of the ablation procedure, including the total procedure time, total ablation time, total ablation lesions, initial ring lesions, visual analogue scale (VAS) score and complications, were collected. Venous blood samples were obtained from all patients in a fasting state on the morning following admission. Plasma lipid parameters, including total cholesterol (TC), triglyceride (TG), high-density lipoprotein cholesterol (HDL-C) and low-density lipoprotein cholesterol (LDL-C), were evaluated using standard techniques. Venous blood for detecting cardiac troponin (cTnI) was collected 24 h after the procedure.

The VAS score [15] was used to rate pain during entire ablation process with a 10-cm straight line divided into 10 equal marks, with 0 indicating no pain and 10 indicating intolerable pain.

Mismatch of three-dimensional (3D) mapping models was defined as displacement and transient procedure interruption resulting from pain-induced body movement.

Catheter ablation procedure

Procedures were performed under conscious sedation using intravenous fentanyl for anaesthesia. A decapolar catheter (APT Medical, China) was placed in the coronary sinus. After double transseptal punctures, a deflectable PentaRay mapping catheter (D128211, Biosense Webster, US) and a 3.5 mm 56-well open irrigated-tip ablation catheter (Thermocool SF, Biosense Webster, US) were advanced into the LA for mapping and ablation via the femoral veins.

3D electroanatomical geometries of the LA and PVs were reconstructed using the pentaray catheter in conjunction with the Carto 3 mapping system after selective PV angiography. Point-by-point PVI was performed using RF energy and a 3.5 mm 56-well irrigated-tip ablation catheter. Intravenous heparin was administered to maintain an activated clotting time of 300 to 350 s. Ablation was performed with an interlesion distance ≤ 5 mm, a power of 40–45 W, a temperature of 43 °C, a flow rate of 15 to 18 mL/min and an ablation index (AI) of 350–380 at the posterior wall and 450–500 at the anterior wall and roof wall. In addition, continuous infusions of heparinized saline were connected to the transseptal sheaths to avoid thrombus or air embolism during the procedures.

PVI was performed with ipsilateral PV isolation in pairs, with an entrance and exit block as the electrophysiological endpoint [16]. In BOXI ablation, PVIs were performed first, followed by linear ablation at the roof and inferior lines connecting the superior and inferior PVs [5]. These lines, combined with bilateral PV isolation, form a “box” around the posterior left atrium (LA) (Fig. 1A). The SRI was performed as follows: anterior to right pulmonary veins, roof, left pulmonary vein ridge, and finally connecting both the inferior PVs with a V-shaped line. This approach creates a continuous circular ablation line encircling all four PVs and the posterior LA in a single loop (Fig. 1B).

Fig. 1
figure 1

A In addition to PVIs, BOXI involves two linear ablation lines (roof and inferior) connecting the superior and inferior PVs, forming a box-shaped isolation zone (red dots). B SRI creates a single continuous circular lesion encircling all four PVs and the posterior LA (red dots), requiring fewer ablation lesions in the posterior LA due to its anatomical efficiency

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When bidirectional conduction block was not achieved, point-by-point activation was performed to identify the earliest breakthrough with the mapping catheter within the ring until all the gaps were abolished.

After ablation, if sinus rhythm was not achieved, a temporary intravenous dose of 1–2 mg of midazolam was administered, followed by external application of ≤ 3 synchronized, biphasic direct current shocks (200 J) to restore sinus rhythm.

The electrical isolation criteria for PW and PVs included [17] (1) dissociation or absence of electrical activity within the ring, (2) the remaining atrium was not captured during pacing of the PW and PVs in sinus rhythm, and (3) associated electrical activity in the PW or PVs was absent when pacing from the coronary sinus catheter.

Postablation Management and follow-up

Patients were scored for intraoperative pain using the VAS on the day after the ablation procedure. After the ablation procedure, intravenous heparin was administered for 1 day to all patients, followed by treatment with warfarin or new oral anticoagulation agents for at least 3 months according to the CHA2DS2-VASc score. All patients were kept on antiarrhythmic drugs for 1 month after ablation unless contraindications were present. The patients were routinely prescribed proton pump inhibitors for 4 weeks after ablation. The patients were followed up at 1, 3, 6 and 12 months after ablation by the referring cardiologists. All patients underwent 24-h Holter recording to determine the incidence of postprocedural atrial arrhythmia at 3, 6 and 12 months after ablation. Recurrence was defined as ≥ 30 s of any atrial arrhythmia, including AF and atrial tachycardia (AT), after a 90-day blanking period.

Statistical analysis

Statistical analysis was performed using SPSS 25.0. Continuous variables were expressed as the mean ± SD, and nonnormally distributed variables were expressed as the median (interquartile range). Categorical variables were presented as frequencies and percentages. Continuous variables were compared by Student’s t test, one-way ANOVA or the nonparametric Mann‒Whitney test, as appropriate. Differences between the two groups were tested using the chi-square test for categorical variables. Recurrence rates during the 12-month follow-up were compared using Kaplan‒Meier analysis. PSM was performed to minimize potential confounding variables. One-to-one nearest-neighbour matching was conducted using a match tolerance of 0.1. All P values were two-sided. A P value less than 0.05 was considered to indicate statistical significance.

Results

A total of 501 patients underwent RFCA for AF from October 2017 to February 2023 at our hospital. Based on the inclusion and exclusion criteria, a total of 141 patients (n = 83 for the BOXI group; n = 58 for the SRI group) were enrolled for further analysis (Fig. 2).

Fig. 2
figure 2

Study flowchart. AF, atrial fibrillation; RFCA, radiofrequency catheter ablation; PsAF, paroxysmal atrial fibrillation; PeAF, persistent atrial fibrillation; PSM, propensity score matching; BOXI, box isolation; SRI, single-ring isolation

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Baseline characteristics of the two groups

The present study included patients [(69 (48.94%) males; 73.15 ± 4.96 years)] with highly symptomatic PeAF before PSM. Some of the differences in the baseline characteristics between the two groups before and after matching are summarized in Table 1. There were significant differences in age and TC and LDL-C levels between the two groups before matching. In our study, a standardized mean difference less than 10% demonstrated a sufficient balance of covariate distribution and high-quality matching between the two groups (Fig. 3). A total of 45 pairs of patients were successfully matched in the two groups by 1:1 PSM. No significant differences were observed in the confounding variables between the two groups after PSM (Fig. 3, Table 1).

Table 1 Comparison of patient characteristics between the two groups before and after propensity score matching
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Fig. 3
figure 3

The clinical baseline data of 19 confounding variables before and after matching between the two groups. LAD, left atrium diameter; TC, total cholesterol; LDL-C, low-density lipoprotein cholesterol; cTnI, cardiac troponin; BMI, body mass index; MAP, mean arterial pressure; EH, essential hypertension; D2M, type 2 diabetes mellitus; CAD, coronary artery disease; HF, heart failure; NT-proBNP, N-terminal pro-B type natriuretic peptide; GERD, gastroesophageal reflux disease; TG, triglyceride; HDL-C, high-density lipoprotein cholesterol; LVEF, left ventricular ejection fraction

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Differences in procedure-related variables between the two groups after PSM

Electroanatomic maps of the LA in posteroanterior and right lateral views for the two ablation methods are shown in Fig. 1a and b, respectively. Posterior left atrium isolation was achieved, and AF was terminated after the procedure in all patients. The differences in procedure-related variables between the two groups were examined and are summarized in Table 2. The total procedure time did not differ between the SRI group and the BOXI group (P = 0.340). However, the procedure time from the 26th case to the 45th case in the SRI group was significantly shorter than that in the BOXI group (186.04 ± 38.69 vs. 224.60 ± 49.79, P = 0.004). The total ablation time in patients who underwent SRI was significantly shorter than that in patients who underwent BOXI (55.23 ± 9.93 min vs. 68.97 ± 13.59 min, P < 0.001). Notably, the average ablation time from the 26th case to the 45th case with SRI was only 47.92 ± 4.43 min. There were significantly fewer ring ablation lesions in the SRI group than in the BOXI group (P < 0.001). Moreover, the number of lesions on the posterior wall in the SRI group was significantly lower than that in the BOXI group (P < 0.001). There was no significant difference in the first pass isolation rate between the SRI group and the BOX group (71.11% vs. 75.55%, P = 0.634). In addition, the cTnI level in the SRI group was significantly lower than that in the SRI group (P = 0.023). The 3D mapping models were mismatched due to pain-induced movement in significantly fewer patients in the SRI group (8.89% vs. 26.67%, P = 0.027) (Table 3). The average number of mismatched 3D mapping models per patient was also significantly lower in the SRI group (P = 0.025).

Table 2 Procedural characteristics of the matched groups
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Table 3 Comparison of procedure-related pain scores and complications between the matched groups
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In addition, immediate sinus rhythm was achieved in 15 (33.33%) patients who underwent SRI after ablation but in only 7 (15.56%) patients who underwent BOXI (P = 0.043). Similarly, < 2 synchronized, biphasic direct current (DC) shocks were used to restore sinus rhythm in 64 patients: 29 (64.44%) in the SRI group and 35 (77.78%) in the BOXI group. The proportion of patients who needed DC shocks to terminate AF were significantly lower in patients with SRI than in those with BOXI (P < 0.05).

Comparison of procedure-related pain scores and complications between the matched groups

Pain scores during the procedure were retrospectively investigated from patients using VAS by the cardiologists on the day after ablation. The results of the questionnaires revealed that pain scores were significantly lower in the SRI group than in the BOXI group (3.40 ± 1.05 vs. 5.53 ± 1.27, P < 0.001).

No major procedure-related complications, including death, cardiac perforation, or atrioesophageal fistula, occurred in any of the study patients. Fever occurred in 7 patients overall; 2 (4.44%) and 5 (11.11%) in the SRI and BOXI groups, respectively. In addition, 7 patients in the SRI group (15.56%) and 17 patients in the BOXI group (37.78%) experienced gastrointestinal symptoms after the procedure, including chest pain, nausea, and vomiting (P = 0.017) (Table 3).

Atrial arrhythmia–free survival rates

The mean follow-up period was not significantly different between the SRI group and the BOXI group [13.42 ± 1.69 months vs. 13.09 ± 1.49 months, P > 0.05]. No patients underwent a second ablation procedure during the 90-day recovery period. At the most recent follow-up visit, AF recurrence was detected in 6 patients in the SRI group and 7 patients in the BOXI group. Eight additional patients with AT in each group were observed. The pattern of atrial arrhythmia–free survival is shown in Fig. 4 by Kaplan‒Meier curves. No significant difference was noted in atrial arrhythmia-free survival at 12 months for SRI and BOXI patients (12-month atrial arrhythmia-free survival: 75.6% [73.2%-86.7] for SRI vs. 73.3% [71.1%-91.1%] for BOXI; P > 0.05) (Fig. 4).

Fig. 4
figure 4

Kaplan–Meier plots of atrial arrhythmia-free survival. K‒M survival plots comparing atrial arrhythmia (atrial fibrillation or atrial tachycardia)-free survival between the single-ring isolation (SRI) group and the box isolation (BOXI) group on the posterior wall of the left atrium

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Discussion

In this single-centre, retrospective study, we investigated differences between SRI and BOXI with high power in elderly patients with PeAF in terms of efficacy and safety. There were four key findings. First, the total ablation time, number of ablation lesions and extent of myocardial injury in the SRI group were significantly lower than those in the BOXI group. Second, the proportion of patients with immediate sinus rhythm was significantly greater in the SRI group during the ablation procedure. Third, a significant reduction in procedure-related gastrointestinal symptoms, pain scores and mismatched 3D mapping models due to pain-induced movement was observed in patients who underwent SRI compared to those who underwent BOXI. Fourth, the 12-month atrial arrhythmia recurrence rate did not differ significantly between the two groups. The study design and main findings were showed in the Central illustration (Fig. 5).

Fig. 5
figure 5

Central Illustration. Compared with BOXI, there were significant reductions in the total ablation time (A), VAS score (B) and number of mismatched 3D mapping models per patient due to pain-induced movement (C) in SRI. ***, P < 0.001; *, P < 0.05; BOXI = posterior box isolation; SRI = single-ring isolation; PeAF = persistent atrial fibrillation; RFCA = radiofrequency catheter ablation; PSM = propensity score matching

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The prevalence of gastroesophageal disorders, such as gastroesophageal reflux disease (GERD), has been reported to markedly increase with age [18]. A previous study showed that the incidence of GERD was as high as 23% in elderly residents of American nursing facilities [19]. GERD was reported to be associated with oesophageal injury after RFCA [12]. Therefore, reduced ablation of the PW in elderly patients may be an important strategy to avoid oesophageal injury. Similarly, in our study of elderly patients with AF, there was also a high rate of GERD (16.67%). Therefore, greater concern regarding oesophageal injury in PW ablation should be directed towards this patient population. Previous studies have demonstrated that the SRI plays an important role in decreasing the ablation time [12, 13]. The findings of the present study align with this, as the ablation time of the SRI group was significantly shorter than that of the BOXI group (P < 0.001). Compared with the BOXI technique, the SRI technique eliminates the need to create two additional ablation lines between the roof and inferior aspects of the posterior wall. This results in a significant reduction in total posterior wall ablation lesions (SRI: 17.78 ± 4.88 vs. BOXI: 40.16 ± 10.24; P < 0.001). The reduced lesion count in SRI aligns with its physiological design to isolate the PVs and posterior LA with a single, contiguous line rather than multiple interconnected lines, potentially lowering the risk of esophageal injury associated with energy delivery near the esophagus.

Nevertheless, regarding total procedure time, our results failed to show a significant difference between the groups. These results are similar to those of a previous report in which PVI was achieved with a similar procedure time [20]. It is difficult for inexperienced operators to achieve the isolation of PVs and PW by a single ring without additional segmental lesions within the ring, which may increase the procedural time. Some anatomical considerations for successful SRI should be considered. The left atrial diverticulum, a characteristic anatomical structure of the LA, is often adjacent to the right superior pulmonary vein. However, due to the insertions of fibres from the epicardium, achieving SRI may pose challenges if the roof line is anterior to the diverticulum. In addition, an anterior roof line may transversely cross the Bachmann bundle, causing difficulties in achieving SRI and requiring additional ablation within the ring. Ablation along the inferior line is recommended as the final step. With robust anterior wall and top line ablation, the PW may only require minimal ablation, such as inferior line sparing, to achieve overall isolation of the pulmonary veins and PW, which can significantly reduce oesophageal injury [21]. In our study, the opportunity to practice this technique more (> 20 patients) may have improved the efficiency of SRI and reduced the procedural time, which is evident from the fact that the procedure time for the last 25 patients in the SRI group was significantly shorter than that in the BOXI group (186.04 ± 38.69 min vs. 224.60 ± 49.79 min, P = 0.004). Hence, the SRI may be superior in terms of total procedure time for the majority of elderly patients, especially for elderly patients with poor surgical tolerance.

Patients who undergo AF ablation often experience pain, especially during PW ablation. Even with the use of morphine and fentanyl for analgesia, some elderly patients still experience intolerable pain, which not only greatly reduces the comfort and satisfaction of patients with the operation but also interrupts the procedure due to the mismatch of the 3D model caused by movement, resulting in insufficient local ablation and increased procedural time, thereby increasing the risk of recurrence. General anaesthesia-based AF catheter ablation is an ideal method, but it is difficult to implement in many centres due to the lack of anaesthesiologists. Therefore, the SRI with minimal PW ablation is the best option. We evaluated the patients' experience during the procedure using retrospective VAS questionnaires. The results showed that elderly patients in the SRI group had lower VAS than those in the BOXI group (3.40 ± 1.05 vs. 5.53 ± 1.27, P < 0.001), suggesting greater procedural comfort and satisfaction, which may enhance the overall ablation experience.

During AF catheter ablation, cTnI may increase, reflecting the extent and scope of myocardial injury caused by ablation. Our study showed that troponin I levels were significantly lower in the SRI group than those in the BOXI group at 24 h postablation (2.54 ± 0.99 ng/ml vs. 2.06 ± 0.98 ng/ml, P = 0.023), which indicates that SRI is associated with less myocardial injury of PW and potential oesophageal injury than the BOXI.

The high-power short-duration (HPSD) ablation strategy comprises the use of higher RFCA power (≥ 40 W) and a shorter duration (5–15 s) of each RF energy application, and HPSD ablation results in larger lesion diameters and smaller lesion depths than conventional (20–35 W, 10–30 s) applications [22]. High-power ablation was previously associated with better procedural effectiveness than conventional RFCA with low power [23]. Currently, there are relatively few reports on the use of HPSD ablation for SRI in elderly patients. Our study revealed that SRI combined with HPSD demonstrated greater effectiveness in restoring sinus rhythm than did BOXI alone. Moreover, the proportion of DC shocks to terminate atrial arrhythmia in patients who underwent SRI was significantly lower than that in patients who underwent BOXI (P = 0.043). Obviously, the SRI procedure with HPSD was more effective and comfortable for elderly patients. The mechanism for the higher percentage of immediate sinus rhythm in patients with SRI is unclear. A possible explanation is that with the intervention of left atrial substrates in the same range, less PW injury and pain stimulation during HPSD ablation may reduce the secretion of adrenergic hormones and stimulation of peripheral ganglia of the heart, lower neural excitability, prolong the effective refractory period of atrial muscle, and improve electrical remodelling of atrial muscle so that AF cannot be maintained.

Prior studies have suggested that fever (73%), neurological (72%), gastrointestinal (41%), and cardiac (40%) symptoms are the most common adverse events that occur between 0 and 60 days postablation (median 21 days). Moreover, atrioesophageal fistula complicating AF ablation is associated with high mortality [24]. In our study, radiofrequency energy was applied at each point with a power of 40–45 W around the PV and near the oesophagus. No major procedure-related complications, including death, cardiac perforation, or atrioesophageal fistula, occurred in any of the study patients. In addition, compared with those in the BOXI group, procedure-related gastrointestinal symptoms were reduced in the SRI group after ablation (15.56% vs. 37.78%, P = 0.017), which may be attributed to fewer PW interventions and oesophageal injury, highlighting the superiority of SRI. Overall, the above results suggest that it is safe to isolate the pulmonary veins and posterior left atrium with the SRI technique using high power in elderly patients.

Long-term results after pulmonary vein isolation have demonstrated high rates of recurrent arrhythmia after ablation procedures. The arrhythmia-free survival rates after catheter ablation procedures were 40%, 37%, and 29% after 1, 2, and 5 years, respectively [25]. A meta-analysis revealed that wider isolation techniques had lower recurrence rates than did ostial isolation in both paroxysmal and persistent AF patients [26]. In addition, Lim et al. [27] reported the superiority of SRI over wide antral pulmonary vein isolation regarding AF recurrence in patients with symptomatic AF (61% paroxysmal, 39% persistent/longstanding persistent). They showed that AF-free survival at 2 years was better after single-ring isolation (74% [95% CI, 65%–82%]) than wide antral isolation (61% [51%–70%]; P = 0.031). Our research was based on the comparison of the long-term outcomes of two ablation approaches with the same electrical isolation range. K‒M analysis revealed that the SRI did not improve AF-free survival or AT-free survival at 12 months (atrial arrhythmia-free survival: 75.6% [73.2%-86.7%] for SRI vs. 73.3% [71.1%-91.1%] for BOXI, P > 0.05). One explanation for this difference is that the proportion of PeAF significantly differed between our study and the study by Lim et al. (100% vs. 39%, P < 0.01). Wide antral pulmonary vein isolation may not be sufficient for PeAF, and other ablation strategies are needed, such as posterior box isolation and substrate and trigger ablation [28]. The posterior wall of the LA is isolated in the SRI, which reduces the critical substrate for the maintenance of PeAF and may improve the outcome [4]. However, in our study, the scope of LA isolation was the same between SRI and BOXI, indicating that the areas of ablation targeted to eliminate triggers and substrates for AF maintenance were also the same. This may be the reason for the lack of a significant difference in long-term efficacy between our two isolation methods. Furthermore, the patients in our study were followed for a relatively short period.

There are several limitations to this study that need to be considered. First, owing to the small sample size and retrospective nature of the study, our results could be biased even if PSM was performed to adjust for between-group differences in the baseline data. Second, gastrointestinal symptoms were not sufficient to evaluate the difference in oesophageal injury between the SRI and BOXI groups. Oesophageal temperature monitoring may demonstrate the advantages of SRI over BOXI. Third, the 12-month follow-up period was relatively short, and there were no long-term outcomes. Fourth, in our study, the VAS score assessed pain throughout the entire ablation process, not just during posterior wall ablation. It is well known that the patients' pain during the ablation mainly occurred during the intervention for posterior wall, especially in the lower posterior wall region of the left and right pulmonary veins. Certainly, we cannot overlook that a small subset of patients may experience maximum pain at times other than during posterior wall ablation. Capturing the patient's pain score during the posterior wall ablation procedure would yield more accurate data and enhance its persuasive value. Finally, because AF recurrence was assessed on the basis of symptoms and 24-h Holter, the occurrence of atrial arrhythmia may have been missed. Daily self-pulse checks, 7-day Holter monitoring and wearable monitoring devices should be used to evaluate AF recurrence in future studies.

In conclusion, this study demonstrates, for the first time, that an SRI ablation strategy with high power could be more efficient and safer for most elderly patients with PeAF than a BOXI ablation strategy. Our data provide a practical method of RFCA in elderly patients with PeAF, but future long-term investigations with larger sample sizes are necessary to confirm our findings.

Data availability

All the data used to support the findings of this study are available from the corresponding author upon reasonable request.

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Acknowledgements

We are grateful to our colleagues at the Department of Cardiology, Wujin Hospital Affiliated with Jiangsu University, for their clinical support and expertise.

Clinical competency in medical technology

The results from this analysis identified opportunities to modify posterior isolation strategy for elderly patients with PeAF to further decrease the risk of oesophageal injury and improve ablation experience of patients.

Translational outlook

Ablation techniques with less damage and a more comfortable experience for patients, while ensuring efficacy, are the pursuit of every electrophysiologist. This analysis identified the efficacy and safety of SRI with high-power on PeAF in elderly patients, and SRI with high-power in posterior isolation might be an preferred treatment option to RFCA for PeAF, especially in elderly patients. Further larger, randomized trials are needed to evaluate the role of SRI in elderly patients with PeAF other than in this setting.

Funding

The study was supported by the Changzhou Sci&Tech Program (CJ20230005), Changzhou's "14th Five-Year Plan" High-level Healthcare Talent Cultivation Project (No. 2024CZBJ028) and the Medical Education Collaborative Innovation Fund of Jiangsu University (No. JDYY2023076). All other authors have reported that they have no relationships relevant to the contents of this paper to disclose.

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Authors and Affiliations

  1. Wujin Hospital Affiliated With Jiangsu University, No. 2, Yongning North Road, Changzhou, Jiangsu, 213017, China

    Yanbin Song, Xiaofang Liang, Sheliang Xue, Bo Xu, Jianqiang Xiao & Wenhua Li

  2. The Wujin Clinical College of Xuzhou Medical University, Changzhou, China

    Yanbin Song, Xiaofang Liang, Sheliang Xue, Bo Xu, Jianqiang Xiao & Wenhua Li

Authors
  1. Yanbin Song
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  2. Xiaofang Liang
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  3. Sheliang Xue
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  4. Bo Xu
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  5. Jianqiang Xiao
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  6. Wenhua Li
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Contributions

Yanbin Song and Wenhua Li designed and conducted study. Yanbin Song and Wenhua Li were responsible for the initial writing of the manuscript. Yanbin Song, Wenhua Li, Xiaofang, Liang, Bo Xu, Jianqiang Xiao and Sheliang Xue collected the data. All of the authors were responsible for the final version of the manuscript.

Corresponding author

Correspondence to Wenhua Li.

Ethics declarations

Ethics approval and consent to participate

The study was approved by the Ethics Committee of Wujin Hospital Affiliated with Jiangsu University, Changzhou, China (2023-SR-055). Written informed consent was not obtained from the included patients because the relevant data were retrospectively obtained from the electronic medical records. The Ethics Committee of Wujin Hospital Affiliated with Jiangsu University waived the need to obtain informed consent. The study conforms to the principles outlined in the Declaration of Helsinki. The data used in this study were anonymized before use.

Competing interests

The authors declare no competing interests.

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Song, Y., Liang, X., Xue, S. et al. Comparison of high-power single-ring isolation and box isolation in elderly patients with persistent atrial fibrillation. BMC Geriatr 25, 344 (2025). https://doiorg.publicaciones.saludcastillayleon.es/10.1186/s12877-025-05981-y

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Keywords

BMC Geriatrics

ISSN: 1471-2318

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