Vol 81, No 5 (2023)
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Original article

Subcutaneous implantable cardioverter-defibrillator therapy in Poland: Results of the Polish S-ICD Registry

Maciej Kempa1Szymon Budrejko1Mateusz Tajstra2Paweł Syska3Michał Lewandowski3Tomasz Fabiszak4Marcin Michalak5Adrian Stanek6Krzysztof Nowak7Przemysław Mitkowski8Krzysztof Kaczmarek9Zbigniew Orski10Marcin Janowski11Piotr Szafarz12Artur Filipecki13Adam Sokal1415Marek Szołkiewicz16Dariusz Jagielski17Andrzej Przybylski1218
1Department of Cardiology and Electrotherapy, Medical University of Gdansk, Gdańsk, Poland
23rd Department of Cardiology, School of Medical Sciences in Zabrze, Medical University of Silesia, Katowice, Poland
32nd Department of Heart Arrhythmia, National Institute of Cardiology, Warszawa, Poland
4Department of Cardiology and Internal Medicine, Collegium Medicum, Nicolaus Copernicus University, Bydgoszcz, Poland
51st Department of Cardiology, Medical University of Warsaw, Warszawa, Poland
6Department of Electrocardiology, John Paul II Hospital, Kraków, Poland
7Institute of Heart Diseases, Wroclaw Medical University, Wrocław, Poland
81st Department of Cardiology, University of Medical Sciences, Poznań, Poland
9Department of Electrocardiology, Medical University of Lodz, Łódź, Poland
10Department of Cardiology and Internal Diseases, Military Institute of Medicine — National Research Institute, Warszawa, Poland
11Chair and Department of Cardiology Medical University of Lublin, Lublin, Poland
121st Department of Cardiology with the Acute Coronary Syndromes Subdivision, Clinical Provincial Hospital No. 2, Rzeszów, Poland
131st Chair and Department of Cardiology, Medical Sciences in Katowice, Medical University of Silesia, Katowice, Poland
141st Department of Cardiology and Angiology, Silesian Center for Heart Diseases, Zabrze, Poland
15Medical University of Silesia, Faculty of Health Sciences, Department of Dietetics, Bytom, Poland
16Department of Cardiology and Interventional Angiology, Kashubian Center for Heart and Vascular Diseases, Pomeranian Hospitals, Wejherowo, Poland
17Department of Cardiology, Center for Heart Diseases, 4th Military Hospital, Wrocław, Poland
18Medical College of Rzeszow University, Rzeszów, Poland

Editorial

by Botto et al.

Correspondence to:

Szymon Budrejko, MD, PhD,

Department of Cardiology and Electrotherapy,

Medical University of Gdansk,

Smoluchowskiego 17, 80–214 Gdańsk, Poland,

phone: +48 58 584 47 60,

e-mail: budrejko@gumed.edu.pl

Copyright by the Author(s), 2023

DOI: 10.33963/KP.a2023.0046

Received: January 12, 2023

Accepted: February 12, 2023

Early publication date: February 19, 2023

ABSTRACT
Background: The use of subcutaneous implantable cardioverter-defibrillators (S-ICD) has been growing in Poland since 2014. The Polish Registry of S-ICD Implantations was run by the Heart Rhythm Section of the Polish Cardiac Society between May 2020 and September 2022 to monitor the implementation of that therapy in Poland.
Aims: To investigate and present the state-of-the-art of S-ICD implantation in Poland.
Methods: Implanting centers reported clinical data of patients undergoing S-ICD implantations and replacements, including age, sex, height, weight, underlying disease, history of pacemaker and defibrillator implantations, indications for S-ICD, electrocardiographical parameters, procedural techniques, and complications.
Results: Four hundred and forty patients undergoing S-ICD implantation (411) or replacement (29) were reported by 16 centers. Most patients were in New York Heart Association class II (218 patients, 53%) or I (150 patients, 36.5%). Left ventricular ejection fraction was 10%–80%, median (IQR) was 33% (25%–55%). Primary prevention indications were present in 273 patients (66.4%). Non-ischemic cardiomyopathy was reported in 194 patients (47.2%). The main reason for the choice of S-ICD were: young age (309, 75.2%), risk of infectious complications (46, 11.2%), prior infective endocarditis (36, 8.8%), hemodialysis (23, 5.6%), and immunosuppressive therapy (7, 1.7%). Electrocardiographic screening was performed in 90% of patients. The rate of adverse events was low (1.7%). No surgical complications were observed.
Conclusions: Qualification for S-ICD in Poland was slightly different when compared to the rest of Europe. The implantation technique was mostly consistent with the current guidelines. S-ICD implantation was safe, and the complication rate was low.
Key words: implantable cardioverter-defibrillator, subcutaneous implantable cardioverter-defibrillator, sudden cardiac death, ventricular arrhythmia

What’s new?

The use of subcutaneous implantable cardioverter-defibrillator (S-ICD) systems in Poland has been growing since 2014, with a significant rise after introduction of full reimbursement. The Polish Registry of S-ICD Implantations was run by the Heart Rhythm Section of the Polish Cardiac Society between May 2020 and September 2022 to monitor the implementation of that modern therapy in Poland. We present data regarding 440 procedures reported to the registry, including 411 de novo S-ICD implantations that represent 75% of the total number of implantations in Poland during that period. There were no perioperative surgical complications, and the rate of adverse events was low.

Introduction

Implantation of a subcutaneous cardioverter-defibrillator (S-ICD) is commonly used for prevention of sudden cardiac death due to ventricular arrhythmias, which is in line with the European and American guidelines [1, 2]. That method of treatment has been employed in Poland since 2014 [3]. During the early period, the number of implantations was limited by the lack of reimbursement, decisions were made on a post-hoc, patient-by-patient basis by the National Healthcare Fund, which discouraged wide application of the new method due to the high cost of the system resulting in the procedure being a high-risk investment for any hospital involved. Complete reimbursement by the National Healthcare Fund was introduced as late as 2019 (under specific conditions: only for experienced, high-volume tertiary cardiology centers, performing at least 30 lead extraction procedures annually, and having cardiac or thoracic surgery backup on-site) [4]. That led to a substantial increase in the number of procedures in the following months. Despite that fact, no national system was established to monitor the growing experience of Polish centers with the new modality of treatment. Therefore, the executive board of the Heart Rhythm Section of the Polish Cardiac Society decided to create the Polish S-ICD Registry to monitor the safety, technical issues, complications, and clinical outcomes of the implementation of that method in Poland. The registry was launched on May 1, 2020 [5]. Centers implanting S-ICD systems reported data of patients undergoing implantation or exchange of the device. Participation of the centers in the registry was not intended to influence their clinical decisions, and data were sent after implantation-related hospitalization. The initial report comprised the data of 123 patients. Low complication rates were observed, as there were no in-hospital surgical complications, and only 2 adverse events were described (pocket hematoma treated conservatively, and unilateral paresis of the lower limb with no apparent pathology of the central nervous system). The most frequent indication for S-ICD and not a transvenous implantable cardioverter-defibrillator (TV-ICD) was patients’ young age, similar to other reports.

During the first year of data collection, the initial results were also published, comparing Poland to other European countries in terms of characteristics of the population of patients undergoing S-ICD implantation, as well as the reasons for choosing subcutaneous systems over transvenous ones [6]. In that report, we concluded that S-ICD systems in Poland were implanted in patients at a more advanced stage of chronic heart failure when compared to other European countries. The most frequent reason for choosing S-ICD and not TV-ICD was the young age of patients, similar to other countries.

The registry data were also compared with the historical small cohort of S-ICD recipients treated during the initial year after the introduction of this new method of treatment in Poland [7]. In that report, we observed a tendency to incorporate new operational techniques (such as intermuscular pocket and 2-incision technique) used in more experienced European centers, with no increase in the perioperative complication rate.

After significant volume of data was gathered by the participating centers, a decision was made to close the registry at the end of September 2022. Our current analysis aimed to investigate and present the state-of-the-art of S-ICD implantation in Poland based on the data reported to the registry during the whole period of two and a half years of its duration.

Methods

The analysis was based on patients’ records reported between May 2020 and September 2022 to the multicenter registry of S-ICD implantations in Poland. The registry was designed, launched, and run by the Heart Rhythm Section of the Polish Cardiac Society, and it was approved by the Bioethical Committee at the Regional Medical Board in Rzeszów (approval no. 35/B/2020). Centers’ participation in the registry was by no means associated with any influence on qualification of patients, procedural technique, or further course of follow-up care. Required data were reported once the index hospitalization of a given patient had finished. The records included information such as age, sex, height, weight and body mass index, underlying disease, history of implantation of other implantable cardiac electronic devices (pacemakers and defibrillators) and their extraction, indications for S-ICD implantation, basic electrocardiographical parameters (including any conduction disturbances and QRS widening), procedural techniques (type of anesthesia, use of 2-incision or 3- incision techniques), results of the implantation procedure, and any complications occurring until the end of patient’ hospitalization. Data were reported digitally on a dedicated web-based platform created for that purpose.

Statistical analysis

Continuous variables were presented as mean and standard deviation or median and interquartile range in the case of non-normal distribution. Categorical parameters were presented as numbers and percentages. The normality of distribution was tested with the Shapiro-Wilk test. Groups were compared with the Pearson’s χ2 test and post-hoc proportion test with Bonferroni’s correction for multiple comparisons. Fisher’s exact test was used in the case of low sample sizes. A P-value of below 0.05 was considered statistically significant. Data management and statistical analysis were performed with Microsoft Excel, Statistica 13.1 software (TIBCO Software, Palo Alto, CA, US), and R version 4.1.2 (November 1, 2021, “Bird Hippie”, The R Foundation for Statistical Computing, Vienna, Austria) and R-studio software (September 2, 2021 build 382).

Results

Data of 440 patients undergoing S-ICD implantation (411 patients) or device replacement (29 patients) were reported to the registry by 16 centers in Poland. That number represented 75% of all procedures performed in Poland during the period of interest, as we estimated on the basis of unpublished data acquired from the manufacturer of the system. The growth rate of the cumulative number of records was constant during the whole duration of the registry. A quarterly number of new records was between 43 and 49, except for the first (19) and last (25 records) quarters. Among 411 patients undergoing first-time implantation, 297 (72.3%) were male and 114 (27.7%) were female. Patients’ age was between 12 and 82 years, with a median (interquartile range [IQR]) value equal to 42 (3155) years.

Most patients were classified as New York Heart Association (NYHA) class II (218, 53%) or I (150, 36.5%), with all the others being in class III. Left ventricular ejection fraction (LVEF) was between 10 and 80% and median (IQR) was 33% (25%–55%). In 273 patients (66.4%), S-ICD was implanted for primary prevention of sudden cardiac death (SCD). Non-ischemic cardiomyopathy was the predominant underlying disease in that cohort, as it was reported in 194 patients (47.2%). Detailed clinical data are presented in Table 1.

Table 1. Clinical characteristics of patients undergoing first-time implantation of a subcutaneous implantable cardioverter-defibrillator

Clinical feature

Value

Age, years, median (IQR)

42 (31–55)

Male sex, n (%)

297 (72.3)

Height, cm, median (IQR)

175 (168–181)

Weight, kg, median (IQR)

80 (70–94)

BMI, kg/m2, median (IQR)

26 (23–30)

Sinus rhythm, n (%)

386 (93.9)

Prior sternotomy, n (%)

40 (9.7)

LVEF, %, median (IQR)

33 (25–55)

Underlying disease

NICM, n (%)

194 (47.2)

ICM, n (%)

112 (27.3)

Primary VF, n (%)

46 (11.2)

LQTS, n (%)

11 (2.7)

HCM, n (%)

7 (1.7)

LVNC, n (%)

7 (1.7)

Brugada syndrome, n (%)

6 (1.5)

Myocarditis, n (%)

5 (1.2)

Congenital heart disease, n (%)

5 (1.2)

ARVC, n (%)

2 (0.5)

CPVT, n (%)

2 (0.5)

MAD, n (%)

1 (0.2)

Electrocardiography and other cardiac implantable electronic devices (CIED)

Data representing cardiac rhythm, conduction disturbances, and the presence of other CIEDs at the time of S-ICD implantation are presented in Table 2.

Table 2. Electrocardiography and other cardiac implantable electronic devices

Sinus rhythm, n (%)

386 (93.9)

Atrial fibrillation, n (%)

25 (6.1)

Paced rhythm, n (%)

4 (1)

Bundle branch block, n (%)

20 (4.9)

Right bundle branch block, n (%)

14 (3.4)

Left bundle branch block, n (%)

6 (1.5)

No history of CIED before S-ICD, n (%)

338 (82.2)

Previous ICD-VR, n (%)

53 (12.9)

Previous ICD-DR, n (%)

18 (4.4)

Previous CRT-D, n (%)

5 (1.2)

Previous CRT-P, n (%)

1 (0.2)

Previous TV-ICD not removed, only deactivated, n (%)

10 (2.4)

Reasons for preference of S-ICD over TV-ICD

The main reason for the choice of S-ICD (instead of a traditional TV-ICD) was patients’ young age and long life expectancy, and it was reported as such in 309 patients (75.2%). The other significant group of reasons declared by the implanting physicians fell into the category of increased risk of infectious complications or recurrent infection due to (sorted by decreasing frequency): chronic infectious states in 46 patients (11.2%), prior infective endocarditis in 36 patients (8.8%), hemodialysis in 23 patients (5.6%), and immunosuppressive therapy in 7 patients (1.7%). Lead failure of a previously implanted transvenous lead was reported as the main reason in 27 cases (6.6%) and difficult vascular access in 18 cases (4.4%). In the majority of patients (370 — 90%), the decision to qualify for S-ICD implantation was preceded by electrocardiographic (ECG) screening, as presented in Table 3.

Table 3. Results of preoperative electrocardiography screening, which was performed in 370 of 411 patients undergoing first-time implantation

Number of vectors positive for a given patient

Number of patients (%)

3

190 (51.4)

2

171 (46.2)

1

9 (2.4)

Number and percentage of positive results for a given vector in the whole cohort

Number of patients (%)

Primary

346 (93.5)

Secondary

334 (90.3)

Alternate

241 (65.1)

S-ICD implantation procedure

S-ICD systems were implanted mostly by cardiologists. A cardiac surgeon was involved only in 8 cases (1.9%). The procedure was performed most frequently under general anesthesia (302 patients, 73.5%), using a 2-incision technique (323 patients, 78.6%), and creating an intermuscular (over the serratus anterior muscular fascia and beneath the latissimus dorsi muscle) device pocket (367 patients, 89.3%). A defibrillation test was performed in 322 patients out of 411 undergoing first-time implantation (78.3%). The test shock was set to 65J in 309 cases, 70J in 10, 72J in 2, and 80J in one case. In 89 patients the defibrillation test was waived, and the predominant reasons for avoiding the test were: extremely low LVEF (17 patients, 19.1%), thromboembolic material within heart chambers (14 patients, 15.8%), and transvenous lead extraction (possibly increasing the risk of complications) performed just before S-ICD implantation (10 patients, 11.2%).

During data collection, we observed an evolution of operational techniques, that is the number of incisions, location of the device pocket, and the type of anesthesia used for the implantation procedure. To trace that evolution, we divided the whole duration of the registry into 4 equal 7-month periods (1st period: May 2020December 2020, 2nd period: January 2021July 2021, 3rd period: August 2021February 2022, 4th period: March 2022September 2022). During the first period, the 3-incision technique was used in 53.2% of cases, with predominant intermuscular pocket (96.4%) and the procedure was performed under general anesthesia (72.1%). In the last period, more procedures were reported to have been performed with the 2-incision technique (93.3%; P <0.001) with a lower rate of intermuscular pocket (80.9%; P = 0.01). The rates of procedures performed under general anesthesia or fascial plane block were not significantly different (P = 0.83). Detailed data are presented in Figures 13.

Figure 1. Evolution of the implantation technique percentages of 2- and 3-incision procedures in 4 consecutive 7-month periods of the registry (1st period: May 2020December 2020, 2nd period: January 2021July 2021, 3rd period: August 2021February 2022, 4th period: March 2022September 2022). P <0.001 for inter-group difference; P <0.001 for 1st vs. 4th period comparison
Figure 2. Evolution of the implantation technique location of the device pocket in 4 consecutive 7-month periods of the registry (1st period: May 2020December 2020, 2nd period: January 2021July 2021, 3rd period: August 2021February 2022, 4th period: March 2022September 2022). The submuscular pocket is located under the serratus anterior muscle; the intermuscular pocket is located between the latissimus dorsi and serratus anterior muscles. P <0.01 for inter-group difference; P = 0.01 for 1st vs. 4th period comparison
Figure 3. Evolution of the implantation technique type of anesthesia in 4 consecutive 7-month periods of the registry (1st period: May 2020December 2020, 2nd period: January 2021July 2021, 3rd period: August 2021February 2022, 4th period: March 2022September 2022). P = 0.04 for inter-group difference; P = 0.83 for 1st vs. 4th period comparison
Periprocedural adverse events and complications related to S-ICD implantation or replacement

S-ICD replacement procedures (29 patients) were not associated with any adverse events. In 411 patients undergoing first-time implantation, 7 adverse events were observed (1.7%) during the periprocedural period (in-hospital, before discharge from the implantation-related hospitalization). Inappropriate interventions were reported in 4 cases (1%), and they were due to inappropriate sensing resulting most probably from air entrapment in the device pocket or the tunnel around the lead course (4 patients, 1%), as well as low amplitude of the R wave (in addition) in 1 of those patients (0.2%). Subcutaneous emphysema was reported in one patient (0.2%). Moreover, one patient (0.2%) suffered from transient atrioventricular conduction disturbances immediately after the defibrillation test shock. In one patient (0.2%), paresis of the right lower extremity was observed, and an in-depth diagnostic investigation did not reveal any neurological reason that could explain that complication. No surgical complications, infections, or early system revisions were reported.

Discussion

Data collected in that multicenter registry were used for previously published analyses comparing indications and clinical characteristics of populations of patients undergoing S-ICD implantation in Poland and other European countries [8]. When considering the complete registry duration of 2.5 years, the percentages and trends did not change significantly. Among patients receiving S-ICD systems, the percentage of subjects in NYHA class I is approximately 40%, and in class III around 11%. Those percentages are different than in the rest of Europe, where more patients are in class I (67.7%) and fewer in class III (2.9%), as we reported before [8]. In our extended registry cohort, mean LVEF was still below 40%; hence, the tendency of Polish patients to have more advanced heart failure at the time of S-ICD implantation remained unchanged. That result is concordant with the findings of the Heart Failure Pilot Survey [9]. S-ICD was invariably less frequently implanted in patients with no structural heart disease in Poland than in the rest of Europe. That finding is surprising because, in a recently published survey, the majority of Polish experts in S-ICD implantation declared that patients with inherited arrhythmic syndromes should be qualified for S-ICD rather than TV-ICD unless a history of ventricular tachycardia eligible for antitachycardia pacing was present [10].

Interesting results were found in the analysis of reasons for selection of an S-ICD instead of a TV-ICD. Polish centers reported patients’ young age as the predominant reason. The second most important factor was the fear of infectious complications. Those results are in conformity with both the European and American guidelines, where the long-life expectancy and the risk of infection or infection recurrence are recommended for consideration during qualification and should favor S-ICD systems [1, 2]. The above observations are also in line with the results of a survey study, where 92% of Polish experts declared a history of transvenous CIED-related infection resulting in the extraction of that system as the reason for the subsequent choice of S-ICD, and the age below 50 years should favor the choice of S-ICD and not TV-ICD irrespective of the etiology of heart failure [10]. Importantly, according to legal regulations in Poland, complete reimbursement of the S-ICD system is granted only on declaration of the indication predefined by the healthcare fund [4]. Therefore, the reasons such as an active lifestyle, cosmetic effect, or patients’ preference cannot justify the choice of S-ICD, and then an additional reason should be reported for reimbursement, even if it is not predominant.

In the majority of patients, a decision to implant S-ICD was preceded by ECG screening. Three acceptable vectors were recorded in 51.4% of patients, and only one in 2.4% of cases. According to the S-ICD manual, at least one vector passing in all the tested body positions is considered sufficient to proceed with S-ICD implantation. Most of the authors of this study consider that insufficient and prefer to have at least two vectors positive in both supine and standing body positions. Unfortunately, we do not have information on how many of the patients initially considered for S-ICD implantation failed ECG screening, as only S-ICD implantations were reported to the registry, and not preoperative qualification.

Surgical techniques used during S-ICD implantation were in line with the current European Heart Rhythm Association (EHRA) recommendations [11]. Implantation procedures were performed mostly under general anesthesia, using the 2-incision technique and an intermuscular device pocket. The recommended 2-incision technique was used with an increasing rate from the first period of the registry to the last one. There was no significant difference in the rates of regional anesthesia and fascial plane block between the consecutive periods. We also made a surprising observation that the rate of using subcutaneous (and not intermuscular) pocket location increased during the time of data collection. Such a technique is not recommended, as it increases the risk of infectious complications. The most probable explanation for this phenomenon is that new centers with less experienced operators joined the registry during ongoing data collection. A conclusion may be drawn that some form of training requirements for operators, and not only legal requirements for centers, should be considered to promote appropriate operational techniques.

A defibrillation test was performed in 322 of 411 patients undergoing first-time S-ICD implantation. It means that the test is abandoned increasingly more often despite being a recommended step in the implantation procedure [11]. The main reason for skipping the test was very low LVEF (and thus the fear of worsening heart failure with induced ventricular fibrillation). Another reason was transvenous lead extraction directly preceding S-ICD implantation. Mechanical strain applied to the vessel walls and heart chambers during lead extraction may impair their integrity and increase the risk of subsequent rupture and perforation due to increased pressure trauma, which may be related to abrupt chest muscle contraction during the induction and defibrillation of ventricular fibrillation. Although that fear is based on the experience of physicians performing lead extractions and has no sound data to support it, it is not limited to us. In a recent report of S-ICD implantation up to several days after transvenous lead extraction, defibrillation testing was performed only in 47% of S-ICD recipients, and “physician’s choice” was also among the reasons behind skipping the test [12].

In 309 patients, a test shock of 65J was effective. The remaining 13 patients were tested with higher energy. Induced arrhythmias were successfully terminated in all cases. That result seems to be slightly better than the percentages reported in clinical studies [13, 14]. It may be related to a high rate of using intermuscular pocket location (which is nowadays the preferred device location). In the majority of patients reported to the registry, the device pocket was dissected under the border of the latissimus dorsi muscle, as recommended. It forces a more dorsal position of the device compared to the subcutaneous pocket and results in high efficacy of the test shock due to a relatively low impedance of the defibrillation pathway [15, 16]. Unfortunately, not all operators declared such a location (i.e. intermuscular and not subcutaneous) as their default choice for the device pocket.

In 10 cases, previously implanted ICDs were not removed before S-ICD implantation. The reasons for that decision were not specifically reported in the registry. In general, in such cases, TV-ICDs may be either planned for removal after S-ICD implantation or they may be switched off and abandoned. The latter approach is possible only in the case of non-infectious complications (such as lead failure), but in our opinion, it should be avoided if only possible. That approach is still under investigation [17] and conclusive evidence is lacking.

In the group of 411 de novo S-ICD implantations, 7 adverse events were reported. Most of them were inappropriate interventions of the system. The occurrence of those interventions resulted predominantly from a recognized phenomenon of air entrapment in the device pocket and along the lead course after the implantation procedure [18]. The problem typically resolves by itself, with air being resorbed within several days. To avoid such events, every operator should carefully evacuate air during implantation, and some authors recommend filling the lead tunnel and the device pocket with sterile saline [19]. Delayed activation of the system, up to 48 hours after implantation, may also be considered. Nonetheless, such an event does not require surgical intervention. According to the results of the UNTOUCHED study, the common use of the 2-incision technique may contribute to a higher rate of air entrapment within the subcutaneous lead tunnel [20]. In 3 of those 4 patients in our group, the 2-incision technique was used for implantation. Such a complication may also occur after device replacement when the new can is smaller than the old one, but no such case was reported in our patient population.

Subcutaneous emphysema and transient atrioventricular conduction disturbances were also incidentally observed in our study, but they did not require any additional intervention. The most serious reported complication was a neurological event in one patient, whose mechanism remained unclear despite thorough evaluation. Therefore, a complication requiring additional diagnostic and therapeutic measures could be attributed only to that single case. That rate is very low, and lower than reported in the available studies. Surgical complications such as dislocation of system components and inappropriate healing of a postoperative wound have been described in up to 3% of patients during the first month after implantation [21]. In our group, none of the patients had surgical complications after de novo implantation, but the initial observation period was relatively short, as it continued only until patients’ discharge from the hospital.

Limitations

The main limitation of our analysis is a relatively low number of patients despite multicenter involvement. The registry covered only 75% of patients undergoing S-ICD implantation or replacement during that specific time in Poland. Participation was voluntary, not all implanting centers joined the registry, new centers were launched after the registry was started, and they did not decide to join. Underreporting from the participating centers cannot be excluded. The registry was launched by the Heart Rhythm Section, it included specific clinical centers, and local coordinators were responsible for data collection and transfer, but we did not verify or confirm the reported data in any way, and therefore possibly limited data reliability may also be an issue. The COVID-19 pandemic might have also influenced the clinical routine, as the availability of S-ICD implantation, device choice, and other clinical decisions might have been altered during the pandemic [22]. ECG screening was not performed in 10% of patients.

Conclusion

The analysis of data collected in the registry showes that a certain dissimilarity exists in qualification for S-ICD implantation between Poland and other European countries. The course of the procedure and implantation technique are in most cases consistent with the current guidelines. Good outcomes and an almost complete lack of serious complications during the early postoperative period demonstrate that implanting centers were appointed appropriately, and the implanting teams were well-trained.

Article information

Conflict of interest: MK received speaker/proctoring fees from Boston Scientific. PS received speaker/proctoring fees from Boston Scientific. ML received lecture honoraria and a proctorship agreement from Boston Scientific. PM received a speaker fee from Boston Scientific Poland. KK received proctor and consulting fees from Boston Scientific Poland. AS consultancy agreement Boston Scientific; AP received advisory board fee from Boston Scientific. Other authors declare no conflict of interest.

Funding: The registry was partially supported by a research grant from Boston Scientific for the Polish Cardiac Society.

Open access: This article is available in open access under Creative Common Attribution-Non-Commercial-No Derivatives 4.0 International (CC BY-NC-ND 4.0) license, which allows downloading and sharing articles with others as long as they credit the authors and the publisher, but without permission to change them in any way or use them commercially. For commercial use, please contact the journal office at kardiologiapolska@ptkardio.pl.

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Polish Heart Journal (Kardiologia Polska)