Search Results (83)

Management of ventricular tachycardia (VT) requires an integrated approach combining invasive therapy and cardiac imaging. This article reviews the principal imaging modalities and their integration with electroanatomical mapping systems to plan and guide procedures and to assess the success of VT ablation during follow-up. The central role of imaging in optimizing the efficacy and safety of VT ablation is emphasized. Studies demonstrating that imaging-supported workflows can improve substrate localization, reduce procedural times and radiation exposure, and lower recurrence rates are highlighted. Current limitations and future challenges are also discussed. Full article

Atrioventricular (AV) node ablation represents an established therapeutic option in the management of atrial fibrillation (AF) and other atrial tachyarrhythmias, particularly in patients with symptomatic tachycardia who remain unresponsive or intolerant to pharmacological therapy. The procedure is often considered in cases of refractory arrhythmias, antiarrhythmic drugs intolerance, or tachycardiomyopathy, and plays a key role in optimizing outcomes in patients undergoing cardiac resynchronization therapy, where achieving adequate biventricular pacing is otherwise compromised by rapid ventricular responses. Traditionally, AV node ablation is performed using radiofrequency energy delivered at the region of the His bundle, guided by the earliest His potential recordings. However, the anatomical complexity of the AV node and Koch’s triangle poses important challenges, including the risk of incomplete ablation, persistence of conduction, lack of reliable junctional escape rhythms, and increased risk of proarrhythmia. Recent advances in high-resolution mapping and electroanatomical guidance have enabled a more precise anatomical approach, selectively targeting the compact AV node while reducing collateral injury. These developments offer the potential for improved procedural safety, long-term efficacy, and a more standardized strategy for patient management. This review summarizes current evidence, techniques, and clinical implications of AV node ablation, highlighting its role in the evolving landscape of arrhythmia treatment. Full article

Background: Artificial Intelligence (AI) is a transformative innovation designed to enable machines to perform tasks typically requiring human intelligence. Among various medical fields, cardiology—and particularly electrophysiology—has seen rapid integration of AI technologies. The ability of AI to analyze large and complex datasets is reshaping diagnostic and therapeutic approaches. Objectives: This review aims to provide a comprehensive overview of AI models and their applications in cardiac electrophysiology. The focus is on understanding how AI contributes to clinical practice through ECG interpretation, arrhythmia detection, atrial mapping, and catheter ablation, while also exploring its limitations and future potential. Methods: The review discusses various AI approaches, including Machine Learning (ML) and Deep Learning (DL), and highlights relevant literature illustrating their implementation in electrophysiological settings. Key clinical applications are examined thematically, with a narrative synthesis of current capabilities, technologies, and outcomes. Results: AI-based tools have demonstrated effectiveness in identifying supraventricular arrhythmias like atrial fibrillation (AF) and atrial flutter (AFL), as well as complex conditions such as ventricular tachycardias (VTs) and long QT syndrome (LQTS). In procedural contexts, AI enhances electro-anatomical mapping, reduces operative time, and supports tailored post-ablation management. Discussion: While AI offers clear advantages in diagnostic accuracy and procedural efficiency, challenges remain regarding data security, ethical transparency, and clinical adoption. Addressing these limitations will be crucial for integrating AI into routine electrophysiology and maximizing its potential in future cardiology practice. Full article

Background: Pulse field ablation (PFA) is a novel ablation technology with efficacy and safety, potentially making it a preferred ablation technology for persistent atrial fibrillation (AF). There is no optimal procedural workflow established to optimize efficacy, limiting the number of PFA applications and risks of the procedure. Due to the importance of optimal catheter–tissue contact for effective pulse field ablation, a workflow combining superior left atrial intracardiac echo (ICE) imaging and electroanatomic mapping (EAM) is an attractive strategy for PFA of persistent AF. Methods: A detailed procedural workflow was developed for fluoroscopy-free PFA using a pentaspline ablation catheter supported by left atrial ICE and EAM, and a case series of its execution in 30 consecutive patients with persistent AF is presented. All patients underwent pulmonary vein and posterior wall isolation as the index procedure, followed by additional ablation targeting non-pulmonary vein triggers and other inducible atrial arrhythmias. Results: Left atrial ICE imaging and EAM guided procedure resulted in successful isolation of the pulmonary veins and posterior wall in all patients, with additional ablation of spontaneous arrhythmias or non-pulmonary triggers if induced. There were no major complications of the procedure. Average procedure times and short-term efficacy were comparable with reported PFA outcomes using traditional imaging techniques. Conclusions: Fluoroscopy-free PFA guided by left-sided ICE for persistent AF can be performed with superior catheter–tissue contact imaging in a safe manner with a comparable procedural time and short-term efficacy as reported with the use of other imaging modalities. Full article

Background/Objectives: Atrial fibrillation (AF) is the most common sustained arrhythmia, with catheter ablation outcomes differing significantly between paroxysmal and persistent forms. While pulmo-nary vein isolation (PVI) remains the cornerstone of ablation, persistent AF is often associ-ated with atrial remodeling and non-pulmonary vein triggers, reducing procedural success rates and necessitating repeat interventions. However, in selected patients with minimal atrial substrate, a single PVI may achieve durable rhythm control. This case report illus-trates such a scenario in a young patient with persistent AF and tachyarrhythmia-induced cardiomyopathy (TIC). Methods: A 42-year-old previously healthy male presented with newly diagnosed persistent AF complicated by TIC and heart fail-ure (left ventricular ejection fraction [LVEF] 25%). Despite rate control, anticoagulation, guideline-directed heart failure therapy, amiodarone pretreatment, and two failed electrical cardioversions, the patient remained symptomatic. Elec-troanatomic mapping was performed to assess atrial substrate prior to radiofrequency ablation. Results: Mapping revealed no extensive low-voltage zones, indicating absence of significant atrial fibrosis. During ablation, si-nus rhythm was restored spontaneously with a single application targeting the infero-posterior aspect of the right infe-rior pulmonary vein. No additional arrhythmogenic substrate was identified. The patient maintained sinus rhythm throughout 14 months of follow-up, with marked clinical improvement, normalization of LVEF (55%), regression of atrial and ventricular enlargement, and resolution of heart failure symptoms. Quality of life, assessed by the ASTA question-naire, improved from 24 to 0 points. Conclusions: This case highlights that even in therapy-resistant persistent AF with severe structural and functional cardiac impairment, arrhythmia may be driven by discrete pulmonary vein-dependent mechanisms. Careful patient selection, particu-larly in younger individuals without advanced atrial remodeling, can identify those in whom PVI alone achieves durable rhythm control and reverse cardiac remodeling. Full article

Background: The VARIPULSE platform is an advanced Pulsed Field Ablation (PFA) system fully integrated with electro-anatomical mapping system, employing a variable loop circular catheter (VLCC) for atrial fibrillation (AF) ablation. The objective of the study is to assess for the first time the feasibility, safety, and procedural impact of AI (artificial intelligence)-assisted ICE (intracardiac echocardiography) mapping with the CARTOSOUND FAM Module compared with conventional electroanatomical mapping during PFA. Methods: In this retrospective, multicenter study, 157 consecutive patients undergoing PFA for paroxysmal or persistent AF were included. Patients were divided into two groups: ICE-guided cohort (n = 64) and non-ICE-guided cohort (n = 93). Propensity score matching (PSM) was used to adjust for baseline differences. Results: AI-assisted ICE mapping was feasible in all cases. Compared with conventional mapping, it significantly reduced LA (left atrium) mapping time (median 5 vs. 8 min; p < 0.001), LA dwell time (33.5 vs. 38.5 min; p = 0.001), and fluoroscopy time (7.5 vs. 14 min; p < 0.001). The total number of PFA applications was similar across groups (p = 0.136). No major adverse events occurred in either cohort during the procedure or within the first month of follow-up. Conclusions: AI-assisted ICE mapping using the CARTOSOUND FAM Module enables accurate anatomical reconstruction and significantly optimizes procedural efficiency in PFA. This approach supports further development toward radiation-sparing and potentially fluoroscopy-free PFA workflows. For the first time, it addresses a gap in the current evidence regarding the use of ICE in PFA, building on evidence already established for radiofrequency ablation procedures. Full article

Percutaneous coronary intervention (PCI) is a widely performed revascularisation procedure for coronary artery disease. Although effective, its reliance on fluoroscopy and iodinated contrast exposes patients and operators to risks of radiation and nephrotoxicity. As PCI techniques have become more complex, interest has grown in imaging methods that reduce dependence on fluoroscopy and contrast. Electro-anatomical mapping systems (EAMS), developed for catheter navigation in electrophysiology, enable real-time three-dimensional visualisation without the need for fluoroscopy or contrast. By adapting coronary guidewires as electrodes, EAMS can reconstruct vessel anatomy and track interventional tools in real time. EAMS have demonstrated feasibility and safety in device implantation, and early studies suggest their applicability to PCI, where they may mitigate radiation and contrast exposure by providing an alternative method for guidewire and stent visualisation. This review provides a narrative overview of current evidence, outlining the technical principles, applications in device implantation, and the emerging role of EAMS in coronary intervention. Full article

Background/Objectives: For many years, catheter ablation (CA) has been a cornerstone in atrial fibrillation (AF) rhythm control therapy; however, recurrence remains common. Multiple parameters have been proposed to quantify AF arrhythmogenic substrate, yet reliable predictors of long-term outcomes are lacking. To assess the value of non-invasive amplified P-wave duration (PWD), echocardiographic parameters, biomarkers, and electroanatomical mapping (EAM) were used in predicting left atrial (LA) fibrosis and arrhythmia recurrence after CA. Methods: We included 196 patients undergoing first CA for paroxysmal or persistent AF. Amplified 12-lead ECG PWD parameters [Pmax, Pmin and left atrial P-wave (LAP)], echocardiographic parameters, and biomarkers were assessed pre-procedure. We measured low-voltage areas (LVA, 0.2–0.5 mV) on high-density voltage EAM during sinus rhythm as a surrogate of fibrosis. Freedom from arrhythmia was evaluated at 6 and 12 months. Results: Patients with LVA on EAM had prolonged Pmax (148 vs. 135 ms, p < 0.0001), Pmin (111 vs. 101.5 ms, p = 0.0001), LAP (73.5 vs. 55.5 ms, p < 0.0001), larger LA diameter (p = 0.0002), area (p = 0.0365) and volume (p = 0.004), higher E/E’ (p = 0.0007) and E/A ratios (p = 0.037), more mitral regurgitation (p = 0.0315), and higher pro-BNP levels (p = 0.0094). Univariate analysis showed 12-month recurrence rates higher with greater Pmax, Pmin, LAP, LVA presence and extent; however, in multivariate analysis, only P-wave parameters remained independently associated with recurrence. Conclusions: Prolonged PWD parameters strongly reflect LA substrate (Pmax, Pmin) and independently predict post-ablation AF recurrence (Pmax, Pmin, and LAP). LA size, diastolic dysfunction, and mitral regurgitation were associated with LA fibrosis, while pro-BNP was associated with both fibrosis and arrhythmia recurrence. Integrating these simple, non-invasive markers into a multimodal assessment alongside EAM could improve pre-procedural risk stratification and guide individualized ablation strategies. Full article

Background: Left ventricular (LV) summit is an important origin for ventricular arrhythmias (VAs). However, the complex electroanatomic structure of LV summit and the surrounding anatomic sites makes ablation of this arrhythmia challenging. Aim: In this paper, we review the main strategies to mapping and ablation of LV summit VAs and summarize our experience in this challenging ablation. Methods: To summarize our experience, we included all consecutive patients with outflow VAs referred to our institute for ablation between 2019 and 2024 who were eventually diagnosed with LV summit origin based on electroanatomical mapping and ablation result using stepwise and sequential ablation approach. Results: A total of 38 patients were found to have VAs from LV summit origin. Overall five patients had history of at least one failed ablation. V1 transition was seen in 15 patients, V2 transition in 12 patients, and V3 transition in 11 patients. Four patients had R wave pattern break in lead V2. Ablation was performed from the earliest activation or from one of the adjacent sites using stepwise and sequential approach. Acute suppression of VAs occurred in 35 patients without complications, except one case of pseudoaneurysm of femoral artery. Conclusions: Stepwise and sequential ablation approach can suppress VAs originating from LV summit in most patients. Full article

Introduction: The radiofrequency catheter ablation (RFCA) of ventricular arrhythmias (VAs) originating from the right ventricular outflow tract (RVOT) is a well-established therapy. Traditionally, RFCA is guided using electroanatomical 3D mapping systems involving manual catheter navigation within cardiac chambers. While effective, this approach may be time-consuming, and it carries a potential risk of cardiac wall perforation. Although the risk is low, it cannot be underestimated. Therefore, alternative mapping methods are sought to reduce procedural times and improve the overall efficiency of RVOT-VAs ablation. Aim: To evaluate the safety, feasibility, and efficacy of a universal RVOT 3D model implementation for the ablation of idiopathic RVOT-VAs. Methods: Consecutive patients undergoing VA ablation supported with a universal RVOT 3D model (3D-MODEL group) were included in the study. The RVOT universal model in this group was created by processing DICOM images for the improved segmentation of anatomical structures, followed by production using 3D printing technology. Patients who underwent classic endocardial electroanatomical mapping served as controls (EAM group). Results: A total of 228 patients were included in the study (143 women, age 50 ± 17 years): 149 in the 3D-MODEL group and 79 in the EAM group. The acute complete elimination of clinical VAs was achieved for 133 (89%) of patients in the 3D-MODEL group vs. 65 (82%) in the EAM group (p = 0.14). The procedural time was significantly shorter in the 3D-MODEL group compared to the EAM group (38 ± 14 min vs. 80 ± 39 min, p < 0.001). A significant difference was also observed in the radiofrequency time between the 3D-MODEL and EAM groups (251 ± 176 s vs. 503 ± 425 s, p < 0.001). No significant difference in fluoroscopy time was found between the groups (284 ± 167 s vs. 260 ± 327 s, p = 0.49). Two cases of cardiac tamponade occurred, both in patients from the EAM group. During follow-up, lasting 14 ± 10 months, 87% of patients in the 3D-MODEL group and 75% in the EAM group remained arrhythmia-free (p = 0.45). Conclusions: The use of universal RVOT 3D modeling is a feasible, safe, and effective alternative to classic electroanatomical mapping in the ablation of idiopathic RVOT-VAs. Full article

Ventricular tachycardia (VT) remains a major cause of morbidity and mortality in patients with structural heart disease. While catheter ablation has become a cornerstone in VT management, recurrence rates remain substantial due to limitations in electroanatomic mapping (EAM), particularly in cases of deep or heterogeneous arrhythmogenic substrates. Cardiac imaging, especially when multimodal and integrated with mapping systems, has emerged as a critical adjunct to enhance procedural efficacy, safety, and individualized strategy. This comprehensive review explores the evolving role of various imaging modalities, including echocardiography, cardiac magnetic resonance (CMR), computed tomography (CT), positron emission tomography (PET), and intracardiac echocardiography (ICE), in the preprocedural and intraprocedural phases of VT ablation. We highlight their respective strengths in substrate identification, anatomical delineation, and real-time guidance. While limitations persist, including costs, availability, artifacts in device carriers, and lack of standardization, future advances are likely to redefine procedural workflows. Full article

Background: Atrial fibrosis is a key contributor to atrial cardiomyopathy and can be assessed invasively using mean left atrial voltage (MLAV) from electroanatomical mapping. However, the invasive nature of this procedure limits its clinical applicability. Machine learning (ML), particularly regression tree-based models, may offer a non-invasive approach for predicting MLAV using clinical and echocardiographic data, improving non-invasive atrial fibrosis characterisation beyond current dichotomous classifications. Methods: We prospectively included and followed 113 patients with paroxysmal or persistent atrial fibrillation (AF) undergoing pulmonary vein isolation (PVI) with ultra-high-density voltage mapping (uHDvM), from whom MLAV was estimated. Standardised two-dimensional transthoracic echocardiography was performed before ablation, and clinical and echocardiographic variables were analysed. A regression tree model was constructed using the Classification and Regression Trees—CART-algorithm to identify key predictors of MLAV. Results: The regression tree model exhibited moderate predictive accuracy (R² = 0.63; 95% CI: 0.55–0.71; root mean squared error = 0.90; 95% CI: 0.82–0.98), with indexed minimum LA volume and passive emptying fraction emerging as the most influential variables. No significant differences in AF recurrence-free survival were found among MLAV tertiles or model-based generated groups (log-rank p = 0.319 and p = 0.126, respectively). Conclusions: We present a novel ML-based regression tree model for non-invasive prediction of MLAV, identifying minimum LA volume and passive emptying fraction as the most significant predictors. This model offers an accessible, non-invasive tool for refining atrial cardiomyopathy characterisation by reflecting the fibrotic substrate as a continuum, a crucial advancement over existing dichotomous approaches to guide tailored therapeutic strategies. Full article

Background: The influence of the initial ablation modality on pulmonary vein (PV) reconnection and substrate characteristics in redo procedures for recurrent atrial fibrillation (AF) remains unclear. We assessed how different thermal strategies—ablation index (AI)-guided radiofrequency (RF) versus cryoballoon (CB) ablation—affect remapping findings during redo pulmonary vein isolation (PVI). Methods: We included patients undergoing redo ablation between 2015 and 2024 with high-density electroanatomic mapping. Initial PVI modalities were retrospectively classified as low-power, long-duration (LPLD) RF; high-power, short-duration (HPSD) RF; or second-/third-generation CB. Reconnection sites were mapped using multielectrode catheters. Redo PVI was performed using AI-guided RF. Segments showing PV reconnection were reisolated; if all PVs remained isolated and AF persisted, posterior wall isolation was performed. Results: Among 195 patients (LPLD: 63; HPSD: 30; CB: 102), complete PVI at redo was observed in 0% (LPLD), 23.3% (HPSD), and 10.1% (CB) (p < 0.01 for LPLD vs. HPSD). Reconnection patterns varied by technique; LPLD primarily affected the right carina, while HPSD and CB showed reconnections at the LSPV ridge. Organized atrial tachycardia was least frequent after CB (12.7%, p < 0.002). Conclusion: Initial ablation strategy significantly influences PV reconnection and post-PVI arrhythmia patterns, with implications for redo procedure planning. Full article

Background: Atypical atrial flutter (AFL) is a complex clinical challenge, particularly in patients with prior atrial fibrillation (AF) treated with pulmonary vein isolation (PVI). Arrhythmias involving the vein of Marshall (VOM) often require extensive lesion sets, including ethanol infusion, to effectively target the epicardial substrate. To minimize tissue damage, an alternative strategy has been proposed, emphasizing advanced electroanatomical mapping, entrainment maneuvers, and highly targeted ablation techniques. Case Presentation: We describe a 72-year-old woman with recurrent atrial arrhythmias following pulmonary vein isolation (PVI), who presented with palpitations as her primary symptom. After ineffective pharmacological therapy, she underwent a catheter ablation procedure. Electroanatomical mapping revealed significant left atrial scarring and suggested a macroreentrant circuit involving the VOM. Entrainment maneuvers confirmed the VOM’s involvement. A single targeted endocardial ablation guided by the ablation index terminated the arrhythmia within 12 s, without the need for ethanol infusion or extensive lesion sets. Discussion: This case underscores the VOM’s role in sustaining atypical AFL post-PVI and highlights the effectiveness of precise electroanatomical mapping combined with targeted endocardial ablation. Unlike broader ablation or ethanol infusion strategies, a focused lesion at the critical isthmus achieved arrhythmia termination with minimal tissue damage. Conclusions: Endocardial ablation at the site of entrainment can safely and effectively treat VOM-related AFL, offering symptom relief and restoration of sinus rhythm. This approach may reduce procedural risks and expand the feasibility of VOM-related arrhythmia management in centers without access to ethanol infusion. Full article

Brugada syndrome (BrS) has been traditionally considered a pure electrical disorder without an underlying structural substrate. However, early ECG studies showed the presence of depolarization abnormalities in this condition, while many studies based on advanced imaging have suggested the presence of subtle structural alterations. On the other hand, electrophysiological study (EPS) and electroanatomic mapping (EAM) techniques have provided important data regarding right ventricular functional and structural arrhythmic substrate. More recently, histology and immunology shed light on the possible role of fibrotic and inflammatory substrates in BrS. Notably, a significant overlap between electro anatomical and structural features in BrS and arrhythmogenic cardiomyopathy has been proposed. In this review, we summarized the physio pathological pathways and substrate underlying BrS. A deeper knowledge of the structural abnormalities involved in the pathogenesis of this disease could improve our diagnostic and prognostic approach, while novel findings regarding the role of inflammation and immune activation could potentially lead to new therapeutic strategies for BrS. Full article