TY - JOUR
AU - Owada,, Shingen
AB - Abstract Background Systemic lupus erythematosus (SLE) is known to cause inappropriate sinus tachycardia (IST). However, there is limited evidence available with regard to the treatment of IST in this setting. In this article, we report a case of drug refractory IST in a patient with SLE treated with radiofrequency catheter ablation (RFCA) using a non-contact mapping system. Case summary A 33-year-old woman had been diagnosed with SLE in 2001. She presented with complaints of persistent palpitations for 1 month and persistent sinus tachycardia. She underwent RFCA using a non-contact mapping system for drug refractory IST. The voltage and activation maps did not show obvious differences in the earliest activation site at heart rates (HRs) 90–150 b.p.m. In contrast, the areas of breakout sites were clearly distinguished between those from the normal P-wave zones at HR <140 b.p.m. and those from higher rate sites at HR >140 b.p.m. Radiofrequency catheter ablation was performed in those areas as the target for ablation. Thereafter, the symptoms steadily disappeared and the maximum HR—using 24-h Holter monitoring—decreased from 156 to 120 b.p.m. Discussion Radiofrequency catheter ablation using a non-contact mapping system was applied to the treatment of drug refractory IST in a patient with SLE. Of note, IST in such patients may be left untreated. This approach may be considered as a first-line therapy option for drug refractory IST in patients with SLE. Inappropriate sinus tachycardia, Systemic lupus erythematosus, Non-contact mapping system , Radiofrequency catheter ablation, Case report Learning points Radiofrequency catheter ablation was used for the treatment of drug refractory inappropriate sinus tachycardia (IST) in a patient with systemic lupus erythematosus. Radiofrequency catheter ablation using non-contact mapping system for the treatment of IST permits successful ablation, while reducing the risk of sinus node injury. Introduction Inappropriate sinus tachycardia (IST) is defined as: (i) a P-wave axis and morphology during the tachycardia similar to that of the sinus rhythm; (ii) a sinus heart rate (HR) >100 b.p.m. at rest; and (iii) a mean HR >90 b.p.m. via 24-h Holter monitoring.1 The autonomic dysfunction and abnormal automaticity of the sinus node involved in IST remain poorly understood.2–7 Although systemic lupus erythematosus (SLE) is known to cause IST,8 therapeutic strategies are not well-documented. Radiofrequency catheter ablation (RFCA) is an acceptable therapy for drug refractory IST.9–11 Herein, we describe the first application of RFCA using a non-contact mapping system for the treatment of drug refractory IST in a patient with SLE. Timeline Dates Events 2001 Diagnosis of systemic lupus erythematosus. October 2017 Awareness of persistent palpitations. 29 November 2017 24-h electrocardiography (ECG) monitoring of the sinus rhythm. The minimum, maximum, and mean heart rates (HRs) were 71, 156, and 103 b.p.m., respectively. Total heart beats (THB)/day: 144 721. Echocardiography did not show structural pathology. Laboratory investigations were unremarkable. Diagnosis of inappropriate sinus tachycardia. Administration of a β-blocker or calcium channel blocker was initiated. 10 September 2018 Hospitalization. 11 September 2018 Radiofrequency catheter ablation. 13 September 2018 Discharge without complications. 9 October 2018 Post-operation follow-up (1 month). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 60, 129, and 82 b.p.m., respectively. THB/day: 115 245. 13 November 2018 Post-operation follow-up (2 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 50, 120, and 77 b.p.m., respectively. THB/day: 107 063. 25 March 2019 Post-operation follow-up (6 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 46, 130, and 78 b.p.m., respectively. THB/day: 107 664. Dates Events 2001 Diagnosis of systemic lupus erythematosus. October 2017 Awareness of persistent palpitations. 29 November 2017 24-h electrocardiography (ECG) monitoring of the sinus rhythm. The minimum, maximum, and mean heart rates (HRs) were 71, 156, and 103 b.p.m., respectively. Total heart beats (THB)/day: 144 721. Echocardiography did not show structural pathology. Laboratory investigations were unremarkable. Diagnosis of inappropriate sinus tachycardia. Administration of a β-blocker or calcium channel blocker was initiated. 10 September 2018 Hospitalization. 11 September 2018 Radiofrequency catheter ablation. 13 September 2018 Discharge without complications. 9 October 2018 Post-operation follow-up (1 month). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 60, 129, and 82 b.p.m., respectively. THB/day: 115 245. 13 November 2018 Post-operation follow-up (2 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 50, 120, and 77 b.p.m., respectively. THB/day: 107 063. 25 March 2019 Post-operation follow-up (6 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 46, 130, and 78 b.p.m., respectively. THB/day: 107 664. Open in new tab Dates Events 2001 Diagnosis of systemic lupus erythematosus. October 2017 Awareness of persistent palpitations. 29 November 2017 24-h electrocardiography (ECG) monitoring of the sinus rhythm. The minimum, maximum, and mean heart rates (HRs) were 71, 156, and 103 b.p.m., respectively. Total heart beats (THB)/day: 144 721. Echocardiography did not show structural pathology. Laboratory investigations were unremarkable. Diagnosis of inappropriate sinus tachycardia. Administration of a β-blocker or calcium channel blocker was initiated. 10 September 2018 Hospitalization. 11 September 2018 Radiofrequency catheter ablation. 13 September 2018 Discharge without complications. 9 October 2018 Post-operation follow-up (1 month). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 60, 129, and 82 b.p.m., respectively. THB/day: 115 245. 13 November 2018 Post-operation follow-up (2 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 50, 120, and 77 b.p.m., respectively. THB/day: 107 063. 25 March 2019 Post-operation follow-up (6 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 46, 130, and 78 b.p.m., respectively. THB/day: 107 664. Dates Events 2001 Diagnosis of systemic lupus erythematosus. October 2017 Awareness of persistent palpitations. 29 November 2017 24-h electrocardiography (ECG) monitoring of the sinus rhythm. The minimum, maximum, and mean heart rates (HRs) were 71, 156, and 103 b.p.m., respectively. Total heart beats (THB)/day: 144 721. Echocardiography did not show structural pathology. Laboratory investigations were unremarkable. Diagnosis of inappropriate sinus tachycardia. Administration of a β-blocker or calcium channel blocker was initiated. 10 September 2018 Hospitalization. 11 September 2018 Radiofrequency catheter ablation. 13 September 2018 Discharge without complications. 9 October 2018 Post-operation follow-up (1 month). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 60, 129, and 82 b.p.m., respectively. THB/day: 115 245. 13 November 2018 Post-operation follow-up (2 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 50, 120, and 77 b.p.m., respectively. THB/day: 107 063. 25 March 2019 Post-operation follow-up (6 months). 24-h ECG monitoring of the sinus rhythm. The minimum, maximum, and mean HR were 46, 130, and 78 b.p.m., respectively. THB/day: 107 664. Open in new tab Case presentation A 33-year-old woman was diagnosed with SLE in 2001. The patient was treated with prednisolone (initial and maintenance dose: 50 and 15 mg/day, respectively). Polyarthritis pain, Raynaud’s sign, and photosensitivity were recognized early in the onset of SLE. After initiation of prednisolone, the SLE symptoms improved. The patient complained of persistent palpitations for 1 month. Examination showed that she was haemodynamically stable. Surface electrocardiography (ECG) revealed narrow QRS tachycardia with a P-wave of 139 b.p.m. The P-wave axis during tachycardia was similar to that observed during sinus rhythm (Figure 1A). Of note, 24-h ECG monitoring showed a minimum, maximum, and mean HR of 71, 156, and 103 b.p.m., respectively. In addition, tachycardia was persistent at rest (Figure 1B). Laboratory investigations revealed proteinuria (2.3 g/day) and positivity for anti-DNA antibody. In contrast, there was no evidence of secondary pathological sinus tachycardia (e.g. anaemia, hyperthyroidism, or neurohormonal disease). Physical examination, chest X-ray, and echocardiography did not yield evidence of clinically overt structural and/or organic heart disease. We diagnosed IST on the basis of diagnostic criteria.1–3 Moreover, bisoprolol (2.5 mg/day), carvedilol (5.0 mg/day), and verapamil (240 mg/day) were administered. However, IST was refractory, and the administration of these agents was discontinued due to the development of adverse effects (i.e. general fatigue, headache, and dizziness). Figure 1 Open in new tabDownload slide Surface electrocardiography pattern of sinus tachycardia (A). Heart rate trend during 24-h electrocardiography monitoring (B). Figure 1 Open in new tabDownload slide Surface electrocardiography pattern of sinus tachycardia (A). Heart rate trend during 24-h electrocardiography monitoring (B). An electrophysiological evaluation was performed to verify the mechanism of arrhythmia and exclude the presence of other arrhythmias. A multielectrode array catheter (EnSite™ Array, St. Jude Medical, St. Paul, MN, USA) was placed in the right atrium (RA), approximately at the level of the superior vena cava and right atrial junction (Figure 2). A 7-Fr quadripolar ablation catheter with a 4-mm-tip electrode (Therapy™, St. Jude Medical, St. Paul, MN, USA) was percutaneously introduced into the RA, while the baseline geometry of the RA was determined. Figure 2 Open in new tabDownload slide A multielectrode array catheter was placed in the right atrium. Figure 2 Open in new tabDownload slide A multielectrode array catheter was placed in the right atrium. Surface ECG at rest prior to ablation showed a sinus rhythm of HR 100 b.p.m. (Figure 3A). Prior to RFCA, the HR was controlled (90–155 b.p.m.) through the intravenous administration of a β1 antagonist and agonist (Figure 3B and C). Moreover, voltage and activation mapping were performed at each HR 90–155 b.p.m. Activation mapping did not show differences in the earliest activation sites (EAS) at HR 90–150 b.p.m. during the intravenous administration of a β1 antagonist and agonist (Figure 4A and B). In contrast, the shift to the posteroseptal of breakout sites (BOS) was clearly distinguished between those from the normal P-wave zones at HR <140 b.p.m. and those from higher-rate sites at HR >140 b.p.m. (Figure 4A). This finding was in accordance with the appearance of tall P-waves (Figure 3C). Radiofrequency catheter ablation for 30–60 s under a pre-set temperature of 50°C and power limit of 30 W was delivered to the target areas of shifted BOS (Figure 4C). The ablation catheter potential prior to ablation was not a complete QS pattern, indicating that it was not the EAS (Figure 4D). Thereafter, the maximum HR decreased to 120 b.p.m. regardless of the intravenous administration of a β1 agonist (Figure 3D). After RFCA, the palpitations were markedly improved. The patient exhibited an uneventful course without evidence of recurrence for ≥6 months. Figure 3 Open in new tabDownload slide Surface electrocardiography at rest (heart rate = 100 b.p.m.) (A). Under intravenous administration of a β1 antagonist (heart rate = 90 b.p.m.) (B). Under intravenous administration of a β1 agonist (heart rate = 155 b.p.m.) (C). After delivery of radiofrequency energy (heart rate = 120 b.p.m.) (D). Figure 3 Open in new tabDownload slide Surface electrocardiography at rest (heart rate = 100 b.p.m.) (A). Under intravenous administration of a β1 antagonist (heart rate = 90 b.p.m.) (B). Under intravenous administration of a β1 agonist (heart rate = 155 b.p.m.) (C). After delivery of radiofrequency energy (heart rate = 120 b.p.m.) (D). Figure 4 Open in new tabDownload slide Right anterior oblique view of the EnSite™ activation (A) and voltage (B) maps showing the right atrium. Green tag with the red circle: the earliest activation site. Yellow circle: target site for ablation (B). Red tag: ablation site (C). Local electrograms from the ablation catheter in the successful ablation point (D). Abl D, ablation catheter distal potential; Abl P, ablation catheter proximal potential; Abl Uni, ablation catheter unipolar potential; HR, heart rate. Figure 4 Open in new tabDownload slide Right anterior oblique view of the EnSite™ activation (A) and voltage (B) maps showing the right atrium. Green tag with the red circle: the earliest activation site. Yellow circle: target site for ablation (B). Red tag: ablation site (C). Local electrograms from the ablation catheter in the successful ablation point (D). Abl D, ablation catheter distal potential; Abl P, ablation catheter proximal potential; Abl Uni, ablation catheter unipolar potential; HR, heart rate. Discussion This is the first reported application of RFCA for the treatment of IST in a patient with SLE. Firstly, RFCA was effective in this setting. Currently, the mechanism of IST in SLE remains poorly understood.12,13 The Systemic Lupus Erythematosus Disease Activity Index (SLEDAI) score is useful for assessing the relationship between the inflammatory activity of SLE and chronic tachycardia (i.e. IST).13 In this case, the SLEDAI score was 6, indicating that sustained SLE activity may induce IST. Furthermore, the IST was refractory to pharmacological therapy; thus, we performed RFCA. Informed consent was provided by the patient prior to the procedure. Following RFCA, the clinical status of the patient improved. Secondly, RFCA using a non-contact mapping system was effective against IST. The non-contact mapping system assists in the rapid, simple, and detailed assessment of sinus node activation, as expressed by the EAS and BOS activation routes per heartbeat.14 Therefore, it may be more effective against arrhythmias with fluctuating HR (i.e. IST) vs. contact mapping system. This approach clearly determined the BOS at different HR. At HR < 140 b.p.m., the BOS was conducted all around, whereas at HR ≥ 140 b.p.m. it shifted to the posteroseptal site. Consequently, it became possible to perform successful ablation without the risk of injury to the sinus nodal function. In this case, the ablation success site was distant from the EAS. This result was consistent with those of a previous study highlighting that a successful RFCA in IST patients may not take place at the earliest site, but at a distant one (mean: 7 mm) from the EAS.10 These findings suggest that the aetiology of IST involves the degeneration of the compact node (plus its paranodal areas) and sinoatrial conduction system. Moreover, autonomic nervous disorder may be involved in the development of IST. Regulation of the autonomic tone induces a shift in the activation site of the sinus node.9 In this case, RFCA using the Ensite™ mapping system effectively and safely separated the areas of the EAS and BOS (target site of RFCA). Conclusion In conclusion, RFCA using a non-contact mapping system was effective for the treatment of drug refractory IST in a patient with SLE. Further studies are warranted to clarify the mechanism of IST and develop therapeutic strategies involving mapping technology for patients with IST. Lead author biography Open in new tabDownload slide Open in new tabDownload slide Reisuke Yoshizawa is a graduate of the Teikyo University School of Medicine in 2008. Currently, he is an interventional cardiac electrophysiologist, and Assistant Professor in Division of Cardiology, Department of Internal Medicine, Iwate Medical University, Japan. Supplementary material Supplementary material is available at European Heart Journal - Case Reports online. Slide sets: A fully edited slide set detailing this case and suitable for local presentation is available online as Supplementary data. Consent: The author/s confirm that written consent for submission and publication of this case report including image(s) and associated text has been obtained from the patient in line with COPE guidance. Conflict of interest: none declared. References 1 Sheldon RS , Grubb BP , Olshansky B , Shen W-K , Calkins H , Brignole M , Raj SR , Krahn AD , Morillo CA , Stewart JM , Sutton R , Sandroni P , Friday KJ , Hachul DT , Cohen MI , Lau DH , Mayuga KA , Moak JP , Sandhu RK , Kanjwal K. 2015 Heart Rhythm Society expert consensus statement on the diagnosis and treatment of postural tachycardia syndrome, inappropriate sinus tachycardia, and vasovagal syncope . Heart Rhythm 2015 ; 12 : e41 – e63 . Google Scholar Crossref Search ADS PubMed WorldCat 2 Olshansky B , Sullivan RM. Inappropriate sinus tachycardia . J Am Coll Cardiol 2013 ; 61 : 793 – 801 . 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Radiofrequency catheter ablation of inappropriate sinus tachycardia guided by activation mapping . J Am Coll Cardiol 2000 ; 35 : 451 – 457 . Google Scholar Crossref Search ADS PubMed WorldCat 11 Lee RJ , Kalman JM , Fitzpatrick AP , Epstein LM , Fisher WG , Olgin JE , Lesh MD , Scheinman MM. Radiofrequency catheter modification of the sinus node for “inappropriate” sinus tachycardia . Circulation 1995 ; 92 : 2919 – 2928 . Google Scholar Crossref Search ADS PubMed WorldCat 12 Maule S , Quadri R , Mirante D , Pellerito RA , Marucco E , Marinone C , Vergani D , Chiandussi L , Zanone MM. Autonomic nervous dysfunction in systemic lupus erythematosus (SLE) and rheumatoid arthritis (RA): possible pathogenic role of autoantibodies to autonomic nervous structures . Clin Exp Immunol 1997 ; 110 : 423 – 427 . Google Scholar Crossref Search ADS PubMed WorldCat 13 Utset TO , Ward AB , Thompson TL , Green SL. Significance of chronic tachycardia in systemic lupus erythematosus . Arthritis Care Res 2013 ; 65 : 827 – 831 . Google Scholar Crossref Search ADS WorldCat 14 Bonhomme CE , Deger FT , Schultz J , Hsu SS. Radiofrequency catheter ablation using non-contact mapping for inappropriate sinus tachycardia . J Interv Card Electrophysiol 2004 ; 10 : 159 – 163 . Google Scholar Crossref Search ADS PubMed WorldCat © The Author(s) 2019. Published by Oxford University Press on behalf of the European Society of Cardiology. This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is properly cited. For commercial re-use, please contact journals.permissions@oup.com
TI - Radiofrequency catheter ablation for inappropriate sinus tachycardia in a patient with systemic lupus erythematosus: a case report
JO - European Heart Journal - Case Reports
DO - 10.1093/ehjcr/ytz102
DA - 2019-09-01
UR - https://www.deepdyve.com/lp/oxford-university-press/radiofrequency-catheter-ablation-for-inappropriate-sinus-tachycardia-is7Ojc5oZZ
VL - 3
IS - 3
DP - DeepDyve
ER -