高频导管消融后阻抗升高导致左冠状动脉主干急性闭塞 "的社论:为 EP 实验室的灾难性事件做好准备

IF 2.2 Q2 CARDIAC & CARDIOVASCULAR SYSTEMS Journal of Arrhythmia Pub Date : 2024-08-11 DOI:10.1002/joa3.13132
Satoshi Higa MD, PhD, FHRS
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During a 6-year long-term follow-up, the patient remained free of stent restenosis.</p><p>Current guidelines provide enough evidence of highly successful outcomes with overall cure rates of catheter ablation of idiopathic ventricular arrhythmias (VAs) and propose as a first-line therapy. However, successful ablation cannot be obtained in some populations due to anatomic limitations. For this particular reason, one of the most challenging issues that physicians may encounter in the EP laboratory is the approach to VAs originating from the left ventricular summit (LVS). Highly variable complex anatomies between the LVS and neighboring structures emphasizes the importance of a detailed characterization of the individual anatomy of this region and the use of 3D-anatomical reconstructions using image integration of ICE (intracardiac echocardiography) or a computed tomography for precise and safe mapping and ablation procedures. Although, the LVS can be accessed directly via an epicardial approach, the approach to this superior region usually is very limited due to the close proximity to the LMCA and thick fat layer. Practically, VAs originating from the epicardial aspect of the LVS can be targeted from the anterior interventricular vein (AIV)/great cardiac vein (GCV). On the other hand, the endocardial to intramural aspect of the LVS can be approached from the LCC, left ventricular outflow tract (LVOT) endocardium, or right ventricular outflow tract (RVOT) septal side. Due to the close proximity of multiple structures and nature of the preferential conduction around this region, the pace mapping method's efficacy for localizing VA origins may be poor. Therefore, activation mapping during spontaneous VAs is mandatory for localizing VA origins. In general, an earlier activation time in the distal GCV or proximal AIV than other sites within the RV/LVOT suggests epicardial LVS VAs. Regarding the ECG characteristics of the author's case, the previous algorithm using the aVL/aVR Q-wave ratio for LVS VAs supports a GCV/AIV region.<span><sup>2</sup></span> Furthermore, finding an earlier ventricular activation time preceding the QRS onset and unipolar electrogram morphology with a QS pattern also suggest a GCV/AIV origin. For more accurate localization of VA origins, epicardial LVS mapping using a 0.014-inch guidewire or 2Fr multiple electrode catheter through the GCV/AIV can be feasible. Ablation procedure problematic issues within the GCV/AIV are the difficulty in advancing ablation catheters to target sites because of relatively smaller vessel sizes, inability to apply an appropriate radiofrequency energy due to high impedances and/or insufficient blood cooling flow, and close proximity to the LMCA. If ablation within the GCV/AIV is not feasible or unsuccessful ablation results, the next mapping/ablation target would be the LCC, LVOT endocardial, or RVOT septal side. In this case, the ventricular activation time and an rS unipolar electrogram morphology suggest that the LCC was not an ideal target. However, the authors attempted to ablate in the LCC because ablating in the AIV failed due to a high impedance. According to a multicenter study, the procedural success rate of the conventional approach is relatively low despite both endocardial and/or epicardial approaches.<span><sup>3</sup></span> To overcome unfavorable outcomes correlated with anatomical limitations, several alternative techniques including ablation using small 5Fr-ablation catheters, low energy ablation using a guidewire, anatomical bipolar ablation, and focal monopolar pulsed field ablation can be used for eliminating epicardial VAs.</p><p>The case report by Koyama et al.<span><sup>1</sup></span> highlights safety concerns when performing ablation in the coronary cusp and the requirement for immediate management of a lethal complications. LMCA occlusions and thromboembolisms can cause severe an acute myocardial infarction or in-hospital death. The authors suggested two potential causes underlying the acute LMCA occlusion in this case. Firstly, radiofrequency energy could induce heat conduction from the left coronary artery ostium and cause subsequent LMCA thermal injury. Secondly, temporary catheter migration into the LMCA and accidental intracoronary radiofrequency applications could induce direct thermal injury causing an LMCA occlusion. Although the authors provided IVUS imaging exhibiting intimal thickening and tissue protrusion within the stent, the precise mechanism of the LMCA's acute occlusion and persistent in-stent restenosis that required repeated balloon inflations remains unclear. In a previous review article, Castaño et al.<span><sup>4</sup></span> summarized three mechanisms of radiofrequency energy-induced acute coronary artery occlusions including coronary spasms by heat-induced nervus terminalis modulation, direct vessel trauma by collagen shrinkage and subsequent vessel narrowing, and thromboembolisms. Interestingly, radiofrequency energy delivered adjacent and parallel to vessels results in lesions formation limited to the intima-media. However, radiofrequency energy delivered directly and perpendicularly to vessels induces severe intimal hyperplasia and thrombosis formation. Therefore, both the radiofrequency energy's extent and catheter tip orientation with the coronary artery are very important considerations for electrophysiologists.</p><p>Catheter ablation in the coronary cusp can be complicated by potentially disastrous outcomes in cases with LMCA involvement. LMCA injury is a rare but potentially life-threatening complication. A retrospective analysis by Klaudel et al.<span><sup>5</sup></span> demonstrated 22 cases of serious LMCA damage identified between 1987 and 2018. Eighty-six percent of LMCA trauma cases manifest with dramatic life-threatening arrhythmias, cardiogenic shock, or severe hypotension. The in-hospital mortality rate is high (32%) and direct stenting is the most effective strategy. Considering safety issues, visualization of the coronary artery by angiography and/or an ICE should be mandatory during ablation in this area. Physicians also should perform careful impedance monitoring to avoid catheter migration into vessels. Furthermore, adequate sedation of the patient is very important to minimize sudden uncontrolled motions and to enhance catheter stability for avoiding catheter dislodgement.</p><p>To ensure emergent management, electrophysiologists need to establish a team-based cross-specialty approach with close corporation with highly experienced coronary interventionists and cardiovascular surgeons.</p><p>None.</p><p>The author has potential conflicts of interest: S.H. is a consultant to Japan Lifeline, Johnson &amp; Johnson, Boston Scientific, and Medtronic, and received speaker's honoraria from Japan Lifeline, Johnson &amp; Johnson, Boston Scientific, Medtronic, Abbott, and Biotronik, and the Boehringer-Ingelheim, Bristol-Myers, Bayer, Pfizer, Daiichi-Sankyo, Mochida and Ono Pharmaceutical Companies.</p><p>None.</p><p>None.</p><p>None.</p>","PeriodicalId":15174,"journal":{"name":"Journal of Arrhythmia","volume":"40 5","pages":"1175-1176"},"PeriodicalIF":2.2000,"publicationDate":"2024-08-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/joa3.13132","citationCount":"0","resultStr":"{\"title\":\"Editorial to “Acute occlusion of the left main coronary artery following impedance rise after high-frequency catheter ablation”: Prepare for a disastrous matter in the EP laboratory\",\"authors\":\"Satoshi Higa MD, PhD, FHRS\",\"doi\":\"10.1002/joa3.13132\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>In this issue of the <i>Journal of Arrhythmia</i>, Koyama et al.<span><sup>1</sup></span> reported a case of frequent premature ventricular contractions complicated with a left main coronary artery (LMCA) occlusion post-ablation in the left coronary cusp (LCC). Although they emergently performed angioplasty and implanted a drug-eluting stent, coronary angiography showed a 99% in-stent acute stenosis requiring repeat balloon dilatations. Intravascular ultrasound (IVUS) revealed intimal thickening and tissue protrusion within the stent. Finally, the in-stent restenosis completely resolved after additional balloon dilatations. The patient was successfully weaned from assisted circulation and was discharged on postoperative Day 7. During a 6-year long-term follow-up, the patient remained free of stent restenosis.</p><p>Current guidelines provide enough evidence of highly successful outcomes with overall cure rates of catheter ablation of idiopathic ventricular arrhythmias (VAs) and propose as a first-line therapy. However, successful ablation cannot be obtained in some populations due to anatomic limitations. For this particular reason, one of the most challenging issues that physicians may encounter in the EP laboratory is the approach to VAs originating from the left ventricular summit (LVS). Highly variable complex anatomies between the LVS and neighboring structures emphasizes the importance of a detailed characterization of the individual anatomy of this region and the use of 3D-anatomical reconstructions using image integration of ICE (intracardiac echocardiography) or a computed tomography for precise and safe mapping and ablation procedures. Although, the LVS can be accessed directly via an epicardial approach, the approach to this superior region usually is very limited due to the close proximity to the LMCA and thick fat layer. Practically, VAs originating from the epicardial aspect of the LVS can be targeted from the anterior interventricular vein (AIV)/great cardiac vein (GCV). On the other hand, the endocardial to intramural aspect of the LVS can be approached from the LCC, left ventricular outflow tract (LVOT) endocardium, or right ventricular outflow tract (RVOT) septal side. Due to the close proximity of multiple structures and nature of the preferential conduction around this region, the pace mapping method's efficacy for localizing VA origins may be poor. Therefore, activation mapping during spontaneous VAs is mandatory for localizing VA origins. In general, an earlier activation time in the distal GCV or proximal AIV than other sites within the RV/LVOT suggests epicardial LVS VAs. Regarding the ECG characteristics of the author's case, the previous algorithm using the aVL/aVR Q-wave ratio for LVS VAs supports a GCV/AIV region.<span><sup>2</sup></span> Furthermore, finding an earlier ventricular activation time preceding the QRS onset and unipolar electrogram morphology with a QS pattern also suggest a GCV/AIV origin. For more accurate localization of VA origins, epicardial LVS mapping using a 0.014-inch guidewire or 2Fr multiple electrode catheter through the GCV/AIV can be feasible. Ablation procedure problematic issues within the GCV/AIV are the difficulty in advancing ablation catheters to target sites because of relatively smaller vessel sizes, inability to apply an appropriate radiofrequency energy due to high impedances and/or insufficient blood cooling flow, and close proximity to the LMCA. If ablation within the GCV/AIV is not feasible or unsuccessful ablation results, the next mapping/ablation target would be the LCC, LVOT endocardial, or RVOT septal side. In this case, the ventricular activation time and an rS unipolar electrogram morphology suggest that the LCC was not an ideal target. However, the authors attempted to ablate in the LCC because ablating in the AIV failed due to a high impedance. According to a multicenter study, the procedural success rate of the conventional approach is relatively low despite both endocardial and/or epicardial approaches.<span><sup>3</sup></span> To overcome unfavorable outcomes correlated with anatomical limitations, several alternative techniques including ablation using small 5Fr-ablation catheters, low energy ablation using a guidewire, anatomical bipolar ablation, and focal monopolar pulsed field ablation can be used for eliminating epicardial VAs.</p><p>The case report by Koyama et al.<span><sup>1</sup></span> highlights safety concerns when performing ablation in the coronary cusp and the requirement for immediate management of a lethal complications. LMCA occlusions and thromboembolisms can cause severe an acute myocardial infarction or in-hospital death. The authors suggested two potential causes underlying the acute LMCA occlusion in this case. Firstly, radiofrequency energy could induce heat conduction from the left coronary artery ostium and cause subsequent LMCA thermal injury. Secondly, temporary catheter migration into the LMCA and accidental intracoronary radiofrequency applications could induce direct thermal injury causing an LMCA occlusion. Although the authors provided IVUS imaging exhibiting intimal thickening and tissue protrusion within the stent, the precise mechanism of the LMCA's acute occlusion and persistent in-stent restenosis that required repeated balloon inflations remains unclear. In a previous review article, Castaño et al.<span><sup>4</sup></span> summarized three mechanisms of radiofrequency energy-induced acute coronary artery occlusions including coronary spasms by heat-induced nervus terminalis modulation, direct vessel trauma by collagen shrinkage and subsequent vessel narrowing, and thromboembolisms. Interestingly, radiofrequency energy delivered adjacent and parallel to vessels results in lesions formation limited to the intima-media. However, radiofrequency energy delivered directly and perpendicularly to vessels induces severe intimal hyperplasia and thrombosis formation. Therefore, both the radiofrequency energy's extent and catheter tip orientation with the coronary artery are very important considerations for electrophysiologists.</p><p>Catheter ablation in the coronary cusp can be complicated by potentially disastrous outcomes in cases with LMCA involvement. LMCA injury is a rare but potentially life-threatening complication. A retrospective analysis by Klaudel et al.<span><sup>5</sup></span> demonstrated 22 cases of serious LMCA damage identified between 1987 and 2018. Eighty-six percent of LMCA trauma cases manifest with dramatic life-threatening arrhythmias, cardiogenic shock, or severe hypotension. 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引用次数: 0

摘要

在本期《心律失常杂志》(Journal of Arrhythmia)上,Koyama 等人1 报告了一例左冠状动脉尖(LCC)消融术后左冠状动脉主干(LMCA)闭塞并发频繁室性早搏的病例。虽然他们紧急实施了血管成形术并植入了药物洗脱支架,但冠状动脉造影显示支架内急性狭窄达 99%,需要反复进行球囊扩张。血管内超声(IVUS)显示支架内膜增厚,组织突出。最后,经过多次球囊扩张,支架内再狭窄完全消除。患者成功脱离辅助循环,并于术后第 7 天出院。在 6 年的长期随访中,患者一直没有发生支架再狭窄。目前的指南提供了足够的证据,证明特发性室性心律失常(VAs)的导管消融术在总体治愈率方面取得了非常成功的结果,并建议将其作为一线疗法。然而,由于解剖结构的限制,有些人群无法成功消融。由于这一特殊原因,医生在 EP 实验室可能遇到的最具挑战性的问题之一就是如何处理源于左心室峰(LVS)的室性心律失常。LVS 与邻近结构之间的复杂解剖结构千变万化,因此必须对这一区域的个体解剖结构进行详细描述,并利用 ICE(心内超声心动图)或计算机断层扫描的图像集成进行三维解剖重建,以实现精确、安全的绘图和消融手术。虽然可以通过心外膜途径直接进入 LVS,但由于 LVS 靠近 LMCA 且脂肪层较厚,因此进入这一上部区域的途径通常非常有限。实际上,可以从室间隔前静脉(AIV)/心脏大静脉(GCV)对源自 LVS 心外膜的 VA 进行定位。另一方面,可以从 LCC、左室流出道(LVOT)心内膜或右室流出道(RVOT)室间隔侧接近 LVS 的心内膜至膜内侧。由于该区域附近有多个结构和优先传导的性质,步伐图法定位 VA 起源的效果可能较差。因此,自发VA时的激活图谱是定位VA起源的必要条件。一般来说,GCV 远端或 AIV 近端激活时间早于 RV/LVOT 内的其他部位提示心外膜左心室 VA。关于作者病例的心电图特征,之前使用 aVL/aVR Q 波比率来确定 LVS VA 的算法支持 GCV/AIV 区域。2 此外,发现 QRS 起始前较早的心室激活时间和具有 QS 模式的单极电图形态也提示 GCV/AIV 起源。为了更准确地定位 VA 起源,可以使用 0.014 英寸导丝或 2Fr 多电极导管通过 GCV/AIV 绘制心外膜 LVS 图。在 GCV/AIV 内进行消融术存在的问题包括:由于血管尺寸相对较小,很难将消融导管推进到目标部位;由于阻抗高和/或血液冷却流不足,无法应用适当的射频能量;以及靠近 LMCA。如果在 GCV/AIV 内消融不可行或消融不成功,下一个映射/消融目标将是 LCC、LVOT 心内膜或 RVOT 间隔侧。在本病例中,心室激活时间和 rS 单极电图形态表明 LCC 不是理想的目标。然而,作者尝试在 LCC 进行消融,因为在 AIV 进行消融因阻抗过高而失败。根据一项多中心研究,尽管采用了心内膜和/或心外膜方法,但传统方法的手术成功率相对较低。Koyama 等人的病例报告1 强调了在冠状动脉尖进行消融时的安全问题,以及立即处理致命并发症的要求。LMCA 闭塞和血栓栓塞可导致严重的急性心肌梗死或院内死亡。作者认为,本病例中 LMCA 急性闭塞的潜在原因有两个。首先,射频能量可能诱发左冠状动脉骨膜的热传导,导致 LMCA 热损伤。其次,导管暂时移入 LMCA 和意外的冠状动脉内射频应用可能引起直接热损伤,导致 LMCA 闭塞。
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Editorial to “Acute occlusion of the left main coronary artery following impedance rise after high-frequency catheter ablation”: Prepare for a disastrous matter in the EP laboratory

In this issue of the Journal of Arrhythmia, Koyama et al.1 reported a case of frequent premature ventricular contractions complicated with a left main coronary artery (LMCA) occlusion post-ablation in the left coronary cusp (LCC). Although they emergently performed angioplasty and implanted a drug-eluting stent, coronary angiography showed a 99% in-stent acute stenosis requiring repeat balloon dilatations. Intravascular ultrasound (IVUS) revealed intimal thickening and tissue protrusion within the stent. Finally, the in-stent restenosis completely resolved after additional balloon dilatations. The patient was successfully weaned from assisted circulation and was discharged on postoperative Day 7. During a 6-year long-term follow-up, the patient remained free of stent restenosis.

Current guidelines provide enough evidence of highly successful outcomes with overall cure rates of catheter ablation of idiopathic ventricular arrhythmias (VAs) and propose as a first-line therapy. However, successful ablation cannot be obtained in some populations due to anatomic limitations. For this particular reason, one of the most challenging issues that physicians may encounter in the EP laboratory is the approach to VAs originating from the left ventricular summit (LVS). Highly variable complex anatomies between the LVS and neighboring structures emphasizes the importance of a detailed characterization of the individual anatomy of this region and the use of 3D-anatomical reconstructions using image integration of ICE (intracardiac echocardiography) or a computed tomography for precise and safe mapping and ablation procedures. Although, the LVS can be accessed directly via an epicardial approach, the approach to this superior region usually is very limited due to the close proximity to the LMCA and thick fat layer. Practically, VAs originating from the epicardial aspect of the LVS can be targeted from the anterior interventricular vein (AIV)/great cardiac vein (GCV). On the other hand, the endocardial to intramural aspect of the LVS can be approached from the LCC, left ventricular outflow tract (LVOT) endocardium, or right ventricular outflow tract (RVOT) septal side. Due to the close proximity of multiple structures and nature of the preferential conduction around this region, the pace mapping method's efficacy for localizing VA origins may be poor. Therefore, activation mapping during spontaneous VAs is mandatory for localizing VA origins. In general, an earlier activation time in the distal GCV or proximal AIV than other sites within the RV/LVOT suggests epicardial LVS VAs. Regarding the ECG characteristics of the author's case, the previous algorithm using the aVL/aVR Q-wave ratio for LVS VAs supports a GCV/AIV region.2 Furthermore, finding an earlier ventricular activation time preceding the QRS onset and unipolar electrogram morphology with a QS pattern also suggest a GCV/AIV origin. For more accurate localization of VA origins, epicardial LVS mapping using a 0.014-inch guidewire or 2Fr multiple electrode catheter through the GCV/AIV can be feasible. Ablation procedure problematic issues within the GCV/AIV are the difficulty in advancing ablation catheters to target sites because of relatively smaller vessel sizes, inability to apply an appropriate radiofrequency energy due to high impedances and/or insufficient blood cooling flow, and close proximity to the LMCA. If ablation within the GCV/AIV is not feasible or unsuccessful ablation results, the next mapping/ablation target would be the LCC, LVOT endocardial, or RVOT septal side. In this case, the ventricular activation time and an rS unipolar electrogram morphology suggest that the LCC was not an ideal target. However, the authors attempted to ablate in the LCC because ablating in the AIV failed due to a high impedance. According to a multicenter study, the procedural success rate of the conventional approach is relatively low despite both endocardial and/or epicardial approaches.3 To overcome unfavorable outcomes correlated with anatomical limitations, several alternative techniques including ablation using small 5Fr-ablation catheters, low energy ablation using a guidewire, anatomical bipolar ablation, and focal monopolar pulsed field ablation can be used for eliminating epicardial VAs.

The case report by Koyama et al.1 highlights safety concerns when performing ablation in the coronary cusp and the requirement for immediate management of a lethal complications. LMCA occlusions and thromboembolisms can cause severe an acute myocardial infarction or in-hospital death. The authors suggested two potential causes underlying the acute LMCA occlusion in this case. Firstly, radiofrequency energy could induce heat conduction from the left coronary artery ostium and cause subsequent LMCA thermal injury. Secondly, temporary catheter migration into the LMCA and accidental intracoronary radiofrequency applications could induce direct thermal injury causing an LMCA occlusion. Although the authors provided IVUS imaging exhibiting intimal thickening and tissue protrusion within the stent, the precise mechanism of the LMCA's acute occlusion and persistent in-stent restenosis that required repeated balloon inflations remains unclear. In a previous review article, Castaño et al.4 summarized three mechanisms of radiofrequency energy-induced acute coronary artery occlusions including coronary spasms by heat-induced nervus terminalis modulation, direct vessel trauma by collagen shrinkage and subsequent vessel narrowing, and thromboembolisms. Interestingly, radiofrequency energy delivered adjacent and parallel to vessels results in lesions formation limited to the intima-media. However, radiofrequency energy delivered directly and perpendicularly to vessels induces severe intimal hyperplasia and thrombosis formation. Therefore, both the radiofrequency energy's extent and catheter tip orientation with the coronary artery are very important considerations for electrophysiologists.

Catheter ablation in the coronary cusp can be complicated by potentially disastrous outcomes in cases with LMCA involvement. LMCA injury is a rare but potentially life-threatening complication. A retrospective analysis by Klaudel et al.5 demonstrated 22 cases of serious LMCA damage identified between 1987 and 2018. Eighty-six percent of LMCA trauma cases manifest with dramatic life-threatening arrhythmias, cardiogenic shock, or severe hypotension. The in-hospital mortality rate is high (32%) and direct stenting is the most effective strategy. Considering safety issues, visualization of the coronary artery by angiography and/or an ICE should be mandatory during ablation in this area. Physicians also should perform careful impedance monitoring to avoid catheter migration into vessels. Furthermore, adequate sedation of the patient is very important to minimize sudden uncontrolled motions and to enhance catheter stability for avoiding catheter dislodgement.

To ensure emergent management, electrophysiologists need to establish a team-based cross-specialty approach with close corporation with highly experienced coronary interventionists and cardiovascular surgeons.

None.

The author has potential conflicts of interest: S.H. is a consultant to Japan Lifeline, Johnson & Johnson, Boston Scientific, and Medtronic, and received speaker's honoraria from Japan Lifeline, Johnson & Johnson, Boston Scientific, Medtronic, Abbott, and Biotronik, and the Boehringer-Ingelheim, Bristol-Myers, Bayer, Pfizer, Daiichi-Sankyo, Mochida and Ono Pharmaceutical Companies.

None.

None.

None.

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来源期刊
Journal of Arrhythmia
Journal of Arrhythmia CARDIAC & CARDIOVASCULAR SYSTEMS-
CiteScore
2.90
自引率
10.00%
发文量
127
审稿时长
45 weeks
期刊最新文献
Issue Information Dementia risk reduction between DOACs and VKAs in AF: A systematic review and meta-analysis Electro-anatomically confirmed sites of origin of ventricular tachycardia and premature ventricular contractions and occurrence of R wave in lead aVR: A proof of concept study The Japanese Catheter Ablation Registry (J-AB): Annual report in 2022 Slow left atrial conduction velocity in the anterior wall calculated by electroanatomic mapping predicts atrial fibrillation recurrence after catheter ablation—Systematic review and meta-analysis
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