Mapping of septal ventricular tachycardia: Clinical and experimental correlations^{, , , , ,}

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• 作者：Yuichiro Kawamura ; Pierre L. Pagé ; René ; Cardinal ; Pierre Savard ; Ré ; ginald Nadeau
• 刊名：The Journal of Thoracic and Cardiovascular Surgery
• 出版年：1996
• 出版时间：October 1996
• 年：1996
• 卷：112
• 期：4
• 页码：914-925
• 全文大小：1164 K

文摘

In patients with chronic myocardial infarction, ventricular tachycardia originating in the interventricular septum may account for a significant number of arrhythmia recurrences after direct ablative operations. We used total computer-assisted cardiac mapping (epicardial sock, left and right ventricular endocardial balloon electrode arrays) to assess whether tachycardia originating in deep or right-sided layers of the interventricular septum is associated with a specific pattern of epicardial activation sequence. We performed these studies during operations in 18 patients and during experiments in 12 dogs in which a septal myocardial infarction was produced by ligating the anterior septal coronary artery. Intraseptal needle electrodes were plunged into the septum of all animal preparations to generate pace-mapping data and to obtain intraseptal recordings (six preparations) during reentrant ventricular tachycardia induced by programmed stimulation. In addition, pace-mapping data of infarcted canine heart preparations were compared with those of nine healthy heart preparations. In the clinical study, 31 ventricular tachycardias with a septal site of origin were analyzed. Twenty tachycardias displayed an epicardial breakthrough in the area of the interventricular groove, whereas 11 had an epicardial breakthrough in the right ventricular free wall. Biventricular endocardial mapping revealed that left septal endocardial activation preceded right septal activation in the former and that right septal activation occurred earlier in the latter. In the experimental study, 14 ventricular tachycardias (cycle length 146 ± 34 msec) were induced by programmed stimulation in 11 infarcted heart preparations. Eight tachycardias displaying an epicardial breakthrough on the right ventricle were found to originate in the right ventricular septal subendocardial layers, whereas six tachycardias in which the epicardial breakthrough occurred on the anterior interventricular groove originated in the left ventricular septal subendocardial layers. The epicardial breakthrough preceded the left ventricular endocardial breakthrough in six tachycardias (85.7 % ) originating in intermediate or right ventricular septal layers, but in only one of five tachycardias originating in the left ventricular septal layers. In the pace-mapping study, the epicardial breakthrough shifted progressively from the right ventricular free wall toward the interventricular groove area in response to pacing from the right, intermediate, and left ventricular thirds of the basal septum. This relationship was similar for infarcted and noninfarcted hearts, although transseptal conduction time was prolonged in infarcted hearts (45 ± 10 msec vs 33 ± 7 msec, p < 0.01). Therefore the information integrated from the localization of the epicardial breakthrough and the relative timing between the epicardial and the left ventricular endocardial breakthroughs can be used to estimate the depth of the site of origin of septal ventricular tachycardias. This study confirms that a three-dimensional view of the substratum of ventricular tachycardia can be derived from simultaneous epicardial and left ventricular endocardial mapping and can provide a superior basis for therapeutic interventions. (J THORAC CARDIOVASC SURG 1996;112:914-25)