Department of Cardiovascular Diseases, Mayo Clinic Arizona, Phoenix, Arizona.
Department of Cardiovascular Diseases, Mayo Clinic Rochester, Rochester, Minnesota.
J Cardiovasc Electrophysiol. 2019 Sep;30(9):1679-1687. doi: 10.1111/jce.14079. Epub 2019 Aug 1.
Macroreentrant atrial tachycardias often occur following atrial fibrillation ablation, most commonly due to nontransmural lesions in prior ablation lines. Perimitral atrial flutter is one such arrhythmia which requires ablation of the mitral isthmus. Our objectives were to review the literature regarding ablation of the mitral isthmus and to provide our approach for assessment of mitral isthmus block.
We review anatomical considerations, ablation strategies, and assessment of conduction block across the mitral isthmus, which is subject to several pitfalls. Activation sequence and spatial differential pacing techniques are discussed for assessment of both endocardial and epicardial bidirectional mitral isthmus block.
Traditional methods for verifying mitral isthmus block include spatial differential pacing, activation mapping, and identification of double potentials. Up to 70% of cases require additional ablation in the coronary sinus (CS) to achieve transmural block. Interpretation of transmural block is subject to six pitfalls involving pacing output, differentiation of endocardial left atrial recordings from epicardial CS recordings, identification of a slowly conducting gap in the line, and catheter positioning during spatial differential pacing. Interpretation of unipolar electrograms can identify nontransmural lesions. We employ a combined epicardial and endocardial assessment of mitral isthmus block, which involves using a CS catheter for epicardial recording and a duodecapolar Halo catheter positioned around the mitral annulus for endocardial recording.
The assessment of transmural mitral isthmus block can be challenging. Placement of an endocardial mapping catheter around the mitral annulus can provide a precise assessment of conduction across the mitral isthmus.
心房颤动消融后常发生大折返性房性心动过速,最常见的原因是先前消融线中的非透壁性病变。心耳部房扑是一种需要消融二尖瓣峡部的心律失常。我们的目的是回顾关于消融二尖瓣峡部的文献,并提供我们评估二尖瓣峡部阻滞的方法。
我们回顾了二尖瓣峡部的解剖学考虑因素、消融策略和传导阻滞的评估,这涉及到几个陷阱。讨论了激活序列和空间差分起搏技术,用于评估心内膜和心外膜双向二尖瓣峡部阻滞。
传统的验证二尖瓣峡部阻滞的方法包括空间差分起搏、激活图和双电位的识别。多达 70%的病例需要在冠状窦(CS)中进行额外的消融以实现透壁阻滞。透壁阻滞的解释存在六个陷阱,涉及起搏输出、心内左心房记录与心外 CS 记录的区分、线路中缓慢传导间隙的识别以及空间差分起搏期间导管的定位。单极电图的解释可以识别非透壁性病变。我们采用心外膜和心内膜联合评估二尖瓣峡部阻滞,包括使用 CS 导管进行心外膜记录和在二尖瓣环周围放置 12 极 Halo 导管进行心内膜记录。
透壁性二尖瓣峡部阻滞的评估具有挑战性。在心内膜上放置一个二尖瓣环周围的标测导管可以对二尖瓣峡部的传导进行精确评估。