Roney Caroline H, Beach Marianne L, Mehta Arihant M, Sim Iain, Corrado Cesare, Bendikas Rokas, Solis-Lemus Jose A, Razeghi Orod, Whitaker John, O'Neill Louisa, Plank Gernot, Vigmond Edward, Williams Steven E, O'Neill Mark D, Niederer Steven A
School of Biomedical Engineering and Imaging Sciences, King's College London, London, United Kingdom.
Department of Biophysics, Medical University of Graz, Graz, Austria.
Front Physiol. 2020 Sep 16;11:1145. doi: 10.3389/fphys.2020.572874. eCollection 2020.
Catheter ablation therapy for persistent atrial fibrillation (AF) typically includes pulmonary vein isolation (PVI) and may include additional ablation lesions that target patient-specific anatomical, electrical, or structural features. Clinical centers employ different ablation strategies, which use imaging data together with electroanatomic mapping data, depending on data availability. The aim of this study was to compare ablation techniques across a virtual cohort of AF patients. We constructed 20 paroxysmal and 30 persistent AF patient-specific left atrial (LA) bilayer models incorporating fibrotic remodeling from late-gadolinium enhancement (LGE) MRI scans. AF was simulated and post-processed using phase mapping to determine electrical driver locations over 15 s. Six different ablation approaches were tested: (i) PVI alone, modeled as wide-area encirclement of the pulmonary veins; PVI together with: (ii) roof and inferior lines to model posterior wall box isolation; (iii) isolating the largest fibrotic area (identified by LGE-MRI); (iv) isolating all fibrotic areas; (v) isolating the largest driver hotspot region [identified as high simulated phase singularity (PS) density]; and (vi) isolating all driver hotspot regions. Ablation efficacy was assessed to predict optimal ablation therapies for individual patients. We subsequently trained a random forest classifier to predict ablation response using (a) imaging metrics alone, (b) imaging and electrical metrics, or (c) imaging, electrical, and ablation lesion metrics. The optimal ablation approach resulting in termination, or if not possible atrial tachycardia (AT), varied among the virtual patient cohort: (i) 20% PVI alone, (ii) 6% box ablation, (iii) 2% largest fibrosis area, (iv) 4% all fibrosis areas, (v) 2% largest driver hotspot, and (vi) 46% all driver hotspots. Around 20% of cases remained in AF for all ablation strategies. The addition of patient-specific and ablation pattern specific lesion metrics to the trained random forest classifier improved predictive capability from an accuracy of 0.73 to 0.83. The trained classifier results demonstrate that the surface areas of pre-ablation driver regions and of fibrotic tissue not isolated by the proposed ablation strategy are both important for predicting ablation outcome. Overall, our study demonstrates the need to select the optimal ablation strategy for each patient. It suggests that both patient-specific fibrosis properties and driver locations are important for planning ablation approaches, and the distribution of lesions is important for predicting an acute response.
持续性心房颤动(AF)的导管消融治疗通常包括肺静脉隔离(PVI),可能还包括针对患者特定解剖、电或结构特征的额外消融病灶。临床中心采用不同的消融策略,根据数据可用性,将成像数据与电解剖标测数据结合使用。本研究的目的是比较AF患者虚拟队列中的消融技术。我们构建了20个阵发性和30个持续性AF患者特异性左心房(LA)双层模型,纳入了延迟钆增强(LGE)MRI扫描的纤维化重塑。使用相位映射对AF进行模拟和后处理,以确定15秒内的电驱动位置。测试了六种不同的消融方法:(i)单独的PVI,建模为肺静脉的大面积环绕;PVI联合:(ii)顶部和下部线以模拟后壁盒状隔离;(iii)隔离最大纤维化区域(由LGE-MRI识别);(iv)隔离所有纤维化区域;(v)隔离最大驱动热点区域[识别为高模拟相位奇点(PS)密度];以及(vi)隔离所有驱动热点区域。评估消融疗效以预测个体患者的最佳消融治疗。随后,我们训练了一个随机森林分类器,使用(a)仅成像指标、(b)成像和电指标或(c)成像、电和消融病灶指标来预测消融反应。导致终止的最佳消融方法,或者如果不可能则为房性心动过速(AT),在虚拟患者队列中各不相同:(i)单独PVI占20%,(ii)盒状消融占6%,(iii)最大纤维化区域占2%,(iv)所有纤维化区域占4%,(v)最大驱动热点占2%,以及(vi)所有驱动热点占46%。对于所有消融策略,约20%的病例仍处于AF状态。在训练的随机森林分类器中添加患者特异性和消融模式特异性病灶指标,可将预测能力从0.73的准确率提高到0.83。训练后的分类器结果表明,消融前驱动区域的表面积以及未被提议的消融策略隔离的纤维化组织的表面积对于预测消融结果都很重要。总体而言,我们的研究表明需要为每个患者选择最佳消融策略。这表明患者特异性纤维化特性和驱动位置对于规划消融方法都很重要,并且病灶分布对于预测急性反应很重要。
