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心房心肌病的结构和电生理决定因素揭示了阵发性和持续性心房颤动之间的重塑差异。

Structural and electrophysiological determinants of atrial cardiomyopathy identify remodeling discrepancies between paroxysmal and persistent atrial fibrillation.

作者信息

Huang Taiyuan, Nairn Deborah, Chen Juan, Mueller-Edenborn Bjoern, Pilia Nicolas, Mayer Louisa, Eichenlaub Martin, Moreno-Weidmann Zoraida, Allgeier Juergen, Trenk Dietmar, Ahlgrim Christoph, Westermann Dirk, Arentz Thomas, Loewe Axel, Jadidi Amir

机构信息

Arrhythmia Division, Department of Cardiology, Faculty of Medicine, University Heart Center Freiburg-Bad Krozingen, University of Freiburg, Freiburg im Breisgau, Germany.

Institute of Biomedical Engineering (IBT), Karlsruhe Institute of Technology (KIT), Karlsruhe, Germany.

出版信息

Front Cardiovasc Med. 2023 Jan 11;9:1101152. doi: 10.3389/fcvm.2022.1101152. eCollection 2022.

DOI:10.3389/fcvm.2022.1101152
PMID:36712269
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9874680/
Abstract

BACKGROUND

Progressive atrial fibrotic remodeling has been reported to be associated with atrial cardiomyopathy (ACM) and the transition from paroxysmal to persistent atrial fibrillation (AF). We sought to identify the anatomical/structural and electrophysiological factors involved in atrial remodeling that promote AF persistency.

METHODS

Consecutive patients with paroxysmal ( = 134) or persistent ( = 136) AF who presented for their first AF ablation procedure were included. Patients underwent left atrial (LA) high-definition mapping (1,835 ± 421 sites/map) during sinus rhythm (SR) and were randomized to training and validation sets for model development and evaluation. A total of 62 parameters from both electro-anatomical mapping and non-invasive baseline data were extracted encompassing four main categories: (1) LA size, (2) extent of low-voltage-substrate (LVS), (3) LA voltages and (4) bi-atrial conduction time as identified by the duration of amplified P-wave (APWD) in a digital 12-lead-ECG. Least absolute shrinkage and selection operator (LASSO) and logistic regression were performed to identify the factors that are most relevant to AF persistency in each category alone and all categories combined. The performance of the developed models for diagnosis of AF persistency was validated regarding discrimination, calibration and clinical usefulness. In addition, HATCH score and C2HEST score were also evaluated for their performance in identification of AF persistency.

RESULTS

In training and validation sets, APWD (threshold 151 ms), LA volume (LAV, threshold 94 mL), bipolar LVS area < 1.0 mV (threshold 4.55 cm) and LA global mean voltage (GMV, threshold 1.66 mV) were identified as best determinants for AF persistency in the respective category. Moreover, APWD (AUC 0.851 and 0.801) and LA volume (AUC 0.788 and 0.741) achieved better discrimination between AF types than LVS extent (AUC 0.783 and 0.682) and GMV (AUC 0.751 and 0.707). The integrated model (combining APWD and LAV) yielded the best discrimination performance between AF types (AUC 0.876 in training set and 0.830 in validation set). In contrast, HATCH score and C2HEST score only achieved AUC < 0.60 in identifying individuals with persistent AF in current study.

CONCLUSION

Among 62 electro-anatomical parameters, we identified APWD, LA volume, LVS extent, and mean LA voltage as the four determinant electrophysiological and structural factors that are most relevant for AF persistency. Notably, the combination of APWD with LA volume enabled discrimination between paroxysmal and persistent AF with high accuracy, emphasizing their importance as underlying substrate of persistent AF.

摘要

背景

据报道,进行性心房纤维化重塑与心房心肌病(ACM)以及阵发性房颤向持续性房颤的转变有关。我们试图确定参与心房重塑并促进房颤持续的解剖学/结构和电生理因素。

方法

纳入首次接受房颤消融手术的阵发性(n = 134)或持续性(n = 136)房颤连续患者。患者在窦性心律(SR)期间接受左心房(LA)高清标测(每张标测图1,835 ± 421个位点),并随机分为训练集和验证集用于模型开发和评估。从电解剖标测和无创基线数据中总共提取62个参数,涵盖四个主要类别:(1)左心房大小,(2)低电压基质(LVS)范围,(3)左心房电压,以及(4)通过数字12导联心电图中放大P波持续时间(APWD)确定的双房传导时间。进行最小绝对收缩和选择算子(LASSO)及逻辑回归分析,以单独确定每个类别以及所有类别组合中与房颤持续最相关的因素。对所开发的用于诊断房颤持续的模型在区分度、校准度和临床实用性方面进行验证。此外,还评估了HATCH评分和C2HEST评分在识别房颤持续方面的表现。

结果

在训练集和验证集中,APWD(阈值151毫秒)、左心房容积(LAV,阈值94毫升)、双极LVS面积< 1.0 mV(阈值4.55平方厘米)以及左心房整体平均电压(GMV,阈值1.66 mV)被确定为各自类别中房颤持续的最佳决定因素。此外,与LVS范围(AUC分别为0.783和0.682)和GMV(AUC分别为0.751和0.707)相比,APWD(AUC分别为0.851和0.801)和左心房容积(AUC分别为0.788和0.741)在区分房颤类型方面表现更好。综合模型(结合APWD和LAV)在区分房颤类型方面表现出最佳的区分性能(训练集中AUC为0.876,验证集中AUC为0.830)。相比之下,在本研究中,HATCH评分和C2HEST评分在识别持续性房颤个体时AUC均< 0.60。

结论

在62个电解剖参数中,我们确定APWD、左心房容积、LVS范围和左心房平均电压为与房颤持续最相关的四个决定性电生理和结构因素。值得注意的是,APWD与左心房容积的组合能够高精度地区分阵发性房颤和持续性房颤,强调了它们作为持续性房颤潜在基质的重要性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3523/9874680/b96a7a933dc1/fcvm-09-1101152-g009.jpg
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3
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