Bram Hunt, Eugene Kwan, Tolga Tasdizen, Jake Bergquist, Matthias Lange, Benjamin Orkild, Robert S MacLeod, Derek J Dosdall, Ravi Ranjan
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引用次数: 0
摘要
"驱动因素 "是持续性心房颤动的理论机制。机器学习算法已被用于识别驱动因素,但目前驱动因素数据集的规模较小,限制了其性能。我们假设,在未标记电图的大型数据集上进行无监督学习的预训练,将提高分类器在较小驱动程序数据集上的准确性。在这项研究中,我们使用了基于 SimCLR 的框架,在 113K 个未标记的 64 电极测量数据集上对残差神经网络进行了预训练,结果发现加权测试准确率比未预训练的网络有所提高(78.6±3.9% vs 71.9±3.3%)。这为开发卓越的驱动器检测算法奠定了基础,并支持将迁移学习用于其他心内膜电图数据集。
Transfer Learning for Improved Classification of Drivers in Atrial Fibrillation.
"Drivers" are theorized mechanisms for persistent atrial fibrillation. Machine learning algorithms have been used to identify drivers, but the small size of current driver datasets limits their performance. We hypothesized that pretraining with unsupervised learning on a large dataset of unlabeled electrograms would improve classifier accuracy on a smaller driver dataset. In this study, we used a SimCLR-based framework to pretrain a residual neural network on a dataset of 113K unlabeled 64-electrode measurements and found weighted testing accuracy to improve over a non-pretrained network (78.6±3.9% vs 71.9±3.3%). This lays ground for development of superior driver detection algorithms and supports use of transfer learning for other datasets of endocardial electrograms.
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