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引用本文的文献

1
Expert and deep learning model identification of iEEG seizures and seizure onset times.基于专家和深度学习模型的颅内脑电图癫痫发作及发作起始时间识别
Front Neurosci. 2023 Jul 5;17:1156838. doi: 10.3389/fnins.2023.1156838. eCollection 2023.
2
Responsive Neurostimulation for Seizure Control: Current Status and Future Directions.用于癫痫控制的反应性神经刺激:现状与未来方向。
Biomedicines. 2022 Oct 23;10(11):2677. doi: 10.3390/biomedicines10112677.

机器学习对慢性脑电描记术中的相对发作频率进行分类。

Machine Learning to Classify Relative Seizure Frequency From Chronic Electrocorticography.

机构信息

NYU Center for Data Science, New York, New York, U.S.A.

New York University Comprehensive Epilepsy Center, New York, New York, U.S.A.; and.

出版信息

J Clin Neurophysiol. 2023 Feb 1;40(2):151-159. doi: 10.1097/WNP.0000000000000858. Epub 2021 May 26.

DOI:10.1097/WNP.0000000000000858
PMID:34049367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8617083/
Abstract

PURPOSE

Brain responsive neurostimulation (NeuroPace) treats patients with refractory focal epilepsy and provides chronic electrocorticography (ECoG). We explored how machine learning algorithms applied to interictal ECoG could assess clinical response to changes in neurostimulation parameters.

METHODS

We identified five responsive neurostimulation patients each with ≥200 continuous days of stable medication and detection settings (median, 358 days per patient). For each patient, interictal ECoG segments for each month were labeled as "high" or "low" to represent relatively high or low long-episode (i.e., seizure) count compared with the median monthly long-episode count. Power from six conventional frequency bands from four responsive neurostimulation channels were extracted as features. For each patient, five machine learning algorithms were trained on 80% of ECoG, then tested on the remaining 20%. Classifiers were scored by the area-under-the-receiver-operating-characteristic curve. We explored how individual circadian cycles of seizure activity could inform classifier building.

RESULTS

Support vector machine or gradient boosting models achieved the best performance, ranging from 0.705 (fair) to 0.892 (excellent) across patients. High gamma power was the most important feature, tending to decrease during low-seizure-frequency epochs. For two subjects, training on ECoG recorded during the circadian ictal peak resulted in comparable model performance, despite less data used.

CONCLUSIONS

Machine learning analysis on retrospective background ECoG can classify relative seizure frequency for an individual patient. High gamma power was the most informative, whereas individual circadian patterns of seizure activity can guide model building. Machine learning classifiers built on interictal ECoG may guide stimulation programming.

摘要

目的

脑反应神经刺激(NeuroPace)治疗难治性局灶性癫痫,并提供慢性皮层电图(ECoG)。我们探讨了应用于间发性 ECoG 的机器学习算法如何评估对神经刺激参数变化的临床反应。

方法

我们确定了 5 名反应性神经刺激患者,每位患者均有≥200 天稳定的药物和检测设置(中位数,每位患者 358 天)。对于每位患者,每个月的间发性 ECoG 段被标记为“高”或“低”,以表示与中位数每月长发作(即癫痫发作)计数相比,相对较高或较低的长发作计数。从四个反应性神经刺激通道中的六个常规频带提取功率作为特征。对于每位患者,使用 80%的 ECoG 训练 5 种机器学习算法,然后在剩余的 20%上进行测试。使用受试者工作特征曲线下的面积对分类器进行评分。我们探讨了个体癫痫发作活动的昼夜周期如何为分类器构建提供信息。

结果

支持向量机或梯度提升模型的表现最佳,在患者之间的范围从 0.705(一般)到 0.892(优秀)。高伽马功率是最重要的特征,在低发作频率时期往往会降低。对于两名患者,尽管使用的数据较少,但在昼夜发作高峰期记录的 ECoG 上进行训练可导致类似的模型性能。

结论

对回顾性背景 ECoG 的机器学习分析可以对个体患者的相对癫痫发作频率进行分类。高伽马功率是最具信息量的,而个体癫痫发作活动的昼夜模式可以指导模型构建。基于间发性 ECoG 构建的机器学习分类器可能有助于刺激编程。