Zhang Yipeng, Lu Qiujing, Monsoor Tonmoy, Hussain Shaun A, Qiao Joe X, Salamon Noriko, Fallah Aria, Sim Myung Shin, Asano Eishi, Sankar Raman, Staba Richard J, Engel Jerome, Speier William, Roychowdhury Vwani, Nariai Hiroki
Department of Electrical and Computer Engineering, University of California, Los Angeles, CA 90095, USA.
Division of Pediatric Neurology, Department of Pediatrics, UCLA Mattel Children's Hospital, David Geffen School of Medicine, Los Angeles, CA 90095, USA.
Brain Commun. 2021 Nov 3;4(1):fcab267. doi: 10.1093/braincomms/fcab267. eCollection 2022.
Intracranially recorded interictal high-frequency oscillations have been proposed as a promising spatial biomarker of the epileptogenic zone. However, its visual verification is time-consuming and exhibits poor inter-rater reliability. Furthermore, no method is currently available to distinguish high-frequency oscillations generated from the epileptogenic zone (epileptogenic high-frequency oscillations) from those generated from other areas (non-epileptogenic high-frequency oscillations). To address these issues, we constructed a deep learning-based algorithm using chronic intracranial EEG data via subdural grids from 19 children with medication-resistant neocortical epilepsy to: (i) replicate human expert annotation of artefacts and high-frequency oscillations with or without spikes, and (ii) discover epileptogenic high-frequency oscillations by designing a novel weakly supervised model. The 'purification power' of deep learning is then used to automatically relabel the high-frequency oscillations to distill epileptogenic high-frequency oscillations. Using 12 958 annotated high-frequency oscillation events from 19 patients, the model achieved 96.3% accuracy on artefact detection (F1 score = 96.8%) and 86.5% accuracy on classifying high-frequency oscillations with or without spikes (F1 score = 80.8%) using patient-wise cross-validation. Based on the algorithm trained from 84 602 high-frequency oscillation events from nine patients who achieved seizure-freedom after resection, the majority of such discovered epileptogenic high-frequency oscillations were found to be ones with spikes (78.6%, < 0.001). While the resection ratio of detected high-frequency oscillations (number of resected events/number of detected events) did not correlate significantly with post-operative seizure freedom (the area under the curve = 0.76, = 0.06), the resection ratio of epileptogenic high-frequency oscillations positively correlated with post-operative seizure freedom (the area under the curve = 0.87, = 0.01). We discovered that epileptogenic high-frequency oscillations had a higher signal intensity associated with ripple (80-250 Hz) and fast ripple (250-500 Hz) bands at the high-frequency oscillation onset and with a lower frequency band throughout the event time window (the inverted T-shaped), compared to non-epileptogenic high-frequency oscillations. We then designed perturbations on the input of the trained model for non-epileptogenic high-frequency oscillations to determine the model's decision-making logic. The model confidence significantly increased towards epileptogenic high-frequency oscillations by the artificial introduction of the inverted T-shaped signal template (mean probability increase: 0.285, < 0.001), and by the artificial insertion of spike-like signals into the time domain (mean probability increase: 0.452, < 0.001). With this deep learning-based framework, we reliably replicated high-frequency oscillation classification tasks by human experts. Using a reverse engineering technique, we distinguished epileptogenic high-frequency oscillations from others and identified its salient features that aligned with current knowledge.
颅内记录的发作间期高频振荡已被认为是癫痫源区一种很有前景的空间生物标志物。然而,其视觉验证耗时且评分者间可靠性较差。此外,目前尚无方法可区分癫痫源区产生的高频振荡(癫痫源性高频振荡)与其他区域产生的高频振荡(非癫痫源性高频振荡)。为解决这些问题,我们利用来自19例药物难治性新皮质癫痫患儿的硬膜下网格慢性颅内脑电图数据构建了一种基于深度学习的算法,以:(i)复制人类专家对伪迹以及有无棘波的高频振荡的标注,(ii)通过设计一种新型弱监督模型发现癫痫源性高频振荡。然后利用深度学习的“净化能力”自动重新标注高频振荡,以提取癫痫源性高频振荡。使用来自19例患者的12958个标注高频振荡事件,该模型在伪迹检测上的准确率达到96.3%(F1分数 = 96.8%),在对有无棘波的高频振荡进行分类时准确率达到86.5%(F1分数 = 80.8%),采用患者层面的交叉验证。基于从9例切除术后无发作患者的84602个高频振荡事件训练的算法,发现的此类癫痫源性高频振荡大多为有棘波的振荡(78.6%,<0.001)。虽然检测到的高频振荡的切除率(切除事件数/检测到的事件数)与术后无发作情况无显著相关性(曲线下面积 = 0.76, = 0.06),但癫痫源性高频振荡的切除率与术后无发作情况呈正相关(曲线下面积 = 0.87, = 0.01)。我们发现,与非癫痫源性高频振荡相比,癫痫源性高频振荡在高频振荡起始时与涟漪(80 - 250Hz)和快速涟漪(250 - 500Hz)频段的信号强度更高,且在整个事件时间窗内与较低频段相关(倒T形)。然后我们对训练模型的非癫痫源性高频振荡输入进行扰动,以确定模型的决策逻辑。通过人工引入倒T形信号模板(平均概率增加:0.285,<0.001)以及在时域人工插入棘波样信号(平均概率增加:0.452,<0.001),模型对癫痫源性高频振荡的置信度显著提高。借助这个基于深度学习的框架,我们可靠地复制了人类专家的高频振荡分类任务。通过逆向工程技术,我们区分了癫痫源性高频振荡与其他振荡,并确定了其与当前知识相符的显著特征。
