通过分解颅内脑电图和脑电波功率谱识别致痫异常

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Csaba Kozma , Gabrielle Schroeder , Tom Owen , Jane de Tisi , Andrew W. McEvoy , Anna Miserocchi , John Duncan , Yujiang Wang , Peter N. Taylor
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引用次数: 0

摘要

背景准确识别异常脑电图(EEG)活动是诊断和治疗癫痫的关键。最近的研究表明,将大脑活动分解为周期性(振荡)和非周期性(所有频率的趋势)成分可以阐明频谱活动变化的驱动因素。我们将该图谱与正在考虑接受神经外科手术的 63 名难治性局灶性癫痫患者进行了比较。标准图使用三种方法计算:(i) 相对完整频带功率,(ii) 去除非周期性成分后的相对频带功率,以及 (iii) 非周期性指数。每种方法都计算了患者队列中的异常情况。我们评估了空间轮廓,评估了它们定位异常的能力,并使用脑磁图(MEG)复制了这些发现。结果相对完整波段功率和相对周期波段功率的标准图显示出相似的空间轮廓,而非周期性标准图显示颞叶的指数值较高。通过完整波段功率估算出的异常能有效区分疗效好和疗效差的患者。与现有方法的比较和结论对同时存在周期性和非周期性活动异常的脑组织进行切除可能会导致手术效果不佳。孤立地看,周期和非周期性成分并不能提供足够的信息。相对完整波段功率解决方案被证明是最可靠的方法。未来的研究可以探讨大脑位置或病理如何影响周期性或非周期性异常。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Identifying epileptogenic abnormality by decomposing intracranial EEG and MEG power spectra

Background

Accurate identification of abnormal electroencephalographic (EEG) activity is pivotal for diagnosing and treating epilepsy. Recent studies indicate that decomposing brain activity into periodic (oscillatory) and aperiodic (trend across all frequencies) components can illuminate the drivers of spectral activity changes.

New methods

We analysed intracranial EEG (iEEG) data from 234 subjects, creating a normative map. This map was compared to a cohort of 63 patients with refractory focal epilepsy under consideration for neurosurgery. The normative map was computed using three approaches: (i) relative complete band power, (ii) relative band power with the aperiodic component removed, and (iii) the aperiodic exponent. Abnormalities were calculated for each approach in the patient cohort. We evaluated the spatial profiles, assessed their ability to localize abnormalities, and replicated the findings using magnetoencephalography (MEG).

Results

Normative maps of relative complete band power and relative periodic band power exhibited similar spatial profiles, while the aperiodic normative map revealed higher exponent values in the temporal lobe. Abnormalities estimated through complete band power effectively distinguished between good and bad outcome patients. Combining periodic and aperiodic abnormalities enhanced performance, like the complete band power approach.

Comparison with existing methods and conclusions

Sparing cerebral tissue with abnormalities in both periodic and aperiodic activity may result in poor surgical outcomes. Both periodic and aperiodic components do not carry sufficient information in isolation. The relative complete band power solution proved to be the most reliable method for this purpose. Future studies could investigate how cerebral location or pathology influences periodic or aperiodic abnormalities.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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