静息状态神经振荡功率与特质焦虑之间的空间模式识别。

IF 4.5 3区 计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Carmen Vidaurre, Vadim V Nikulin, Maria Herrojo Ruiz
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引用次数: 3

摘要

焦虑影响着全世界约5-10%的成年人,给卫生系统带来了巨大负担。尽管焦虑无处不在,对身心健康都有影响,但大多数受焦虑影响的人没有得到适当的治疗。目前在精神病学领域的研究强调需要识别和验证与这种情况相关的生物标志物。神经生理学临床前研究是确定大脑节律的重要方法,可以作为焦虑关键特征的可靠标记。然而,尽管神经影像学研究一致认为前额叶皮层和皮层下结构(如杏仁核和海马)与焦虑有关,但对于导致这种情况的潜在神经生理过程仍缺乏共识。允许非侵入性记录和评估皮质处理的方法可能为帮助识别可作为干预目标的焦虑特征提供机会。在本研究中,我们将源功率调制(SPoC)应用于不同水平特质焦虑参与者的脑电图(EEG)记录。SPoC的发展是为了寻找空间滤波器和模式,其功率与个体参与者的外部变量相调节。获得的模式可以从神经生理学上解释。在这里,我们将SPoC的使用扩展到多受试者设置,并使用具有现实头部模型的模拟数据测试其有效性。接下来,我们将我们的SPoC框架应用于43名可获得特质焦虑评分的人类参与者的静息状态EEG。对窄频带数据的SPoC主体间分析显示,θ波段(4-7 Hz)的空间模式与焦虑呈负相关,具有神经生理学意义。结果是特定于θ波段,而不是在α(8-12赫兹)或β(13-30赫兹)频率范围内观察到的。θ波段空间模式主要定位于额上回。我们讨论了空间模式结果与寻找焦虑生物标志物及其在神经反馈研究中的应用的相关性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Identification of spatial patterns with maximum association between power of resting state neural oscillations and trait anxiety.

Identification of spatial patterns with maximum association between power of resting state neural oscillations and trait anxiety.

Identification of spatial patterns with maximum association between power of resting state neural oscillations and trait anxiety.

Identification of spatial patterns with maximum association between power of resting state neural oscillations and trait anxiety.

Anxiety affects approximately 5-10% of the adult population worldwide, placing a large burden on the health systems. Despite its omnipresence and impact on mental and physical health, most of the individuals affected by anxiety do not receive appropriate treatment. Current research in the field of psychiatry emphasizes the need to identify and validate biological markers relevant to this condition. Neurophysiological preclinical studies are a prominent approach to determine brain rhythms that can be reliable markers of key features of anxiety. However, while neuroimaging research consistently implicated prefrontal cortex and subcortical structures, such as amygdala and hippocampus, in anxiety, there is still a lack of consensus on the underlying neurophysiological processes contributing to this condition. Methods allowing non-invasive recording and assessment of cortical processing may provide an opportunity to help identify anxiety signatures that could be used as intervention targets. In this study, we apply Source-Power Comodulation (SPoC) to electroencephalography (EEG) recordings in a sample of participants with different levels of trait anxiety. SPoC was developed to find spatial filters and patterns whose power comodulates with an external variable in individual participants. The obtained patterns can be interpreted neurophysiologically. Here, we extend the use of SPoC to a multi-subject setting and test its validity using simulated data with a realistic head model. Next, we apply our SPoC framework to resting state EEG of 43 human participants for whom trait anxiety scores were available. SPoC inter-subject analysis of narrow frequency band data reveals neurophysiologically meaningful spatial patterns in the theta band (4-7 Hz) that are negatively correlated with anxiety. The outcome is specific to the theta band and not observed in the alpha (8-12 Hz) or beta (13-30 Hz) frequency range. The theta-band spatial pattern is primarily localised to the superior frontal gyrus. We discuss the relevance of our spatial pattern results for the search of biomarkers for anxiety and their application in neurofeedback studies.

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来源期刊
Neural Computing & Applications
Neural Computing & Applications 工程技术-计算机:人工智能
CiteScore
11.40
自引率
8.30%
发文量
1280
审稿时长
6.9 months
期刊介绍: Neural Computing & Applications is an international journal which publishes original research and other information in the field of practical applications of neural computing and related techniques such as genetic algorithms, fuzzy logic and neuro-fuzzy systems. All items relevant to building practical systems are within its scope, including but not limited to: -adaptive computing- algorithms- applicable neural networks theory- applied statistics- architectures- artificial intelligence- benchmarks- case histories of innovative applications- fuzzy logic- genetic algorithms- hardware implementations- hybrid intelligent systems- intelligent agents- intelligent control systems- intelligent diagnostics- intelligent forecasting- machine learning- neural networks- neuro-fuzzy systems- pattern recognition- performance measures- self-learning systems- software simulations- supervised and unsupervised learning methods- system engineering and integration. Featured contributions fall into several categories: Original Articles, Review Articles, Book Reviews and Announcements.
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