Investigating cortical complexity and connectivity in rats with schizophrenia.

IF 2.5 4区医学 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Frontiers in Neuroinformatics Pub Date : 2024-08-15 eCollection Date: 2024-01-01 DOI:10.3389/fninf.2024.1392271

Zongya Zhao, Yifan Feng, Menghan Wang, Jiarong Wei, Tao Tan, Ruijiao Li, Heshun Hu, Mengke Wang, Peiqi Chen, Xudong Gao, Yinping Wei, Chang Wang, Zhixian Gao, Wenshuai Jiang, Xuezhi Zhou, Mingcai Li, Chong Wang, Ting Pang, Yi Yu

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Abstract

Background: The above studies indicate that the SCZ animal model has abnormal gamma oscillations and abnormal functional coupling ability of brain regions at the cortical level. However, few researchers have focused on the correlation between brain complexity and connectivity at the cortical level. In order to provide a more accurate representation of brain activity, we studied the complexity of electrocorticogram (ECoG) signals and the information interaction between brain regions in schizophrenic rats, and explored the correlation between brain complexity and connectivity.

Methods: We collected ECoG signal from SCZ rats. The frequency domain and time domain functional connectivity of SCZ rats were evaluated by magnitude square coherence and mutual information (MI). Permutation entropy (PE) and permutation Lempel-Ziv complexity (PLZC) were used to analyze the complexity of ECoG, and the relationship between them was evaluated. In addition, in order to further understand the causal structure of directional information flow among brain regions, we used phase transfer entropy (PTE) to analyze the effective connectivity of the brain.

Results: Firstly, in the high gamma band, the complexity of brain regions in SCZ rats is higher than that in normal rats, and the neuronal activity is irregularity. Secondly, the information integration ability of SCZ rats decreased and the communication of brain network information was hindered at the cortical level. Finally, compared with normal rats, the causal relationship between brain regions of SCZ rats was closer, but the information interaction center was not clear.

Conclusion: The above findings suggest that at the cortical level, complexity and connectivity are valid biomarkers for identifying SCZ. This bridges the gap between peak potentials and EEG. This may help to understand the pathophysiological mechanisms at the cortical level in schizophrenics.

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研究精神分裂症大鼠大脑皮层的复杂性和连通性。

研究背景上述研究表明，SCZ 动物模型的伽马振荡异常，大脑皮层水平的脑区功能耦合能力异常。然而，很少有研究人员关注大脑皮层的复杂性与连通性之间的相关性。为了更准确地表征大脑活动，我们研究了精神分裂症大鼠脑皮质图（ECoG）信号的复杂性和脑区之间的信息交互，并探讨了大脑复杂性与连通性之间的相关性：方法：我们采集了精神分裂症大鼠的心电图信号。方法：我们采集了精神分裂症大鼠的心电信号，通过幅度平方相干性和互信息（MI）评估了精神分裂症大鼠的频域和时域功能连通性。采用置换熵（PE）和置换 Lempel-Ziv 复杂性（PLZC）分析心电图的复杂性，并评估它们之间的关系。此外，为了进一步了解脑区之间定向信息流的因果结构，我们使用相位传递熵（PTE）来分析大脑的有效连通性：结果：首先，在高γ波段，SCZ大鼠脑区的复杂性高于正常大鼠，且神经元活动不规则。其次，SCZ 大鼠的信息整合能力下降，大脑皮层的网络信息交流受阻。最后，与正常大鼠相比，SCZ 大鼠脑区之间的因果关系更密切，但信息交互中心不明确：上述研究结果表明，在皮层水平上，复杂性和连通性是识别 SCZ 的有效生物标志物。这弥补了峰值电位和脑电图之间的差距。这可能有助于理解精神分裂症患者大脑皮层的病理生理机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Neuroinformatics MATHEMATICAL & COMPUTATIONAL BIOLOGY-NEUROSCIENCES

CiteScore

4.80

自引率

5.70%

发文量

132

审稿时长

14 weeks

期刊介绍： Frontiers in Neuroinformatics publishes rigorously peer-reviewed research on the development and implementation of numerical/computational models and analytical tools used to share, integrate and analyze experimental data and advance theories of the nervous system functions. Specialty Chief Editors Jan G. Bjaalie at the University of Oslo and Sean L. Hill at the École Polytechnique Fédérale de Lausanne are supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics and the public worldwide. Neuroscience is being propelled into the information age as the volume of information explodes, demanding organization and synthesis. Novel synthesis approaches are opening up a new dimension for the exploration of the components of brain elements and systems and the vast number of variables that underlie their functions. Neural data is highly heterogeneous with complex inter-relations across multiple levels, driving the need for innovative organizing and synthesizing approaches from genes to cognition, and covering a range of species and disease states. Frontiers in Neuroinformatics therefore welcomes submissions on existing neuroscience databases, development of data and knowledge bases for all levels of neuroscience, applications and technologies that can facilitate data sharing (interoperability, formats, terminologies, and ontologies), and novel tools for data acquisition, analyses, visualization, and dissemination of nervous system data. Our journal welcomes submissions on new tools (software and hardware) that support brain modeling, and the merging of neuroscience databases with brain models used for simulation and visualization.