Investigating the interplay between segregation and integration in developing cortical assemblies

IF 4.2 3区 医学 Q2 NEUROSCIENCES Frontiers in Cellular Neuroscience Pub Date : 2024-09-12 DOI:10.3389/fncel.2024.1429329
Valerio Barabino, Ilaria Donati della Lunga, Francesca Callegari, Letizia Cerutti, Fabio Poggio, Mariateresa Tedesco, Paolo Massobrio, Martina Brofiga
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Abstract

IntroductionThe human brain is an intricate structure composed of interconnected modular networks, whose organization is known to balance the principles of segregation and integration, enabling rapid information exchange and the generation of coherent brain states. Segregation involves the specialization of brain regions for specific tasks, while integration facilitates communication among these regions, allowing for efficient information flow. Several factors influence this balance, including maturation, aging, and the insurgence of neurological disorders like epilepsy, stroke, or cancer. To gain insights into information processing and connectivity recovery, we devised a controllable in vitro model to mimic and investigate the effects of different segregation and integration ratios over time.MethodsWe designed a cross-shaped polymeric mask to initially establish four independent sub-populations of cortical neurons and analyzed how the timing of its removal affected network development. We evaluated the morphological and functional features of the networks from 11 to 18 days in vitro (DIVs) with immunofluorescence techniques and micro-electrode arrays (MEAs).ResultsThe removal of the mask at different developmental stages of the network lead to strong variations in the degree of intercommunication among the four assemblies (altering the segregation/integration balance), impacting firing and bursting parameters. Early removal (after 5 DIVs) resulted in networks with a level of integration similar to homogeneous controls (without physical constraints). In contrast, late removal (after 15 DIVs) hindered the formation of strong inter-compartment connectivity, leading to more clustered and segregated assemblies.DiscussionA critical balance between segregation and integration was observed when the mask was removed at DIV 10, allowing for the formation of a strong connectivity among the still-separated compartments, thus demonstrating the existence of a time window in network development in which it is possible to achieve a balance between segregation and integration.
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研究发育中的大脑皮层集合体中分离与整合之间的相互作用
导言人脑是由相互连接的模块化网络组成的复杂结构,其组织结构兼顾了分离和整合的原则,能够快速交换信息并产生连贯的大脑状态。分隔是指大脑各区域针对特定任务的专门化,而整合则有利于这些区域之间的交流,从而实现高效的信息流。影响这种平衡的因素有很多,包括成熟、衰老以及癫痫、中风或癌症等神经系统疾病的突发。为了深入了解信息处理和连通性恢复,我们设计了一个可控体外模型来模拟和研究不同分离和整合比率随时间变化的影响。方法我们设计了一个十字形聚合掩膜,以初步建立四个独立的皮层神经元亚群,并分析了移除掩膜的时机对网络发育的影响。我们利用免疫荧光技术和微电极阵列(MEAs)评估了体外 11 到 18 天(DIVs)期间网络的形态和功能特征。结果在网络的不同发育阶段移除掩膜会导致四个集合体之间的互通程度发生强烈变化(改变分离/整合平衡),从而影响发射和爆发参数。早期移除(5 DIVs 后)导致网络的整合程度类似于同质对照组(无物理限制)。讨论 当在第 10 个 DIV 期移除掩码时,观察到了分离和整合之间的临界平衡,这使得仍然分离的区室之间形成了强大的连接,从而证明了在网络发育过程中存在一个时间窗口,在这个时间窗口内,分离和整合之间有可能实现平衡。
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来源期刊
CiteScore
7.90
自引率
3.80%
发文量
627
审稿时长
6-12 weeks
期刊介绍: Frontiers in Cellular Neuroscience is a leading journal in its field, publishing rigorously peer-reviewed research that advances our understanding of the cellular mechanisms underlying cell function in the nervous system across all species. Specialty Chief Editors Egidio D‘Angelo at the University of Pavia and Christian Hansel at the University of Chicago are supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
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