ABSTRACT
Activity-dependent self-organization plays an important role in the formation of specific and stereotyped connectivity patterns in neural circuits. By combining neuronal cultures, tools with approaches from network neuroscience and information theory, we can study how complex network topology emerges from local neuronal interactions. We constructed effective connectivity networks using a transfer entropy analysis of electrophysiological signals recorded from rat embryo dissociated hippocampal neuron cultures between 6 and 35 days in vitro to investigate how the neuronal network topology evolves during maturation. The methodology for constructing the networks considered the synapse delay and addressed the influence of firing rate and population bursts as well as spurious effects on the inference of connections. We found that the number of links in the networks grew over the course of development, shifting from a segregated to a more integrated architecture. As part of this progression, three significant aspects of complex network topology emerged. In agreement with previous in silico and in vitro studies, a small-world architecture was detected, largely due to strong clustering among neurons. Additionally, the networks developed in a modular community topology, with most modules comprising nearby neurons. Finally, highly active neurons acquired topological characteristics that made them important nodes to the network and integrators of communities. These findings leverage new insights into how neuronal effective network topology relates to neuronal assembly self-organization mechanisms.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Competing interests: No competing interests declared
Data Availability: All data analyzed in this study is freely available on the Collaborative Research in Computational Neuroscience (CRCNS) data sharing initiative (http://crcns.org/data-sets/hc/hc-8, Nicholas M. Timme, Najja Marshall, Nicholas Bennett, Monica Ripp, Edward Lautzenhiser, and John M. Beggs (2016); Spontaneous spiking activity of thousands of neurons in rat hippocampal dissociated cultures) Previously Published Datasets: Spontaneous spiking activity of thousands of neurons in rat hippocampal dissociated cultures: Nicholas M. Timme, Najja Marshall, Nicholas Bennett, Monica Ripp, Edward Lautzenhiser, and John M. Beggs, 2016, http://dx.doi.org/10.6080/K0PC308P, CRCNS.org
Ethics: Human Subjects: No Animal Subjects: Yes Ethics Statement: All animal care and treatment were done in accordance with the guidelines from the National Institute of Health and all animal procedures were approved by the Indiana University Animal Care and Use Committee (Protocol: 11-041).
↵¶ Joint senior authors.