Reverse Engineering of Feedforward Cortical-Hippocampal Microcircuits for Modelling Neural Network Function and Dysfunction

Overview

Journal Sci Rep

Specialty Science

Date 2024 Oct 30

PMID 39472479

Authors

Katrine Sjaastad Hanssen

Nicolai Winter-Hjelm

Salome Nora Niethammer

Asgeir Kobro-Flatmoen

Menno P Witter

Axel Sandvig

Ioanna Sandvig

Affiliations

Soon will be listed here.

Abstract

Engineered biological neural networks are indispensable models for investigation of neural function and dysfunction from the subcellular to the network level. Notably, advanced neuroengineering approaches are of significant interest for their potential to replicate the topological and functional organization of brain networks. In this study, we reverse engineered feedforward neural networks of primary cortical and hippocampal neurons, using a custom-designed multinodal microfluidic device with Tesla valve inspired microtunnels. By interfacing this device with nanoporous microelectrodes, we show that the reverse engineered multinodal neural networks exhibit capacity for both segregated and integrated functional activity, mimicking brain network dynamics. To advocate the broader applicability of our model system, we induced localized perturbations with amyloid beta to study the impact of pathology on network functionality. Additionally, we demonstrate long-term culturing of subregion- and layer specific neurons extracted from the entorhinal cortex and hippocampus of adult Alzheimer's-model mice and rats. Our results thus highlight the potential of our approach for reverse engineering of anatomically relevant multinodal neural networks to study dynamic structure-function relationships in both healthy and pathological conditions.

Citing Articles

Evolving alterations of structural organization and functional connectivity in feedforward neural networks after induced P301L tau mutation.

Weir J, Hanssen K, Winter-Hjelm N, Sandvig A, Sandvig I Eur J Neurosci. 2024; 60(12):7228-7248.

PMID: 39622242 PMC: 11647444. DOI: 10.1111/ejn.16625.

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