Characterizing neuronal networks activity and their dynamical changes due to endogenous and exogenous causes is a key issue of computational neuroscience and constitutes a fundamental contribution towards the development of innovative intervention strategies in case of brain damage. We address this challenge by making use of a multimodular system able to confine the growth of cells on substrate-embedded microelectrode arrays to investigate the interactions between networks of neurons. We observed their spontaneous and electrically induced network activity before and after a laser cut disconnecting one of the modules from all the others. We found that laser dissection induced de-synchronized activity among different modules during spontaneous activity, and prevented the propagation of evoked responses among modules during electrical stimulation. This reproducible experimental model constitutes a test-bed for the design and development of innovative computational tools for characterizing neural damage, and of novel neuro-prostheses aimed at restoring lost neuronal functionality between distinct brain areas.
A Multimodular System to Study the Impact of a Focal Lesion in Neuronal Cell Cultures / A. Averna, M. Care, S. Buccelli, M. Semprini, F. Difato, M. Chiappalone (LECTURE NOTES IN COMPUTER SCIENCE). - In: Hybrid Systems Biology[s.l] : Springer Verlag, 2019. - ISBN 9783030280413. - pp. 3-15 (( Intervento presentato al 6. convegno International Workshop HSB tenutosi a Prague nel 2019 [10.1007/978-3-030-28042-0_1].
A Multimodular System to Study the Impact of a Focal Lesion in Neuronal Cell Cultures
A. AvernaPrimo
;
2019
Abstract
Characterizing neuronal networks activity and their dynamical changes due to endogenous and exogenous causes is a key issue of computational neuroscience and constitutes a fundamental contribution towards the development of innovative intervention strategies in case of brain damage. We address this challenge by making use of a multimodular system able to confine the growth of cells on substrate-embedded microelectrode arrays to investigate the interactions between networks of neurons. We observed their spontaneous and electrically induced network activity before and after a laser cut disconnecting one of the modules from all the others. We found that laser dissection induced de-synchronized activity among different modules during spontaneous activity, and prevented the propagation of evoked responses among modules during electrical stimulation. This reproducible experimental model constitutes a test-bed for the design and development of innovative computational tools for characterizing neural damage, and of novel neuro-prostheses aimed at restoring lost neuronal functionality between distinct brain areas.
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