Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids

Blast exposure represents a common occupational risk capable of generating mild to severe traumatic brain injuries (TBI). During blast exposure, a pressure shockwave passes through the skull and exposes brain tissue to complex pressure waveforms. The primary neurophysiological response to blast-indu...

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Autores principales: Silvosa, Marc Joshua, Mercado, Nohemi Romo, Merlock, Nikolas, Vidhate, Suhas, Mejia-Alvarez, Ricardo, Yuan, Tony T., Willis, Adam M., Lybrand, Zane R.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Mary Ann Liebert, Inc., publishers 2022
Materias:
Original Articles
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9689772/
https://www.ncbi.nlm.nih.gov/pubmed/35765922
http://dx.doi.org/10.1089/neu.2022.0044
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author Silvosa, Marc Joshua
Mercado, Nohemi Romo
Merlock, Nikolas
Vidhate, Suhas
Mejia-Alvarez, Ricardo
Yuan, Tony T.
Willis, Adam M.
Lybrand, Zane R.
author_facet Silvosa, Marc Joshua
Mercado, Nohemi Romo
Merlock, Nikolas
Vidhate, Suhas
Mejia-Alvarez, Ricardo
Yuan, Tony T.
Willis, Adam M.
Lybrand, Zane R.
author_sort Silvosa, Marc Joshua
collection PubMed
description Blast exposure represents a common occupational risk capable of generating mild to severe traumatic brain injuries (TBI). During blast exposure, a pressure shockwave passes through the skull and exposes brain tissue to complex pressure waveforms. The primary neurophysiological response to blast-induced pressure waveforms remains poorly understood. Here, we use a computer-controlled table-top pressure chamber to expose human stem cell–derived cerebral organoids to varied frequency of pressure waves and characterize the neurophysiological response. Pressure waves that reach a maximum amplitude of 250 kPa were used to model a less severe TBI and 350 kPa for a more severe blast TBI event. With each amplitude, a frequency range of 500 Hz, 3000 Hz, and 5000 Hz was tested. Following the 250 kPa overpressure a multi-electrode array recorded organoid neural activity. We observed an acute suppression neuronal activity in single unit events, population events, and network oscillations that recovered within 24 h. Additionally, we observed a network desynchronization after exposure higher frequency waveforms. Conversely, organoids exposed to higher amplitude pressure (350k Pa) displayed drastic neurophysiological differences that failed to recover within 24 h. Further, lower amplitude “blast” (250 kPa) did not induce cellular damage whereas the higher amplitude “blast” (350 kPa) generated greater apoptosis throughout each organoid. Our data indicate that specific features of pressure waves found intracranially during blast TBI have varied effects on neurophysiological activity that can occur even without cellular damage.
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spelling pubmed-96897722022-11-30 Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids Silvosa, Marc Joshua Mercado, Nohemi Romo Merlock, Nikolas Vidhate, Suhas Mejia-Alvarez, Ricardo Yuan, Tony T. Willis, Adam M. Lybrand, Zane R. J Neurotrauma Original Articles Blast exposure represents a common occupational risk capable of generating mild to severe traumatic brain injuries (TBI). During blast exposure, a pressure shockwave passes through the skull and exposes brain tissue to complex pressure waveforms. The primary neurophysiological response to blast-induced pressure waveforms remains poorly understood. Here, we use a computer-controlled table-top pressure chamber to expose human stem cell–derived cerebral organoids to varied frequency of pressure waves and characterize the neurophysiological response. Pressure waves that reach a maximum amplitude of 250 kPa were used to model a less severe TBI and 350 kPa for a more severe blast TBI event. With each amplitude, a frequency range of 500 Hz, 3000 Hz, and 5000 Hz was tested. Following the 250 kPa overpressure a multi-electrode array recorded organoid neural activity. We observed an acute suppression neuronal activity in single unit events, population events, and network oscillations that recovered within 24 h. Additionally, we observed a network desynchronization after exposure higher frequency waveforms. Conversely, organoids exposed to higher amplitude pressure (350k Pa) displayed drastic neurophysiological differences that failed to recover within 24 h. Further, lower amplitude “blast” (250 kPa) did not induce cellular damage whereas the higher amplitude “blast” (350 kPa) generated greater apoptosis throughout each organoid. Our data indicate that specific features of pressure waves found intracranially during blast TBI have varied effects on neurophysiological activity that can occur even without cellular damage. Mary Ann Liebert, Inc., publishers 2022-11-01 2022-11-01 /pmc/articles/PMC9689772/ /pubmed/35765922 http://dx.doi.org/10.1089/neu.2022.0044 Text en © Marc Joshua Silvosa et al., 2022; Published by Mary Ann Liebert, Inc. https://creativecommons.org/licenses/by/4.0/This Open Access article is distributed under the terms of the Creative Commons License (CC-BY) (http://creativecommons.org/licenses/by/4.0 (https://creativecommons.org/licenses/by/4.0/) ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited.
spellingShingle Original Articles
Silvosa, Marc Joshua
Mercado, Nohemi Romo
Merlock, Nikolas
Vidhate, Suhas
Mejia-Alvarez, Ricardo
Yuan, Tony T.
Willis, Adam M.
Lybrand, Zane R.
Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title_full Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title_fullStr Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title_full_unstemmed Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title_short Understanding Primary Blast Injury: High Frequency Pressure Acutely Disrupts Neuronal Network Dynamics in Cerebral Organoids
title_sort understanding primary blast injury: high frequency pressure acutely disrupts neuronal network dynamics in cerebral organoids
topic Original Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9689772/
https://www.ncbi.nlm.nih.gov/pubmed/35765922
http://dx.doi.org/10.1089/neu.2022.0044
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