Quantitative proteomic profiling in brain subregions of mice exposed to open-field low-intensity blast reveals position-dependent blast effects

The neurological consequences of combat blast-induced neurotrauma (BINT) pose important clinical concerns for military service members and veterans. Previous studies have shown that low-intensity blast (LIB) results in BINT with multifaceted characteristics in mice exposed to open-field blast in pro...

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Bibliographic Details
Published in:Shock waves 2024, Vol.34 (4), p.381-398
Main Authors: Jackson, M., Chen, S., Liu, P., Langenderfer, M., Li, C., Siedhoff, H. R., Balderrama, A., Li, R., Johnson, C. E., Greenlief, C. M., Cernak, I., DePalma, R. G., Cui, J., Gu, Z.
Format: Article
Language:English
Subjects:
Acoustics
Brain damage
Cerebellum
Condensed Matter Physics
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Exposure
Fluid- and Aerodynamics
Heat and Mass Transfer
Injury analysis
Mice
Military personnel
Original Article
Position (location)
Prone position
Proteomics
Signatures
Thermodynamics
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Summary:The neurological consequences of combat blast-induced neurotrauma (BINT) pose important clinical concerns for military service members and veterans. Previous studies have shown that low-intensity blast (LIB) results in BINT with multifaceted characteristics in mice exposed to open-field blast in prone position. Although the prone position is natural for rodents, experimental models of blast using this position do not represent common scenarios of human standing while being exposed to blast during deployment or military training. In this study, we used our previously developed BINT mouse model of open-field LIB with mice in an upright position and then used quantitative proteomics and multiple bioinformatic approaches to analyze brain tissue taken from multiple subregions during the acute post-injury phase. We identified: (1) region-specific BINT-induced proteome changes, which were significantly and differently influenced by animal positioning (upright vs. prone): the upright positioning caused more significant protein alterations in cortex and cerebellum, which were less significant in striatum as compared to prone position; (2) synapse- and mitochondrion-related damage contributed to BINT in both positions; and (3) some molecular signatures were exclusively and/or oppositely regulated in two positions. This study delineates the molecular signatures of the position-dependent blast effects, indicating the importance of brain–body position for BINT translational studies and for modeling the location and extent of position-related blast injuries.
ISSN:0938-1287
1432-2153
DOI:10.1007/s00193-024-01169-2