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Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue

Multiple finite-element (FE) models to predict the biomechanical responses in the human brain resulting from the interaction with blast waves have established the importance of including the brain-surface convolutions, the major cerebral veins, and using non-linear brain-tissue properties to improve...

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Autores principales: Subramaniam, Dhananjay Radhakrishnan, Unnikrishnan, Ginu, Sundaramurthy, Aravind, Rubio, Jose E., Kote, Vivek Bhaskar, Reifman, Jaques
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8599150/
https://www.ncbi.nlm.nih.gov/pubmed/34805106
http://dx.doi.org/10.3389/fbioe.2021.744808
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author Subramaniam, Dhananjay Radhakrishnan
Unnikrishnan, Ginu
Sundaramurthy, Aravind
Rubio, Jose E.
Kote, Vivek Bhaskar
Reifman, Jaques
author_facet Subramaniam, Dhananjay Radhakrishnan
Unnikrishnan, Ginu
Sundaramurthy, Aravind
Rubio, Jose E.
Kote, Vivek Bhaskar
Reifman, Jaques
author_sort Subramaniam, Dhananjay Radhakrishnan
collection PubMed
description Multiple finite-element (FE) models to predict the biomechanical responses in the human brain resulting from the interaction with blast waves have established the importance of including the brain-surface convolutions, the major cerebral veins, and using non-linear brain-tissue properties to improve model accuracy. We hypothesize that inclusion of a more detailed network of cerebral veins and arteries can further enhance the model-predicted biomechanical responses and help identify correlates of blast-induced brain injury. To more comprehensively capture the biomechanical responses of human brain tissues to blast-wave exposure, we coupled a three-dimensional (3-D) detailed-vasculature human-head FE model, previously validated for blunt impact, with a 3-D shock-tube FE model. Using the coupled model, we computed the biomechanical responses of a human head facing an incoming blast wave for blast overpressures (BOPs) equivalent to 68, 83, and 104 kPa. We validated our FE model, which includes the detailed network of cerebral veins and arteries, the gyri and the sulci, and hyper-viscoelastic brain-tissue properties, by comparing the model-predicted intracranial pressure (ICP) values with previously collected data from shock-tube experiments performed on cadaver heads. In addition, to quantify the influence of including a more comprehensive network of brain vessels, we compared the biomechanical responses of our detailed-vasculature model with those of a reduced-vasculature model and a no-vasculature model for the same blast-loading conditions. For the three BOPs, the predicted ICP values matched well with the experimental results in the frontal lobe, with peak-pressure differences of 4–11% and phase-shift differences of 9–13%. As expected, incorporating the detailed cerebral vasculature did not influence the ICP, however, it redistributed the peak brain-tissue strains by as much as 30% and yielded peak strain differences of up to 7%. When compared to existing reduced-vasculature FE models that only include the major cerebral veins, our high-fidelity model redistributed the brain-tissue strains in most of the brain, highlighting the importance of including a detailed cerebral vessel network in human-head FE models to more comprehensively account for the biomechanical responses induced by blast exposure.
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spelling pubmed-85991502021-11-19 Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue Subramaniam, Dhananjay Radhakrishnan Unnikrishnan, Ginu Sundaramurthy, Aravind Rubio, Jose E. Kote, Vivek Bhaskar Reifman, Jaques Front Bioeng Biotechnol Bioengineering and Biotechnology Multiple finite-element (FE) models to predict the biomechanical responses in the human brain resulting from the interaction with blast waves have established the importance of including the brain-surface convolutions, the major cerebral veins, and using non-linear brain-tissue properties to improve model accuracy. We hypothesize that inclusion of a more detailed network of cerebral veins and arteries can further enhance the model-predicted biomechanical responses and help identify correlates of blast-induced brain injury. To more comprehensively capture the biomechanical responses of human brain tissues to blast-wave exposure, we coupled a three-dimensional (3-D) detailed-vasculature human-head FE model, previously validated for blunt impact, with a 3-D shock-tube FE model. Using the coupled model, we computed the biomechanical responses of a human head facing an incoming blast wave for blast overpressures (BOPs) equivalent to 68, 83, and 104 kPa. We validated our FE model, which includes the detailed network of cerebral veins and arteries, the gyri and the sulci, and hyper-viscoelastic brain-tissue properties, by comparing the model-predicted intracranial pressure (ICP) values with previously collected data from shock-tube experiments performed on cadaver heads. In addition, to quantify the influence of including a more comprehensive network of brain vessels, we compared the biomechanical responses of our detailed-vasculature model with those of a reduced-vasculature model and a no-vasculature model for the same blast-loading conditions. For the three BOPs, the predicted ICP values matched well with the experimental results in the frontal lobe, with peak-pressure differences of 4–11% and phase-shift differences of 9–13%. As expected, incorporating the detailed cerebral vasculature did not influence the ICP, however, it redistributed the peak brain-tissue strains by as much as 30% and yielded peak strain differences of up to 7%. When compared to existing reduced-vasculature FE models that only include the major cerebral veins, our high-fidelity model redistributed the brain-tissue strains in most of the brain, highlighting the importance of including a detailed cerebral vessel network in human-head FE models to more comprehensively account for the biomechanical responses induced by blast exposure. Frontiers Media S.A. 2021-11-04 /pmc/articles/PMC8599150/ /pubmed/34805106 http://dx.doi.org/10.3389/fbioe.2021.744808 Text en Copyright © 2021 Subramaniam, Unnikrishnan, Sundaramurthy, Rubio, Kote and Reifman. https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Bioengineering and Biotechnology
Subramaniam, Dhananjay Radhakrishnan
Unnikrishnan, Ginu
Sundaramurthy, Aravind
Rubio, Jose E.
Kote, Vivek Bhaskar
Reifman, Jaques
Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title_full Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title_fullStr Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title_full_unstemmed Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title_short Cerebral Vasculature Influences Blast-Induced Biomechanical Responses of Human Brain Tissue
title_sort cerebral vasculature influences blast-induced biomechanical responses of human brain tissue
topic Bioengineering and Biotechnology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8599150/
https://www.ncbi.nlm.nih.gov/pubmed/34805106
http://dx.doi.org/10.3389/fbioe.2021.744808
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