Rapid Prediction of Brain Injury Pattern in mTBI by Combining FE Analysis With a Machine-Learning Based Approach

Shim, Vickie; Holdsworth, Samantha J.; Champagne, Allen A.; Coverdale, Nicole S.; Cook, Douglas J.; Lee, Tae-Rin; Wang, Alan D.; Li, Shaofan; Fernandez, Justin

doi:10.1109/access.2020.3026350

Cited by 19 publications

(19 citation statements)

References 41 publications

(45 reference statements)

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“…We have developed a subject-specific FE model of the human brain using their MR images. 11,31 However, the material properties for this model came from the literature, limiting its subject-specificity to the geometry and white matter fiber tracts only. Therefore, the location-specific material properties obtained from our study along with the MRI scans taken both pre and post-impact are being used to create a completely subject-specific finite element model (both geometry and material propertywise), which will be the first fully subject-specific brain FE model.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, one of the aims of our overall study is to create a subject‐specific computational model of the sheep brain for mTBI. We have developed a subject‐specific FE model of the human brain using their MR images 11,31 . However, the material properties for this model came from the literature, limiting its subject‐specificity to the geometry and white matter fiber tracts only.…”

Section: Discussionmentioning

confidence: 99%

“…Some biomechanical studies on TBI injury mechanisms such as diffuse axonal injury suggest that brain material responses affect the pattern of white matter injuries 7,10 . In fact, we have developed such model and showed that the material properties obtained from MR images are critical in predicting brain damage patterns 11 . As such, it is vital to accurately characterize the relationship between head motion from the impact and the subsequent responses of the brain tissues in different regions of the brain.…”

Section: Introductionmentioning

confidence: 99%

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Analyzing the changes in the brain material properties after a mild traumatic brain injury—A pilot study

Kwon

Holdsworth

Guild

et al. 2020

Engineering Reports

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Traumatic brain injury (TBI) is a major health challenge, is very difficult to diagnose, and currently has no accepted treatment options. The difficulty in diagnosis is due to the complex pathophysiology of TBI, where the damage mechanisms span multiple spatial and temporal scales and ultimately manifest as diverse cognitive impairments in brain function. The speed and dynamic nature with which the mechanical insults occur in TBI means that computational models are the best candidate to mimic the in vivo event and to investigate the injury progression in detail. A current weakness in TBI computational models is the poor understanding of how material properties within different regions of the brain change after damage. Here, we developed an animal experiment pipeline where a controlled and reproducible mechanical insult can be applied to a sheep brain in vivo followed by ex vivo compression mechanical testing. For each brain, the compression mechanical testing was conducted across the length of the brain to assess baseline regional variations in material properties and how these properties changed after mechanical impact. Using this pipeline, we have characterized locational variations in the brain material properties both pre and post-TBI. Our preliminary results confirm that there exist locational variations in the brain material properties across all regions of cerebrum. The analysis of post-TBI tissues showed that compressive strength was reduced in the area nearest the direct impact.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Analyzing the changes in the brain material properties after a mild traumatic brain injury—A pilot study

Kwon

Holdsworth

Guild

et al. 2020

Engineering Reports

Self Cite

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“…One way of analysing regional migration is to create a computational model of the collective cell migration shape and measure the shape changes over time. In computational image analysis, shape changes can be quantified by measuring the amount of deformation between original undeformed and deformed states [25], which is often described as strain. This has advantages over other methods that measure quantitative shape features, such as area and length, because the strain-based method allows more detailed and region-specific analysis in the cell migration patterns.…”

Section: Introductionmentioning

confidence: 99%

“…One method that allows such analysis is Finite Element (FE) models, which have been used extensively in various bioengineering related problems such as joint biomechanics [26,27], tissue deformation [28] and injury prediction [25]. FE analysis has also been used on a microscale such as the work by Saeed and Weihs who simulated a 3D FE cell model and investigated the cell's morphology changes as it underwent uniformly applied compressions [29].…”

Section: Introductionmentioning

confidence: 99%

Robust Quantification of Regional Patterns of Migration in Three-Dimensional Cell Culture Models

Vong

Wang

Dragunow

et al. 2021

Preprint

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Wound healing assays is a common two-dimensional migration model, with the spheroid assay three-dimensional migration model recently emerging as being more representative of in vivo migration behaviours. These models provide insight to the overall migration of cells in response to various factors such as biological, chemotactic and molecular agents. However, currently available analysis techniques for these assays fall short on providing quantifiable means to measure regional migration patterns, , which is essential to allow more robust assessment of drug treatments on cell migration in a chemotactic fashion. Therefore, the aim of this study is to develop a finite element (FE) based pipeline that can objectively quantify regional migration patterns of cells. Here, we report that our FE based approach was able to accurately measure changes in overall migration areas compared to the standard ImageJ method. Furthermore, our regional migration analysis provided accurate and quantitative means to analyse the migration pattern seen in the phantom data and our experimental results, giving us confidence that it can be a robust tool for analysing cell migration patterns.

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Quantification of tumorsphere migration with a physics‐based machine learning method

et al. 2023

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Current analysis techniques available for migration assays only provide quantitative measurements for overall migration. However, the potential of regional migration analyses can open further insight into migration patterns and more avenues of experimentation with the same assays. Previously, we developed an analysis pipeline utilizing the finite element (FE) method to show its potential in analyzing glioblastoma (GBM) tumorsphere migration, especially in characterizing regional changes in the migration pattern. This study aims to streamline and further automate the analysis system by

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Rapid Prediction of Brain Injury Pattern in mTBI by Combining FE Analysis With a Machine-Learning Based Approach

Cited by 19 publications

References 41 publications

Analyzing the changes in the brain material properties after a mild traumatic brain injury—A pilot study

Analyzing the changes in the brain material properties after a mild traumatic brain injury—A pilot study

Robust Quantification of Regional Patterns of Migration in Three-Dimensional Cell Culture Models

Quantification of tumorsphere migration with a physics‐based machine learning method

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