From Biomechanics to Pathology: Predicting Axonal Injury from Patterns of Strain After Traumatic Brain Injury

Overview

Journal Brain

Publisher Oxford University Press

Specialty Neurology

Date 2021 Jan 17

PMID 33454735

Citations 32

Authors

Cornelius K Donat

Maria Yanez Lopez

Magdalena Sastre

Nicoleta Baxan

Marc Goldfinger

Reneira Seeamber

Franziska Muller

Polly Davies

Peter Hellyer

Petros Siegkas

Steve Gentleman

David J Sharp

Mazdak Ghajari

Affiliations

Soon will be listed here.

Abstract

The relationship between biomechanical forces and neuropathology is key to understanding traumatic brain injury. White matter tracts are damaged by high shear forces during impact, resulting in axonal injury, a key determinant of long-term clinical outcomes. However, the relationship between biomechanical forces and patterns of white matter injuries, associated with persistent diffusion MRI abnormalities, is poorly understood. This limits the ability to predict the severity of head injuries and the design of appropriate protection. Our previously developed human finite element model of head injury predicted the location of post-traumatic neurodegeneration. A similar rat model now allows us to experimentally test whether strain patterns calculated by the model predicts in vivo MRI and histology changes. Using a controlled cortical impact, mild and moderate injuries (1 and 2 mm) were performed. Focal and axonal injuries were quantified with volumetric and diffusion 9.4 T MRI at 2 weeks post injury. Detailed analysis of the corpus callosum was conducted using multi-shell diffusion MRI and histopathology. Microglia and astrocyte density, including process parameters, along with white matter structural integrity and neurofilament expression were determined by quantitative immunohistochemistry. Linear mixed effects regression analyses for strain and strain rate with the employed outcome measures were used to ascertain how well immediate biomechanics could explain MRI and histology changes. The spatial pattern of mechanical strain and strain rate in the injured cortex shows good agreement with the probability maps of focal lesions derived from volumetric MRI. Diffusion metrics showed abnormalities in the corpus callosum, indicating white matter changes in the segments subjected to high strain, as predicted by the model. The same segments also exhibited a severity-dependent increase in glia cell density, white matter thinning and reduced neurofilament expression. Linear mixed effects regression analyses showed that mechanical strain and strain rate were significant predictors of in vivo MRI and histology changes. Specifically, strain and strain rate respectively explained 33% and 28% of the reduction in fractional anisotropy, 51% and 29% of the change in neurofilament expression and 51% and 30% of microglia density changes. The work provides evidence that strain and strain rate in the first milliseconds after injury are important factors in determining patterns of glial and axonal injury and serve as experimental validators of our computational model of traumatic brain injury. Our results provide support for the use of this model in understanding the relationship of biomechanics and neuropathology and can guide the development of head protection systems, such as airbags and helmets.

Citing Articles

Neurodegeneration in the cortical sulcus is a feature of chronic traumatic encephalopathy and associated with repetitive head impacts.

Nicks R, Shah A, Stathas S, Kirsch D, Horowitz S, Saltiel N Acta Neuropathol. 2024; 148(1):79.

PMID: 39643767 PMC: 11624223. DOI: 10.1007/s00401-024-02833-8.

EEG hyperexcitability and hyperconnectivity linked to GABAergic inhibitory interneuron loss following traumatic brain injury.

May H, Tsikonofilos K, Donat C, Sastre M, Kozlov A, Sharp D Brain Commun. 2024; 6(6):fcae385.

PMID: 39605970 PMC: 11600960. DOI: 10.1093/braincomms/fcae385.

Assessing Mild Traumatic Brain Injury-Associated Blood-Brain Barrier (BBB) Damage and Restoration Using Late-Phase Perfusion Analysis by 3D ASL MRI: Implications for Predicting Progressive Brain Injury in a Focused Review.

Joseph C Int J Mol Sci. 2024; 25(21).

PMID: 39519073 PMC: 11547134. DOI: 10.3390/ijms252111522.

An Objective Injury Threshold for the Maximum Principal Strain Criterion for Brain Tissue in the Finite Element Head Model and Its Application.

Zhang Y, Tang L, Liu Y, Yang B, Jiang Z, Liu Z Bioengineering (Basel). 2024; 11(9).

PMID: 39329660 PMC: 11429161. DOI: 10.3390/bioengineering11090918.

Repeated intrathecal injections of peripheral nerve-derived stem cell spheroids improve outcomes in a rat model of traumatic brain injury.

Shin H, Lee W, Park K, Yu Y, Kim G, Roh E Stem Cell Res Ther. 2024; 15(1):314.

PMID: 39300591 PMC: 11414269. DOI: 10.1186/s13287-024-03874-2.

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