Finite Element Model of Human Skull Used for Head Injury Criteria Assessment

Jiroušek, Ondřej; Jìra, Josef; Jìrová, Jitka; Micka, Michal

doi:10.1007/1-4020-3796-1_47

Cited by 7 publications

(6 citation statements)

References 15 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Brain tissue is often modeled using a linear viscoelastic material formulation (Takhounts et al 2003; Kimpara et al 2006; Mao et al 2013; Zhang et al 2001a,b; Al-Bsharat et al 1999; Horgan and Gilchrist 2004; Jiroušek et al 2005). The shear relaxation behavior is described by:

G false(t false) = G_{\infty} + false(G_{0} - G_{\infty} false) * e^{- β t}

where G ∞ is the infinite shear modulus, G 0 is the initial shear modulus, and β is the decay constant.…”

Section: Methodsmentioning

confidence: 99%

Development and validation of an atlas-based finite element brain model

Miller

Urban

Stitzel

2016

Biomech Model Mechanobiol

View full text Add to dashboard Cite

Traumatic brain injury is a leading cause of disability and injury-related death. To enhance our ability to prevent such injuries, brain response can be studied using validated finite element (FE) models. In the current study, a high-resolution, anatomically accurate FE model was developed from the International Consortium for Brain Mapping brain atlas. Due to wide variation in published brain material parameters, optimal brain properties were identified using a technique called Latin hypercube sampling, which optimized material properties against three experimental cadaver tests to achieve ideal biomechanics. Additionally, falx pretension and thickness were varied in a lateral impact variation. The atlas-based brain model (ABM) was subjected to the boundary conditions from three high-rate experimental cadaver tests with different material parameter combinations. Local displacements, determined experimentally using neutral density targets, were compared to displacements predicted by the ABM at the same locations. Error between the observed and predicted displacements was quantified using CORrelation and Analysis (CORA), an objective signal rating method that evaluates the correlation of two curves. An average CORA score was computed for each variation and maximized to identify the optimal combination of parameters. The strongest relationships between CORA and material parameters were observed for the shear parameters. Using properties obtained through the described multiobjective optimization, the ABM was validated in three impact configurations and shows good agreement with experimental data. The final model developed in this study consists of optimized brain material properties and was validated in three cadaver impacts against local brain displacement data.

show abstract

G false(t false) = G_{\infty} + false(G_{0} - G_{\infty} false) * e^{- β t}

where G ∞ is the infinite shear modulus, G 0 is the initial shear modulus, and β is the decay constant.…”

Section: Methodsmentioning

confidence: 99%

Development and validation of an atlas-based finite element brain model

Miller

Urban

Stitzel

2016

Biomech Model Mechanobiol

View full text Add to dashboard Cite

show abstract

“…7 The material properties used in the model are given in Table 1. 2,16,31,33,42,44,51,52,57,58,61,68 brain loading and boundary conditions…”

Section: Materials Propertiesmentioning

confidence: 99%

“…16,33,44 The material properties of the rest of the compartments of the model (i.e., the falx cerebri and skull) are considered to be linear-elastic materials. Thus, the material properties (Young's modulus, density, and Poisson's ratio) of these compartments came from previous studies 2, 31,34,51,52,57,58,61 (Appendix Fig. 1).…”

Section: The Materials Properties and Derivation Of Field Equationsmentioning

confidence: 99%

Porohyperelastic anatomical models for hydrocephalus and idiopathic intracranial hypertension

Kim

Min

Park

et al. 2015

JNS

View full text Add to dashboard Cite

The model simulates all the clinical features in correlation with the MR images obtained in patients with hydrocephalus and IIH, thus providing support for the role of the transmantle pressure gradient and capillary CSF absorption in CSF-related brain deformation. The finite element methods can be used for a better understanding of the pathophysiological mechanisms of neurological disorders associated with parenchymal volumetric fluctuation.

show abstract

“…However, since the brain model is always saturated with incompressible fluid (Poisson's ratio = 0.5), the effective Poisson's ratio of the overall brain model combining solid and fluid elements becomes nearly 0.5, which makes it nearly incompressible material. E p = Young's modulus of the parenchyma (Dutta-Roy et al, 2008;Miller et al, 2005); v p = Poisson's ratio of the parenchyma A C C E P T E D M A N U S C R I P T (Kaczmarek et al, 1997a;Nagashima et al, 1987;Pena et al, 1999); k = permeability (Kaczmarek et al, 1997b); e = void ratio (Nagashima et al, 1987); p  = density of the parenchyma; E f = Young's modulus of the falx cerebri (Jiroušek et al, 2005;Takhounts, 2003); v f = Poisson's ratio of the falx cerebri (Jiroušek et al, 2005;Yoganandan, 1998); t = the thickness (Yoganandan, 1998); f  = density of the falx cerebri (Yoganandan, 1998); E s = Young's modulus of the skull (Jiroušek et al, 2005;Takhounts, 2003); v f = Poisson's ratio of the skull (Jiroušek et al, 2005;Yoganandan, 1998); s  = density of the skull (Yoganandan, 1998).…”

Section: Parenchymamentioning

confidence: 99%

Finite element analysis for normal pressure hydrocephalus: The effects of the integration of sulci

Kim

Park

et al. 2015

Medical Image Analysis

View full text Add to dashboard Cite

Finite element analysis (FEA) is increasingly used to investigate the brain under various pathological changes. Although FEA has been used to study hydrocephalus for decades, previous studies have primarily focused on ventriculomegaly. The present study aimed to investigate the pathologic changes regarding sulcal deformation in normal pressure hydrocephalus (NPH). Two finite element (FE) models-an anatomical brain geometric (ABG) model and the conventional simplified brain geometric (SBG) model-of NPH were constructed. The models were constructed with identical boundary conditions but with different geometries. The ABG model contained details of the sulci geometry, whereas these details were omitted from the SBG model. The resulting pathologic changes were assessed via four biomechanical parameters: pore pressure, von Mises stress, pressure, and void ratio. NPH was induced by increasing the transmantle pressure gradient (TPG) from 0 to a maximum of 2.0 mmHg. Both models successfully simulated the major features of NPH (i.e., ventriculomegaly and periventricular lucency). The changes in the biomechanical parameters with increasing TPG were similar between the models. However, the SBG model underestimated the degree of stress across the cerebral mantle by 150% compared with the ABG model. The SBG model also overestimates the degree of ventriculomegaly (increases of 194.5% and 154.1% at TPG = 2.0 mmHg for the SBG and ABG models, respectively). Including the sulci geometry in a FEA for NPH clearly affects the overall results. The conventional SBG model is inferior to the ABG model, which accurately simulated sulcal deformation and the consequent effects on cortical or subcortical structures. The inclusion of sulci in future FEA for the brain is strongly advised, especially for models used to investigate space-occupying lesions.

show abstract

Finite Element Model of Human Skull Used for Head Injury Criteria Assessment

Cited by 7 publications

References 15 publications

Development and validation of an atlas-based finite element brain model

Development and validation of an atlas-based finite element brain model

Porohyperelastic anatomical models for hydrocephalus and idiopathic intracranial hypertension

Finite element analysis for normal pressure hydrocephalus: The effects of the integration of sulci

Contact Info

Product

Resources

About