Finite element analysis of cerebral contusion

Chung Sheng Chu; Mish Shyan Lin; Haw Ming Huang; Maw Chang Lee

doi:10.1016/0021-9290(94)90208-9

Finite element analysis of cerebral contusion

Chung Sheng Chu, Mish Shyan Lin, Haw Ming Huang, Maw Chang Lee

Research output: Contribution to journal › Article › peer-review

82 Citations (Scopus)

Abstract

Finite element analysis was carried out to study the mechanism of cerebral contusion. Clinical findings indicate that most cerebral contusions in the absence of skull fracture occur at the frontal and temporal lobes. To explain these observations, cavitation and shear strain theories have long been advocated. Plane strain finite element models of a parasagittal section of the human head were developed in the present study. The model was first validated against a set of experimental results from the literature. Frontal and occipital impacts were then simulated, and pressure and shear stress distributions in the brain were compared. While comparable negative pressures always developed in the contrecoup regions, shear stress distributions remained nearly identical regardless of the impact direction, consistent with the clinically observed pattern for contusion. Therefore, shear strain theory appears to account better for the clinical findings in cerebral contusion.

Original language	English
Pages (from-to)	187-194
Number of pages	8
Journal	Journal of Biomechanics
Volume	27
Issue number	2
DOIs	https://doi.org/10.1016/0021-9290(94)90208-9
Publication status	Published - Feb 1994
Externally published	Yes

ASJC Scopus subject areas

Biophysics
Rehabilitation
Biomedical Engineering
Orthopedics and Sports Medicine

Access to Document

10.1016/0021-9290(94)90208-9

Cite this

@article{aeb981f264d2430a8538e13a4e441bea,

title = "Finite element analysis of cerebral contusion",

abstract = "Finite element analysis was carried out to study the mechanism of cerebral contusion. Clinical findings indicate that most cerebral contusions in the absence of skull fracture occur at the frontal and temporal lobes. To explain these observations, cavitation and shear strain theories have long been advocated. Plane strain finite element models of a parasagittal section of the human head were developed in the present study. The model was first validated against a set of experimental results from the literature. Frontal and occipital impacts were then simulated, and pressure and shear stress distributions in the brain were compared. While comparable negative pressures always developed in the contrecoup regions, shear stress distributions remained nearly identical regardless of the impact direction, consistent with the clinically observed pattern for contusion. Therefore, shear strain theory appears to account better for the clinical findings in cerebral contusion.",

author = "Chu, {Chung Sheng} and Lin, {Mish Shyan} and Huang, {Haw Ming} and Lee, {Maw Chang}",

year = "1994",

month = feb,

doi = "10.1016/0021-9290(94)90208-9",

language = "English",

volume = "27",

pages = "187--194",

journal = "Journal of Biomechanics",

issn = "0021-9290",

publisher = "Elsevier Ltd",

number = "2",

}

TY - JOUR

T1 - Finite element analysis of cerebral contusion

AU - Chu, Chung Sheng

AU - Lin, Mish Shyan

AU - Huang, Haw Ming

AU - Lee, Maw Chang

PY - 1994/2

Y1 - 1994/2

N2 - Finite element analysis was carried out to study the mechanism of cerebral contusion. Clinical findings indicate that most cerebral contusions in the absence of skull fracture occur at the frontal and temporal lobes. To explain these observations, cavitation and shear strain theories have long been advocated. Plane strain finite element models of a parasagittal section of the human head were developed in the present study. The model was first validated against a set of experimental results from the literature. Frontal and occipital impacts were then simulated, and pressure and shear stress distributions in the brain were compared. While comparable negative pressures always developed in the contrecoup regions, shear stress distributions remained nearly identical regardless of the impact direction, consistent with the clinically observed pattern for contusion. Therefore, shear strain theory appears to account better for the clinical findings in cerebral contusion.

AB - Finite element analysis was carried out to study the mechanism of cerebral contusion. Clinical findings indicate that most cerebral contusions in the absence of skull fracture occur at the frontal and temporal lobes. To explain these observations, cavitation and shear strain theories have long been advocated. Plane strain finite element models of a parasagittal section of the human head were developed in the present study. The model was first validated against a set of experimental results from the literature. Frontal and occipital impacts were then simulated, and pressure and shear stress distributions in the brain were compared. While comparable negative pressures always developed in the contrecoup regions, shear stress distributions remained nearly identical regardless of the impact direction, consistent with the clinically observed pattern for contusion. Therefore, shear strain theory appears to account better for the clinical findings in cerebral contusion.

UR - http://www.scopus.com/inward/record.url?scp=0028371136&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0028371136&partnerID=8YFLogxK

U2 - 10.1016/0021-9290(94)90208-9

DO - 10.1016/0021-9290(94)90208-9

M3 - Article

C2 - 8132687

AN - SCOPUS:0028371136

SN - 0021-9290

VL - 27

SP - 187

EP - 194

JO - Journal of Biomechanics

JF - Journal of Biomechanics

IS - 2

ER -

Finite element analysis of cerebral contusion

Abstract

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this