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    Simulation of Brain Response to Noncontact Impacts Using Coupled Eulerian–Lagrangian Method

    Source: Journal of Biomechanical Engineering:;2020:;volume( 142 ):;issue: 005
    Author:
    Na, Miao
    ,
    Beavers, Timothy J.
    ,
    Chandra, Abhijit
    ,
    Bentil, Sarah A.
    DOI: 10.1115/1.4045047
    Publisher: The American Society of Mechanical Engineers (ASME)
    Abstract: Finite element (FE) method has been widely used for gaining insights into the mechanical response of brain tissue during impacts. In this study, a coupled Eulerian−Lagrangian (CEL) formulation is implemented in impact simulations of a head system to overcome the mesh distortion difficulties due to large deformation in the cerebrospinal fluid (CSF) region and provide a biofidelic model of the interaction between the brain and skull. The head system used in our FE model is constructed from the transverse section of the human brain, with CSF modeled by Eulerian elements. Spring connectors are applied to represent the pia-arachnoid connection between the brain and skull. Validations of the CEL formulation and the FE model are performed using the experimental results. The dynamic response of brain tissue under noncontact impacts and the brain regions susceptible to injury are evaluated based on the intracranial pressure (ICP), maximum principal strain (MPS), and von Mises stress. While tracking the critical MPS location on the brain, higher likelihood of contrecoup injury than coup injury is found when sudden brain−skull motion takes place. The accumulation effect of CSF in the ventricle system, under large relative brain−skull motion, is also identified. The FE results show that adding relative angular velocities, to the translational impact model, not only causes a diffuse high strain area, but also cause the temporal lobes to be susceptible to cerebral contusions since the protecting CSF is prone to be squeezed away at the temporal sites due to the head rotations.
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      Simulation of Brain Response to Noncontact Impacts Using Coupled Eulerian–Lagrangian Method

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    contributor authorNa, Miao
    contributor authorBeavers, Timothy J.
    contributor authorChandra, Abhijit
    contributor authorBentil, Sarah A.
    date accessioned2022-02-04T14:48:38Z
    date available2022-02-04T14:48:38Z
    date copyright2020/01/20/
    date issued2020
    identifier issn0148-0731
    identifier otherbio_142_05_051011.pdf
    identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4274420
    description abstractFinite element (FE) method has been widely used for gaining insights into the mechanical response of brain tissue during impacts. In this study, a coupled Eulerian−Lagrangian (CEL) formulation is implemented in impact simulations of a head system to overcome the mesh distortion difficulties due to large deformation in the cerebrospinal fluid (CSF) region and provide a biofidelic model of the interaction between the brain and skull. The head system used in our FE model is constructed from the transverse section of the human brain, with CSF modeled by Eulerian elements. Spring connectors are applied to represent the pia-arachnoid connection between the brain and skull. Validations of the CEL formulation and the FE model are performed using the experimental results. The dynamic response of brain tissue under noncontact impacts and the brain regions susceptible to injury are evaluated based on the intracranial pressure (ICP), maximum principal strain (MPS), and von Mises stress. While tracking the critical MPS location on the brain, higher likelihood of contrecoup injury than coup injury is found when sudden brain−skull motion takes place. The accumulation effect of CSF in the ventricle system, under large relative brain−skull motion, is also identified. The FE results show that adding relative angular velocities, to the translational impact model, not only causes a diffuse high strain area, but also cause the temporal lobes to be susceptible to cerebral contusions since the protecting CSF is prone to be squeezed away at the temporal sites due to the head rotations.
    publisherThe American Society of Mechanical Engineers (ASME)
    titleSimulation of Brain Response to Noncontact Impacts Using Coupled Eulerian–Lagrangian Method
    typeJournal Paper
    journal volume142
    journal issue5
    journal titleJournal of Biomechanical Engineering
    identifier doi10.1115/1.4045047
    page51011
    treeJournal of Biomechanical Engineering:;2020:;volume( 142 ):;issue: 005
    contenttypeFulltext
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