Literature DB >> 20199194

Finite element analysis of controlled cortical impact-induced cell loss.

Haojie Mao1, Xin Jin, Liying Zhang, King H Yang, Takuji Igarashi, Linda J Noble-Haeusslein, Albert I King.   

Abstract

The controlled cortical impact (CCI) model has been extensively used to study region-specific patterns of neuronal injury and cell death after a focal traumatic brain injury. Although external parameters such as impact velocity and depth of penetration have been defined in this injury model, little is known about the intracranial mechanical responses within cortical and subcortical brain regions where neuronal loss is prevalent. At present, one of the best methods to determine the internal responses of the brain is finite element (FE) modeling. A previously developed and biomechanically validated detailed three-dimensional FE rat brain model, consisting of 255,700 hexahedral elements and representing all essential anatomical features of a rat brain, was used to study intracranial responses in a series of CCI experiments in which injury severity ranged from mild to severe. A linear relationship was found between the percentage of the neuronal loss observed in vivo and the FE model-predicted maximum principal strain (R(2) = 0.602). Interestingly, the FE model also predicted some risk of injury in the cerebellum, located remote from the point of impact, with a 25% neuronal loss for the "severe" impact condition. More research is needed to examine other regions that do not have histological data for comparison with FE model predictions before this injury mechanism and the associated injury threshold can be fully established.

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Year:  2010        PMID: 20199194      PMCID: PMC2943943          DOI: 10.1089/neu.2008.0616

Source DB:  PubMed          Journal:  J Neurotrauma        ISSN: 0897-7151            Impact factor:   5.269


  30 in total

1.  Increased hippocampal CA3 vulnerability to low-level kainic acid following lateral fluid percussion injury.

Authors:  Elisa Roncati Zanier; Stefan M Lee; Paul M Vespa; Christopher C Giza; David A Hovda
Journal:  J Neurotrauma       Date:  2003-05       Impact factor: 5.269

2.  Brain tissue biomechanics in cortical contusion injury: a finite element analysis.

Authors:  A Peña; J D Pickard; D Stiller; N G Harris; M U Schuhmann
Journal:  Acta Neurochir Suppl       Date:  2005

3.  Regional distribution of fluoro-jade B staining in the hippocampus following traumatic brain injury.

Authors:  Kevin J Anderson; Kelly M Miller; Isabella Fugaccia; Stephen W Scheff
Journal:  Exp Neurol       Date:  2005-05       Impact factor: 5.330

4.  Computational studies of strain exposures in neonate and mature rat brains during closed head impact.

Authors:  Anna Levchakov; Eran Linder-Ganz; Ramesh Raghupathi; Susan S Margulies; Amit Gefen
Journal:  J Neurotrauma       Date:  2006-10       Impact factor: 5.269

5.  Protective effects of glial cell line-derived neurotrophic factor on hippocampal neurons after traumatic brain injury in rats.

Authors:  B T Kim; V L Rao; K A Sailor; K K Bowen; R J Dempsey
Journal:  J Neurosurg       Date:  2001-10       Impact factor: 5.115

6.  Severe controlled cortical impact in rats: assessment of cerebral edema, blood flow, and contusion volume.

Authors:  P M Kochanek; D W Marion; W Zhang; J K Schiding; M White; A M Palmer; R S Clark; M E O'Malley; S D Styren; C Ho
Journal:  J Neurotrauma       Date:  1995-12       Impact factor: 5.269

7.  Age-dependent changes in material properties of the brain and braincase of the rat.

Authors:  Amit Gefen; Nurit Gefen; Qiliang Zhu; Ramesh Raghupathi; Susan S Margulies
Journal:  J Neurotrauma       Date:  2003-11       Impact factor: 5.269

8.  In vivo imaging of rapid deformation and strain in an animal model of traumatic brain injury.

Authors:  Philip V Bayly; Erin E Black; Rachel C Pedersen; Elizabeth P Leister; Guy M Genin
Journal:  J Biomech       Date:  2006       Impact factor: 2.712

9.  Experimental brain injury induces regionally distinct apoptosis during the acute and delayed post-traumatic period.

Authors:  A C Conti; R Raghupathi; J Q Trojanowski; T K McIntosh
Journal:  J Neurosci       Date:  1998-08-01       Impact factor: 6.167

10.  Biomechanical response of the bovine pia-arachnoid complex to tensile loading at varying strain-rates.

Authors:  Xin Jin; Jong B Lee; Lai Yee Leung; Liying Zhang; King H Yang; Albert I King
Journal:  Stapp Car Crash J       Date:  2006-11
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  19 in total

1.  Untangling the Effect of Head Acceleration on Brain Responses to Blast Waves.

Authors:  Haojie Mao; Ginu Unnikrishnan; Vineet Rakesh; Jaques Reifman
Journal:  J Biomech Eng       Date:  2015-12       Impact factor: 2.097

Review 2.  Neuroimaging biomarkers in mild traumatic brain injury (mTBI).

Authors:  Erin D Bigler
Journal:  Neuropsychol Rev       Date:  2013-08-24       Impact factor: 7.444

3.  Why is CA3 more vulnerable than CA1 in experimental models of controlled cortical impact-induced brain injury?

Authors:  Haojie Mao; Benjamin S Elkin; Vinay V Genthikatti; Barclay Morrison; King H Yang
Journal:  J Neurotrauma       Date:  2013-08-03       Impact factor: 5.269

4.  Radiological-pathological correlation of diffusion tensor and magnetization transfer imaging in a closed head traumatic brain injury model.

Authors:  Tsang-Wei Tu; Rashida A Williams; Jacob D Lescher; Neekita Jikaria; L Christine Turtzo; Joseph A Frank
Journal:  Ann Neurol       Date:  2016-04-18       Impact factor: 10.422

5.  Rate of neurodegeneration in the mouse controlled cortical impact model is influenced by impactor tip shape: implications for mechanistic and therapeutic studies.

Authors:  Jennifer M Pleasant; Shaun W Carlson; Haojie Mao; Stephen W Scheff; King H Yang; Kathryn E Saatman
Journal:  J Neurotrauma       Date:  2011-04-21       Impact factor: 5.269

Review 6.  Biomechanical simulation of traumatic brain injury in the rat.

Authors:  John D Finan
Journal:  Clin Biomech (Bristol, Avon)       Date:  2018-01-31       Impact factor: 2.063

7.  Juvenile Traumatic Brain Injury Results in Cognitive Deficits Associated with Impaired Endoplasmic Reticulum Stress and Early Tauopathy.

Authors:  Michael J Hylin; Ryan C Holden; Aidan C Smith; Aric F Logsdon; Rabia Qaiser; Brandon P Lucke-Wold
Journal:  Dev Neurosci       Date:  2018-05-22       Impact factor: 2.984

8.  White matter tract-oriented deformation predicts traumatic axonal brain injury and reveals rotational direction-specific vulnerabilities.

Authors:  Sarah Sullivan; Stephanie A Eucker; David Gabrieli; Connor Bradfield; Brittany Coats; Matthew R Maltese; Jongho Lee; Colin Smith; Susan S Margulies
Journal:  Biomech Model Mechanobiol       Date:  2014-12-30

9.  Dietary Docosahexaenoic Acid Improves Cognitive Function, Tissue Sparing, and Magnetic Resonance Imaging Indices of Edema and White Matter Injury in the Immature Rat after Traumatic Brain Injury.

Authors:  Michelle E Schober; Daniela F Requena; Osama M Abdullah; T Charles Casper; Joanna Beachy; Daniel Malleske; James R Pauly
Journal:  J Neurotrauma       Date:  2015-08-06       Impact factor: 5.269

10.  Multiscale modelling of cerebrovascular injury reveals the role of vascular anatomy and parenchymal shear stresses.

Authors:  Siamak Farajzadeh Khosroshahi; Xianzhen Yin; Cornelius K Donat; Aisling McGarry; Maria Yanez Lopez; Nicoleta Baxan; David J Sharp; Magdalena Sastre; Mazdak Ghajari
Journal:  Sci Rep       Date:  2021-06-21       Impact factor: 4.379
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