Region-Dependent Mechanical Properties of Human Brain Tissue Under Large Deformations Using Inverse Finite Element Modeling

Basilio, A. V., Zeng, D., Pichay, L. A., Maas, S. A., Sundaresh, S. N., Finan, J. D., Elkin, B. S., McKhann, G. M., Ateshian, G. A., & Morrison, B. (2023). Region-Dependent Mechanical Properties of Human Brain Tissue Under Large Deformations Using Inverse Finite Element Modeling. Annals of Biomedical Engineering, 52(3), 600–610. https://doi.org/10.1007/s10439-023-03407-7
Authors:
Andrew V Basilio
Delin Zeng
Leanne A Pichay
Steve A Maas
Sowmya N Sundaresh
John D Finan
Benjamin S Elkin
Guy M McKhann
Gerard A Ateshian
Barclay Morrison
Affiliated Authors:
Andrew V Basilio
Delin Zeng
Leanne A Pichay
Sowmya N Sundaresh
John D Finan
Benjamin S Elkin
Guy M McKhann
Gerard A Ateshian
Barclay Morrison
Columbia Affiliation:
Subjects:
Brain (MeSH)
White Matter (MeSH)
Author Keywords:
biomechanics
constitutive model
indentation
quasilinear theory of viscoelasticity
elink
Publication Type:
Article
Unique ID:
10.1007/s10439-023-03407-7
PMID:
37993751
DOI:
10.1007/s10439-023-03407-7
Journal:
Annals of Biomedical Engineering
Publication Date:
Data Source:
PubMed
Source Link:
View PubMed Record
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