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References | Muscles | Geometries | Constitutive laws | Simulation | Validation |
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Wang et al. [31] | Calf muscles | 1 healthy subject, 2D geometries from MRI data | Hyperelastic material (Mooney-Rivlin model) = 1310 Pa, = −961 Pa, = 886 Pa | Outside compression | In vivo MRI measurement (deformed geometries, cross-sectional area reduction) |
Wu et al. [26] | 20 facial muscles | 1 healthy subject, 3D geometries from MRI data | Hyperelastic material (Mooney-Rivlin model) = 2.5 kPa, = 1.175 kPa | Facial expressions | Skin deformation from the structured-light scanner |
Affagard et al. [29] | Ischios, quadriceps, gracilis, and sartorius | 1 healthy subject, 2D geometries from MRI data | Hyperelastic material (Neo-Hookean model) = [1.75–3.75] kPa, MPa−1 | Contention, compression, and indentation | Ultrasound displacement measurement |
Zöllner et al. [30] | Gastrocnemius | 1 healthy subject, 3D geometries from MRI data | Hyperelastic material (Neo-Hookean model) N/mm2 and N/mm2 | High heel posture | Qualitative comparison with literature |
Lee et al. [32] | Generic (back spine muscles) | 3 healthy subjects, 3D geometries from scanning | Hyperelastic material (Mooney-Rivlin model) = 1.65 kPa, = 3.35 kPa | Contact pressure simulation | Contact pressure measurements |
Wheatley et al. [34] | Biceps femoris | Ideal 3D cuboid form geometries | Visco-poroelastic material (FEBio) | Compression | In vitro permeability measurement |
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