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Miscellaneous

Muscles

  • Modenese, 20201: Automated Generation of Three-Dimensional Complex Muscle Geometries for Use in Personalised Musculoskeletal Models

  • Kocur, 20192: Relationship between age, {BMI}, head posture and superficial neck muscle stiffness and elasticity in adult women

  • Herzog, 20193: The problem with skeletal muscle series elasticity

Zhai, 20194: Mechanical Response of Human Muscle at Intermediate Strain Rates

tensile stress–strain response of human muscle along fiber direction and compressive stress–strain response transverse to fiber direction at intermediate strain rates (100–102/s). An Ogden model with two material constants was adopted to describe the nonlinear tensile and compressive behaviors of human muscle.

Tamura 2019: Elastic tensile behavior of muscle fiber bundles in traumatic loading conditions

Neumann 2019: Regional variations of in vivo surface stiffness of soft tissue layer in extremities

Adipose Tissue

  • Naseri, 20205: The effect of adipose tissue material properties on the lap belt-pelvis interaction: A global sensitivity analysis

General Soft Tissues

  • Macron, 20206: Is a simplified Finite Element model of the gluteus region able to capture the mechanical response of the internal soft tissues under compression?

  • Fougeron, 20207: Combining Freehand Ultrasound-Based Indentation and Inverse Finite Element Modelling for the Identification of Hyperelastic Material Properties of Thigh Soft Tissues

  • Yamada, 20208: Ultrasound Imaging Characterization of Soft Tissue Dynamics of the Seated Human Body

  • Chen, 20199: Inverse finite element characterization of the human thigh soft tissue in the seated position

  • @Calvo-Gallego2019: Comparison of the viscoelastic properties of human abdominal and breast adipose tissue and its incidence on breast reconstruction surgery. A pilot study

  • @Grigoriadis2017: Material properties of the heel fat pad across strain rates

Cartilage

  • Shegaf, 202010: Cartilage Biomechanical Response Differs Under Physiological Biaxial Loads and Uniaxial Cyclic Compression

  1. Luca Modenese and Josef Kohout. Automated generation of three-dimensional complex muscle geometries for use in personalised musculoskeletal models. Annals of Biomedical Engineering, 486:1793–1804, mar 2020. doi:10.1007/s10439-020-02490-4

  2. Piotr Kocur, Maciej Tomczak, Marzena Wiernicka, Magdalena Goliwąs, Jacek Lewandowski, and Dawid Łochyński. Relationship between age, BMI, head posture and superficial neck muscle stiffness and elasticity in adult women. Scientific Reports, jun 2019. doi:10.1038/s41598-019-44837-5

  3. Walter Herzog. The problem with skeletal muscle series elasticity. BMC Biomedical Engineering, dec 2019. doi:10.1186/s42490-019-0031-y

  4. Xuedong Zhai, Eric A. Nauman, Yizhou Nie, Hangjie Liao, Roy J. Lycke, and Weinong W. Chen. Mechanical response of human muscle at intermediate strain rates. Journal of Biomechanical Engineering, mar 2019. doi:10.1115/1.4042900

  5. H. Naseri, J. Iraeus, and H. Johansson. The effect of adipose tissue material properties on the lap belt-pelvis interaction: a global sensitivity analysis. Journal of the Mechanical Behavior of Biomedical Materials, pages 103739, mar 2020. doi:10.1016/j.jmbbm.2020.103739

  6. Aurélien Macron, Hélène Pillet, Jennifer Doridam, Isabelle Rivals, Mohammad Javad Sadeghinia, Alexandre Verney, and Pierre-Yves Rohan. Is a simplified finite element model of the gluteus region able to capture the mechanical response of the internal soft tissues under compression? Clinical Biomechanics, 71:92–100, jan 2020. doi:10.1016/j.clinbiomech.2019.10.005

  7. Nolwenn Fougeron, Pierre-Yves Rohan, Diane Haering, Jean-Loïc Rose, Xavier Bonnet, and Hélène Pillet. Combining freehand ultrasound-based indentation and inverse finite element modelling for the identification of hyperelastic material properties of thigh soft tissues. Journal of Biomechanical Engineering, feb 2020. doi:10.1115/1.4046444

  8. Daisuke Yamada, Alperen Değirmenci, and Robert D. Howe. Ultrasound imaging characterization of soft tissue dynamics of the seated human body. Journal of Biomechanical Engineering, jan 2020. doi:10.1115/1.4045050

  9. Sheng Chen, Justin Scott, Tamara Reid Bush, and Sara Roccabianca. Inverse finite element characterization of the human thigh soft tissue in the seated position. Biomechanics and Modeling in Mechanobiology, 191:305–316, aug 2019. doi:10.1007/s10237-019-01212-7

  10. Ali Shegaf and Andrew Speirs. Cartilage biomechanical response differs under physiological biaxial loads and uniaxial cyclic compression. Journal of Biomechanical Engineering, feb 2020. doi:10.1115/1.4045661