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This article reviews the attributes of the human surrogates most commonly used in injury biomechanics research. In particular, the merits of human cadavers, human volunteers, animals, dummies, and computational models are assessed relative to their ability to characterize the living human response and injury in an impact environment. Although data obtained from these surrogates have enabled biomechanical engineers and designers to develop effective injury countermeasures for occupants and pedestrians involved in crashes, the magnitude of the traffic safety problem necessitates expanded efforts in research and development. This article makes the case that while there are limitations and challenges associated with any particular surrogate, each provides a critical and necessary component in the continued quest to reduce crashrelated injuries and fatalities. Clin. Anat. 24:362-371, 2011. V V C 2011 Wiley-Liss, Inc.

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The Contribution of the Perichondrium to the Structural Mechanical Behavior of the Costal-Cartilage

Forman

Dios

Arregui‐Dalmases

et al. 2010

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The costal-cartilage in the human ribcage is a composite structure consisting of a cartilage substance surrounded by a fibrous, tendon-like perichondrium. Current computational models of the human ribcage represent the costal-cartilage as a homogeneous material, with no consideration for the mechanical contributions of the perichondrium. This study sought to investigate the role of the perichondrium in the structural mechanical behavior of the costal-cartilage. Twenty-two specimens of postmortem human costal-cartilage were subjected to cantilevered-like loading both with the perichondrium intact and with the perichondrium removed. The test method was chosen to approximate the cartilage loading that occurs when a concentrated, posteriorly directed load is applied to the midsternum. The removal of the perichondrium resulted in a statistically significant (two-tailed Student's t-test, p< or =0.05) decrease of approximately 47% (95% C.I. of 35-58%) in the peak anterior-posterior reaction forces generated during the tests. When tested with the perichondrium removed, the specimens also exhibited failure in the cartilage substance in the regions that experienced tension from bending. These results suggest that the perichondrium does contribute significantly to the stiffness and strength of the costal-cartilage structure under this type loading, and should be accounted for in computational models of the thorax and ribcage.

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Prediction of mechanical properties of human rib cortical bone using fractal dimension

Velázquez-Ameijide¹,

García-Vilana²,

Sánchez-Molina³

et al. 2020

Computer Methods in Biomechanics and Biomedical Engineering

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A large number of post mortem human subjects was used to investigate the relation between the micro-structure of rib cortical bone and the mechanical properties using Fractal Dimension. Uniaxial tensile tests were performed on coupons of rib cortical bone. Tensile strength, yield stress, Young's Modulus, maximum strain, and work to fracture were determined for each cou-pon. Fractal dimension was computed using CT images and Digital Image Correlation proce-dures. A highly significant effect of fractal dimension in the mechanical properties was found. In addition, the variation in mechanical properties was found to be adequately represented by Generalized Extreme Value type distributions.

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A stochastic model for soft tissue failure using acoustic emission data

Sánchez-Molina¹,

Martínez-González²,

Velázquez-Ameijide³

et al. 2015

Journal of the Mechanical Behavior of Biomedical Materials

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Indentation response of human patella with elastic modulus correlation to localized fractal dimension and bone mineral density

Kerrigan

Sánchez-Molina

Neggers

et al. 2014

Journal of the Mechanical Behavior of Biomedical Materials

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Mechanical Behavior of Blood Vessels: Elastic and Viscoelastic Contributions

Sánchez-Molina

García-Vilana

Llumà

et al. 2021

Biology

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The mechanical properties of the cerebral bridging veins (CBVs) were studied using advanced microtensile equipment. Detailed high-quality curves were obtained at different strain rates, showing a clearly nonlinear stress–strain response. In addition, the tissue of the CBVs exhibits stress relaxation and a preconditioning effect under cyclic loading, unequivocal indications of viscoelastic behavior. Interestingly, most previous literature that conducts uniaxial tensile tests had not found significant viscoelastic effects in CBVs, but the use of more sensitive tests allowed to observe the viscoelastic effects. For that reason, a careful mathematical analysis is presented, clarifying why in uniaxial tests with moderate strain rates, it is difficult to observe any viscoelastic effect. The analysis provides a theoretical explanation as to why many recent studies that investigated mechanical properties did not find a significant viscoelastic effect, even though in other circumstances, the CBV tissue would clearly exhibit viscoelastic behavior. Finally, this study provides reference values for the usual mechanical properties, as well as calculations of constitutive parameters for nonlinear elastic and viscoelastic models that would allow more accurate numerical simulation of CBVs in Finite Element-based computational models in future works.

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Whole-Body Response to Pure Lateral Impact

Lessley

Shaw

Parent

et al. 2010

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Carlos Arregui‐Dalmases

Fractal dimension and mechanical properties of human cortical bone

Human surrogates for injury biomechanics research

The Contribution of the Perichondrium to the Structural Mechanical Behavior of the Costal-Cartilage

Prediction of mechanical properties of human rib cortical bone using fractal dimension

A stochastic model for soft tissue failure using acoustic emission data

Indentation response of human patella with elastic modulus correlation to localized fractal dimension and bone mineral density

Mechanical Behavior of Blood Vessels: Elastic and Viscoelastic Contributions

Whole-Body Response to Pure Lateral Impact

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