Scott R. Lucas scite author profile

The experiment demonstrated that the viscoelastic mechanical response of the porcine ligament is dependent on the temperature at which it is tested; the force response of the ligament increased as the temperature decreased. This conclusion also applies to human ligaments owing to material and structural similarity. This result settles a controversy on the temperature dependence of ligament in the available literature. The ligament viscoelastic model shows a significant temperature dependence on the material properties; instantaneous elastic force was clearly temperature dependent while the relaxation response was only weakly temperature dependent. This result suggests that temperature dependence should be considered when testing ligaments and developing material models for in vivo force response, and further suggests that previously published material property values derived from room temperature testing may not adequately represent in vivo response. These findings have clinical relevance in the increased susceptibility of ligamentous injury in the cold and in assessing the mechanical behavior of cold extremities and extremities with limited vascular perfusion such as those of the elderly.

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Failure Properties of Cervical Spinal Ligaments Under Fast Strain Rate Deformations

Bass¹,

Lucas²,

Salzar³

et al. 2007

Spine

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Once the injury mechanisms of the cervical spine are fully understood, computational models can be employed to understand the potentially traumatic effects of clinical procedures, and mitigate injury in impact, falls, and other high-rate scenarios. The soft tissue failure properties in this study can be used to develop failure tolerances in fast-rate loading scenarios. Failure properties of the anterior and posterior longitudinal ligaments were similar, and the same properties can be used to model both ligaments.

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Viscoelastic and failure properties of spine ligament collagen fascicles

Lucas

Bass

Crandall

et al. 2009

Biomech Model Mechanobiol

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The microstructural volume fractions, orientations, and interactions among components vary widely for different ligament types. If these variations are understood, however, it is conceivable to develop a general ligament model that is based on microstructural properties. This paper presents a part of a much larger effort needed to develop such a model. Viscoelastic and failure properties of porcine posterior longitudinal ligament (PLL) collagen fascicles were determined. A series of subfailure and failure tests were performed at fast and slow strain rates on isolated collagen fascicles from porcine lumbar spine PLLs. A finite strain quasi-linear viscoelastic model was used to fit the fascicle experimental data. There was a significant strain rate effect in fascicle failure strain (P < 0.05), but not in failure force or failure stress. The corresponding average fast-rate and slow-rate failure strains were 0.098 ± 0.062 and 0.209 ± 0.081. The average failure force for combined fast and slow rates was 2.25 ± 1.17 N. The viscoelastic and failure properties in this paper were used to develop a microstructural ligament failure model that will be published in a subsequent paper.

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Injury Risk in Behind Armor Blunt Thoracic Trauma

Bass

Salzar

Lucas

et al. 2006

International Journal of Occupational Safety and Ergonomics

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Scott R. Lucas

Viscoelastic properties of the cervical spinal ligaments under fast strain-rate deformations

The Temperature-Dependent Viscoelasticity of Porcine Lumbar Spine Ligaments

Failure Properties of Cervical Spinal Ligaments Under Fast Strain Rate Deformations

Viscoelastic and failure properties of spine ligament collagen fascicles

Injury Risk in Behind Armor Blunt Thoracic Trauma

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