Mark Weidenbaum scite author profile

The observed variations in tensile behavior of multiple-layer anulus samples indicate that larger variations in tensile modulus and failure properties occur with radial position in the disc than from anterior to posterolateral regions. This pattern is likely related to site-specific variations in the tensile properties of the single-layer samples of anulus fibrosus lamellae and the organization of successive lamellae and their interactions. The results of the present study suggest that factors other than age, such as compositional and structural variations in the disc, are the most important determinants of tensile behavior of the anulus fibrosus.

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Degeneration affects the anisotropic and nonlinear behaviors of human anulus fibrosus in compression

Iatridis

Setton

Foster

et al. 1998

Journal of Biomechanics

290

220

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Alterations in the mechanical behavior of the human lumbar nucleus pulposus with degeneration and aging

Iatridis

Setton

Weidenbaum

et al. 1997

Journal Orthopaedic Research

245

205

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This study tested the hypothesis that changes in the morphology and composition of the nucleus pulposus with age and degeneration have associated changes in its mechanical properties. A torsional shear experiment was used to determine viscoelastic shear properties of cylindrical samples of human nucleus pulposus with large ranges of grades of morphological degeneration (normal to severely degenerated) and ages (range: 16-88 years; average: 57 +/- 21.5 years). Viscoelastic shear properties were determined from stress-relaxation and dynamic sinusoidal tests. A linear viscoelastic law with a variable-amplitude relaxation spectrum was used to model experimental behaviors of nucleus pulposus specimens. A statistically significant increase in the instantaneous and dynamic shear moduli was found with increasing age and grade of degeneration; the values for moduli ranged from 5.0 to 60 kPa. A significant decrease in tan delta was also detected; the values ranged from 0.43 to 0.33, indicating a decreased capacity for the nucleus pulposus to dissipate energy. The dynamic modulus and tan delta were also significantly affected by frequency. It was generally concluded that the nucleus pulposus undergoes a transition from "fluid-like" behavior to more "solid-like" behavior with aging and degeneration.

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Regional Variation in Tensile Properties and Biochemical Composition of the Human Lumbar Anulus Fibrosus

Skaggs

Weidenbaum²,

Latridis³

et al. 1994

Spine

310

186

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Is the Nucleus Pulposus a Solid or a Fluid? Mechanical Behaviors of the Nucleus Pulposus of the Human Intervertebral Disc

Iatridis

Weidenbaum

Setton

et al. 1996

Spine

315

196

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Mark Weidenbaum

Tensile Properties of Nondegenerate Human Lumbar Anulus Fibrosus

Degeneration affects the anisotropic and nonlinear behaviors of human anulus fibrosus in compression

Alterations in the mechanical behavior of the human lumbar nucleus pulposus with degeneration and aging

Regional Variation in Tensile Properties and Biochemical Composition of the Human Lumbar Anulus Fibrosus

Is the Nucleus Pulposus a Solid or a Fluid? Mechanical Behaviors of the Nucleus Pulposus of the Human Intervertebral Disc

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