Nilsson Holguin

Type

Text

Type

Dissertation

Advisor

Clinton Rubin | Judex, Stefan | Hadjiargyrou, Michael | Dawn Elliott.

Date

2010-12-01

Keywords

Biomedical Engineering -- Biomechanics -- Aerospace Engineering | Degeneration, Microgravity, Spine

Department

Department of Biomedical Engineering

Language

en_US

Source

This work is sponsored by the Stony Brook University Graduate School in compliance with the requirements for completion of degree.

Identifier

http://hdl.handle.net/11401/72535

Publisher

The Graduate School, Stony Brook University: Stony Brook, NY.

Format

application/pdf

Abstract

Changes in intervertebral disc (IVD) biochemistry, morphology and mechanics have been characterized only incompletely in the rat hindlimb unloading (HU) model. Although exposure to chronic vibrations can be damaging, low-magnitude vibrations can attenuate the geometric changes of the IVD due to altered spinal loading. Here, we tested the hypothesis that low-magnitude, high-frequency vibrations will mitigate the hypotrophy, biochemical degradation and deconditioning of the IVD during HU. When applied as whole-body vibrations through all four paws, Sprague-Dawley rats were subjected to HU and exposed to daily periods (15min/d) of either ambulatory activities (HU+AMB) or whole body vibrations superimposed upon ambulation (HU+WBV; WBV at 45Hz, 0.3g). After 4wks and, compared to age-matched control rats (AC), the lumbar IVD of HU+AMB had a 22% smaller glycosaminoglycans/collagen ratio, 12% smaller posterior IVD height, and 13% smaller cross-sectional area. Compared to HU+AMB rats, the addition of low-level vibratory loading did not significantly alter IVD biochemistry, posterior height, area, or volume, but directionally altered IVD geometry. When subjected to upright vibrations through the hindpaws, rats were HU for 4wks. A subset of HU rats stood in an upright posture on a vertically oscillating plate (0.2g) at 45- or 90-Hz (HU+45 or HU+90). After 4wks, regardless of sham (HU+SC) loading (HUñSC) and, compared to AC, IVD of HUñSC had 10% less height, 39% smaller nucleus pulposus area, less glycosaminoglycans in the nucleus pulposus (21%), anterior annulus fibrosus (16%) and posterior annulus fibrosus (19%), 76% less tension-compression neutral zone (NZ) modulus, 26% greater compressive modulus, 25% greater initial elastic damping modulus, 26% less torsional NZ stiffness, no difference in collagen content and a weaker relationship between tension-compression NZ modulus and posterior height change. Exogenously introduced oscillations maintained the morphology, glycosaminoglycan content and axial elastic properties of IVD. Compared to HUñSC, the IVD of HU+90 had 8% larger average height, 35% greater nucleus pulposus area, more glycosaminoglycans in the nucleus pulposus (24%), anterior annulus fibrosus (17%) and posterior annulus fibrosus (19%), 339% greater tension-compression NZ modulus, 18% smaller compressive modulus, and maintained the relationship between tension-compression NZ modulus and posterior height change, but no difference in torsional NZ stiffness or initial elastic damping modulus. In summary, very brief, small mechanical signals partially protected the IVD during hindlimb unloading.

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