Effect of static load on matrix synthesis rates in the intervertebral disc measured in vitro by a new perfusion technique

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Ohshima, Hiroshi¹; Urban, J. P. G.¹; Bergel, D. H.¹

Effect of static load on matrix synthesis rates in the intervertebral disc measured in vitro by a new perfusion technique

J Orthop Res. January 1995;13(1):22-29

©1995 Orthopaedic Research Society

Affiliations

¹University Laboratory of Physiology, Oxford University, Oxford, England
Abstract

The effect of static loading on matrix synthesis was measured in intact bovine coccygeal discs. The discs were maintained at 37°C in a humid atmosphere and were perfused across their upper and lower surfaces for as long as 8 hours with media containing radioisotopes (³H-proline and ³⁵S-sulphate) via porous filter disks embedded in Perspex (Plexiglas) holders. Static loads were applied to the disc with use of weights. The activity of free, nonincorporated isotope in the centre of the disc was monitored continuously with a microdialysis probe. Incorporated tracer in different regions of the disc was determined at the end of each experiment from the activity of the nondialysable tracer. Free tracer activity rose steeply over the first 3–4 hours of perfusion, as tracer diffused into the disc, and reached a steady value after 5–6 hours, as expected from diffusion theory. The rate of tracer incorporation estimated from the integrated value of free tracer concentration was constant for as long as 8 hours. Incorporation rates varied across the disc: the highest rates were in the inner layer of the annulus fibrosus, and the lowest rates were in the outer layer of the annulus. The rates for both ³⁵S-sulphate and ³H-proline varied with load. The rates were lowest in the nucleus pulposus and the inner layer of the annulus fibrosus with a 0.5 kg load, and they almost doubled as the load was increased to 5–10 kg. Heavier loads (15 kg) led to a decrease in incorporation. Hydration of the disc also varied with load; hydration decreased as load increased and was maintained near in vivo values with 5–10 kg of load (0.13–0.26 MN/m²). The effect of load on incorporation rates in the disc is compatible with the suggestion that rates are at a maximum at in vivo hydrations and decrease if the hydration decreases or if the disc swells.
Links

DOI: 10.1002/jor.1100130106

PubMed: 7853100

WoS: A1995QG26900005
History

Received: 1993-04-29

Accepted: 1994-01-14

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Cited By (25)

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1997	Ishihara H, Warensjo K, Roberts S, Urban JPG. Proteoglycan synthesis in the intervertebral disk nucleus: the role of extracellular osmolality. Am J Physiol Cell Physiol. May 1997;272(5):C1499-C1506.
1998	Errington RJ, Puustjarvi K, White IRF, Roberts S, Urban JPG. Characterisation of cytoplasm-filled processes in cells of the intervertebral disc. J Anat. April 1998;192(3):369-378.
2003	Baer AE, Laursen TA, Guilak F, Setton LA. The micromechanical environment of intervertebral disc cells determined by a finite deformation, anisotropic, and biphasic finite element model. J Biomech Eng. February 2003;125(1):1-11.
1996	Adams MA, McNally DS, Dolan P. “Stress” distributions inside intervertebral discs: the effects of age and degeneration. J Bone Joint Surg. November 1996;78B(6):965-972.
2003	Upton ML, Chen J, Guilak F, Setton LA. Differential effects of static and dynamic compression on meniscal cell gene expression. J Orthop Res. November 2003;21(6):963-969.
1997	Handa T, Ishihara H, Ohshima H, Osada R, Tsuji H, Obata K. Effects of hydrostatic pressure on matrix synthesis and matrix metalloproteinase production in the human lumbar intervertebral disc. Spine. May 15, 1997;22(10):1085-1091.
1998	Lotz JC, Colliou OK, Chin JR, Duncan NA, Liebenberg E. Compression-induced degeneration of the intervertebral disc: an in vivo mouse model and finite-element study. Spine. December 1, 1998;23(23):2493-2506.
1999	Iatridis JC, Mente PL, Stokes IAF, Aronsson DD, Alini M. Compression-induced changes in intervertebral disc properties in a rat tail model. Spine. May 15, 1999;24(10):996-1002.
1999	Guilak F, Ting-Beall HP, Baer AE, Trickey WR, Erickson GR, Setton LA. Viscoelastic properties of intervertebral disc cells: identification of two biomechanically distinct cell populations. Spine. December 1, 1999;24(23):2475-2483.
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