The feature of disc degeneration most closely associated with pain is a large fissure in the annulus fibrosus. Nerves and blood vessels are excluded from normal discs by high matrix stresses and by high proteoglycan (PG) content. However, they appear to grow into annulus fissures in surgically-removed degenerated discs. We hypothesize that anulus fissures provide a micro-environment that is mechanically and chemically conducive to the in-growth of nerves and blood vessels. 18 three-vertebra thoraco-lumbar spine specimens (T10/12 to L2/4) were obtained from 9 cadavers aged 68-92 yrs. All 36 discs were injected with Toluidine Blue so that leaking dye would indicate major fissures in the annulus. Specimens were then compressed at 1000 N while positioned in simulated flexed and extended postures, and the distribution of compressive stress within each disc was characterised by pulling a pressure transducer through it in various planes. After testing, discs were dissected and the morphology of fissures noted. Reductions in stress in the vicinity of fissures were compared with average pressure in the disc nucleus. Distributions of PGs and collagen were investigated in 16 surgically-removed discs by staining with Safranin O. Digital images were analysed in Matlab to obtain profiles of stain density in the vicinity of fissures.Introduction
Methods
We investigated the distribution of compressive ‘stress’ within cadaver intervertebral discs, using a pressure transducer mounted in a 1.3 mm diameter needle. The needle was pulled along the midsagittal diameter of a lumbar disc with the face of the transducer either vertical or horizontal while the disc was subjected to a constant compressive force. The resulting ‘stress profiles’ were analysed in order to characterise the distribution of vertical and horizontal compressive stress within each disc. A total of 87 discs from subjects aged between 16 and 87 years was examined. Our results showed that age-related degenerative changes reduced the diameter of the central hydrostatic region of each disc (the ‘functional nucleus’) by approximately 50%, and the pressure within this region fell by 30%. The width of the functional annulus increased by 80% and the height of compressive ‘stress peaks’ within it by 160%. The effects of age and degeneration were greater at L4/L5 than at L2/L3, and the posterior annulus was affected more than the anterior. Age and degeneration were themselves closely related, but the stage of degeneration had the greater effect on stress distributions. We suggest that structural changes within the annulus and endplate lead to a transfer of load from the nucleus to the posterior annulus. High ‘stress’ concentrations within the annulus may cause pain, and lead to further disruption.