Effects of aging and degeneration on the human intervertebral disc during the diurnal cycle: A finite element study

A significant biochemical change that takes place in intervertebral disc degeneration is the loss of proteoglycans in the nucleus pulposus. Proteoglycans attract fluid, which works to reduce mechanical stresses in the solid matrix of the nucleus and provide a hydrostatic pressure to the annulus fibrosus, whose fibrous nature accommodates this stress. Our goals are to develop an osmo‐poroelastic finite element model to study the relationship between proteoglycan content and the stress distribution within the disc and to analyze the effects of degeneration on the disc's diurnal mechanical response. Stress in the annulus increased with degeneration from ～0.2 to 0.4 MPa, and an increase occurred in the center of the nucleus from 1.2 to 1.6 MPa. The osmotic pressure in the central nucleus region decreased the most with degeneration, from ～0.42 to ～0.1 MPa in a severely dehydrated disc. A 3% decrease in diurnal fluid lost with degeneration equated to ～21% decrease in fluid exchange, and hence a decrease in nutrients that require convection to enter the disc. We quantified the increases in internal stresses in the nucleus and annulus throughout the various stages of degeneration, suggesting that these changes lead to further remodeling of the tissue. © 2011 Orthopaedic Research Society Published by Wiley Periodicals, Inc. J Orthop Res 30:122–128, 2012     

Histological changes in intervertebral discs after smoking and cessation: experimental study using a rat passive smoking model

Background Passive smoking has been reported to induce intervertebral disc degeneration in rats, and the objective of the present study was to histologically investigate changes in smoking-induced intervertebral disc degeneration after cessation of smoking. Methods Four-week-old rats were subjected to passive smoking for 8 weeks in a smoking box [20 cigarettes a day: one cigarette an hour (inhaled over 3 minutes and followed by ventilation with room air for 5 minutes)] to induce intervertebral disc degeneration. Smoke-free periods of different lengths were then established, and intervertebral discs were histologically analyzed. Results Immediately after 8 weeks of passive smoking, intervertebral discs exhibited cracks, tears, and misalignment of the annulus fibrosus, and increased fibrous tissue was seen in the nucleus pulposus. In addition, the level of interleukin-1β in intervertebral discs was higher in the smoking group than in the non-smoking group. After cessation, progression of degeneration ceased, and the matrix of the nucleus pulposus and annulus fibrosus exhibited increased fibrous connective tissue and proteoglycan. However, there were no changes in annulus fibrosus misalignment. Interleukin-1β levels also remained significantly elevated after 8 weeks of cessation. Conclusions While the annulus fibrosus degeneration caused by smoking was partially irreversible after cessation of smoking, the amount of mucin (proteoglycan) in the nucleus pulposus and annulus fibrosus tended to increase after cessation, thus suggesting the possibility that smoking-induced intervertebral disc degeneration can be repaired to some degree by cessation of smoking.     

An in vivo model of degenerative disc disease.

Although the precise etiology of low back pain is disputed, degeneration of the intervertebral disc is believed to play an important role. Many animal models have been described which reproduce the changes found in degenerative disc disease, but none allow for efficient, large-scale testing of purported therapeutic agents. The purpose of this study was to develop a simple animal model resembling degenerative disc disease using the intervertebral discs found in the tails of rats. The proximal two intervertebral discs in the tails of 20 rats were injected with either chondroitinase ABC or control (phosphate buffered saline, PBS). The tails were harvested at 2 weeks, and measurements were made of intervertebral disc height (measured radiographically and histologically), biomechanics (stiffness, hysteresis, and residual deformation), and histologic appearance. Treatment with chondroitinase ABC resulted in a significant loss in intervertebral disc height (radiographic intervertebral disc height, p=0.001; histologic intervertebral disc height, p<0.001) and significant increases in all biomechanical parameters (stiffness, p<0.001; hysteresis, p=0.006; residual deformation, p=0.004) compared to PBS controls. Intervertebral discs treated with chondroitinase ABC had significantly lower histologic grades for each grading category (nucleus pulposus (NP), annulus fibrosus, and proteoglycan staining) compared to controls. The results of injury with chondroitinase ABC were similar to the findings in degenerative disc disease: reduced intervertebral disc height, diminished proteoglycan content, loss of NP cells, and increased stiffness of the disc. Thus, the model appears to be a reasonable tool for the preliminary in vivo evaluation of proposed treatments for degenerative disc disease.     

颈椎终板软骨细胞凋亡的检测及相关意义

目的检测颈椎终板软骨细胞的细胞凋亡指数,探讨其在椎间盘退变中可能的作用机制。方法颈椎间盘终板及髓核取自我院行颈椎前路手术的35例颈椎椎间盘退变患者（退变组）和19例颈椎外伤患者（外伤组）。光镜观察退变组和外伤组终板和髓核的细胞密度,TUNEL法检测两组终板软骨细胞和髓核细胞的细胞凋亡指数,咔唑分光光度法比较两组髓核蛋白多糖含量。结果退变组终板细胞密度较外伤组减少（P〈0.05）,TUNEL染色显示退变组终板细胞凋亡指数为（34.6±16.1）%,外伤组为（20.1±9.3）%,两组间比较差异有统计学意义（P〈0.05）。Pearson相关分析显示,颈椎终板TUNEL染色阳性细胞率与终板细胞密度、髓核蛋白多糖含量之间呈负相关（r=—0.805,P=0.001;r=—0.677,P=0.023）,与髓核TUNEL阳性细胞率之间呈正相关（r=0.758,P=0.003）。结论颈椎退变终板软骨细胞凋亡率较高,推测在椎间盘退变过程中可能发挥重要作用;软骨细胞凋亡可能与髓核细胞凋亡增加、终板细胞密度与髓核蛋白多糖含量降低密切相关。     

The mechanical response of the lumbar spine to different combinations of disc degenerative changes investigated using randomized poroelastic finite element models

Degeneration of the intervertebral disc is related to progressive changes in the disc tissue composition and morphology, such as water loss, disc height loss, endplate calcification, osteophytosis. These changes may be present separately or, more frequently, in various combinations. This work is aimed to the biomechanical investigation of a wide range of clinical scenarios of disc degeneration, in which the most common degenerative changes are present in various combinations. A poroelastic non-linear finite element model of the healthy L4–L5 human spine segment was employed and randomly scaled to represent ten spine segments from different individuals. Six different degenerative characteristics (water loss in the nucleus pulposus and annulus fibrosus; calcification and thickness reduction of endplate cartilage; disc height loss; osteophyte formation; diffuse sclerosis) were modeled in 30 randomly generated models, 10 for each overall degree of degeneration (mild, moderate, severe). For each model, a daily loading cycle including 8 h of rest, 16 h in the standing position with superimposed two flexion–extension motion cycles was simulated. A tendency to an increase of stiffness with progressing overall degeneration was observed, in compression, flexion and extension. Hence, instability for mild degeneration was not predicted. Facet forces and fluid loss decreased with disc degeneration. Nucleus, annulus and endplate degeneration, disc height loss, osteophytosis and diffuse sclerosis all induced a statistically significant decrease in the total daily disc height variation, facet force and flexibility in flexion–extension. Therefore, grading systems for disc degeneration should include all the degenerative changes considered in this work, since all of them had a significant influence on the spinal biomechanics.     

Molecular biology of degenerative disc disease

The intervertebral disc is a complex anatomic and biochemical structure. It is composed primarily of fibrocytes and chondrocytes that are anatomically segregated in an elaborate avascular macromolecular matrix of collagen and proteoglycans. Degenerative processes associated with aging and trauma result in morphological and molecular changes to the disc. Morphological changes are observed as dehydration, fissuring, and tearing of the nucleus, annulus and endplates. On the molecular level, degenerative changes include decreased diffusion, decreased cell viability, decreased proteoglycan synthesis, and alteration in collagen distribution. The role of inflammatory mediators in these processes, and the potential use of growth factors to delay or reverse the degenerative cascade, is poorly understood. However, these areas are under active investigation, the results of which may soon contribute significantly to our understanding of degenerative disc disease.     

Postmortem changes in ultrastructures of the mouse intervertebral disc

To elucidate the effects of nutrition and oxygen deficiencies on the intervertebral disc, cell components of mouse intervertebral discs and their postmortem changes were observed by electron microscopy. The annulus fibrosus could be divided into an inner and outer region. The main cell components of the annulus fibrosus were fibroblast-like cells in the outer region and chondrocytes in the inner region. The nucleus pulposus consisted of massively packed notochordal cells. The cartilage plates could also be divided into two zones: articular cartilage and growth cartilage containing chondrocytes. Postmortem degenerative changes proceeded from the peripheral to the central parts of the intervertebral disc, ie, showing degeneration of first the fibroblast-like cells, next the chondrocytes, and finally, the notochordal cells. The findings suggest that cells situated at the periphery predominantly depend on aerobic metabolism, whereas the cells situated more centrally depend on anaerobic metabolism. Furthermore, postmortem changes of the nucleus pulposus were similar to age-related changes. The age-related changes or degeneration in the intervertebral disc appear to be related to deficiencies of nutrition or oxygen caused by changes in structures of the disc and the surrounding tissues.     

微载体立体培养腰椎间盘细胞蛋白多糖表达的研究

目的研究腰椎间盘细胞在微载体培养与单层培养中细胞表达蛋白多糖含量的差别。方法椎间盘疾病手术病例的术中切除组织采用酶消化法分别进行微载体三维细胞培养和单层细胞培养；取胎儿椎间盘组织，显微镜下区分髓核细胞和纤维环细胞，分别进行培养，同成入组对照。利用^35S放射标记渗入放免定量测定的方法进行蛋白多糖含量的检测。结果①椎间盘细胞胞内的蛋白多糖含量（cpm），细胞单层培养组为101．909±11．439，微载体立体培养组为136．607±10．792，P〈0．05；②椎间盘细胞表达的蛋白多糖含量（cpm），细胞单层培养组为105．119±13．040，微载体立体培养组为174．231±17．676，P〈0．05；③各组椎间盘细胞表达的蛋白多糖含量均高于细胞内的含量；④胎儿腰椎间盘细胞蛋白多糖的含量及表达量均高于成人退变椎间盘细胞，胎儿髓核细胞蛋白多糖的表达量高于纤维环细胞的表达量。结论椎间盘细胞的微载体三维立体培养相对单层培养具有较高细胞蛋白多糖的表达量，是一种较好的细胞培养方式。     

Experimental disc degeneration due to endplate injury

The aim of this study was to create an experimental model of disc degeneration that closely mimicked human disc degeneration. In six domestic pigs, an L4 cranial endplate perforation into the nucleus pulposus was made. Three months postoperatively, compressive testing was performed on the L2-L4 motion segments, and intradiscal pressure was measured in the intervening discs. Histochemical and morphologic examinations were made on the excised degenerated and adjacent discs. A significant reduction in water content was observed in the outer anterior annulus of the degenerated disc. In the nucleus, the proteoglycan content was significantly reduced, as well as the cellularity, although not significantly. The nucleus lost its gel-like structure and was discolored, and there was delamination of annular layers. Intradiscal pressure in the nucleus was significantly lower in the degenerated disc. In conclusion, experimental degeneration of the intervertebral disc induced by endplate penetration resembled human disc degeneration, as exemplified by biochemical and structural changes.     

实验性脊柱内固定后相应区域椎间盘超微结构观察

目的　观察脊柱内固定后相应区域椎间盘的超微结构变化。　方法　日本大耳白兔2 4只,随机分成实验组和对照组,每组12只。实验组骨膜下游离T1 0 ～L3棘突和关节突,克氏针制成“L”形,将钢丝横行穿过T1 1、1 2 ,L1、2 的关节突关节,并与置于T1 1 ～L3棘突两旁的克氏针系紧,对相应区域的脊柱行内固定术。对照组未行手术,仅喂养至实验完成。术后6个月,对两组动物摄X线片观察1次,随后处死动物。取两组动物的L1 椎间盘组织(髓核、纤维环内侧及纤维环外侧)行透射电镜观察,对两组T1 2 、L2 椎间盘组织分别行水平面和矢状面透射电镜及扫描电镜观察。　结果　X线片显示,实验组与对照组椎体及椎间隙差别不明显;透射电镜与扫描电镜观察,实验组椎间盘的髓核、纤维环内层细胞的结构改变较纤维环外层早;对照组的髓核、纤维环内层细胞的结构改变与纤维环外层差别不明显。在退变的椎间盘基质中,蛋白多糖颗粒和特殊结构明显减少。髓核与纤维环基质内有蛋白多糖颗粒和一种特殊结构,而特殊结构在髓核与纤维环内层的形态不一致。　结论　脊柱内固定术后6个月,实验组在异常应力环境下发生椎间盘退变。髓核、纤维环内层基质内的特殊结构分布有特殊规律,与蛋白多糖颗粒在椎间盘退变中的生物学行为密切相关。     

A clinicopathological study of cervical intervertebral discs--Part 1: On histopathological findings

In order to examine the aging process of the cervical intervertebral discs, a histopathological study was performed on 158 cervical discs obtained at autopsy from 37 individuals ranging in age from 3 months to 87 years. In the nucleus pulposus, degenerative changes consisting of myxomatous and slightly hyalinized degeneration were already seen in the specimens obtained from subjects in the third decade of life. Degenerative changes of the annulus fibrosus, however, tended to develop from the fourth decade of life, with myxomatous degeneration mainly in the anterior and hyalinized degeneration in the posterior annulus. The horizontal fissure of the annulus extending to its outer portion was seen more frequently in the posterior portion. In the cartilaginous plate of the vertebral body, fissure formation and degeneration became evident in the fifth decade of life. In contrast to the disc, repairing processes were observed in the cartilaginous plate. Spur formation at the corner of the vertebral body may be due to the degeneration of the outer layer of the disc leading to enchondral ossification.     

Effects of axial traction stress on solute transport and proteoglycan synthesis in the porcine intervertebral disc in vitro

Summary The effects of axial traction stress on intradiscal hydration, solute transport and proteoglycan synthesis were examined in 658 porcine coccygeal intervertebral discs in vitro. Measurements were performed in three tissue fractions: nucleus pulposus, inner and outer annulus fibrosus. At 0.80 MPa traction stress, the equilibrium hydration did not change in the nucleus pulposus. However, in the inner and outer annulus, the equilibrium hydration was reduced, and the change led to an increase of the effective fixed charge density. Diffusion of solute to the nucleus pulposus was significantly suppressed at 0.80 MPa traction stress. The fluid flow of the intervertebral disc tended to be suppressed during the creep recovery process after compression. The proteoglycan synthesis rate in the outer annulus was markedly suppressed by traction stress of 0.80 MPa for 4 h, but not that in the nucleus pulposus. These results suggest that a prolonged excessive axial traction stress induces a decrease in tissue hydration in the annulus fibrosus, and this may lead to an increase in the fractional volume of solid in the matrix and tissue osmotic pressure, resulting in diffusion inhibition of solute and suppression of proteoglycan synthesis. Thus, prolonged and excessive spinal traction may accelerate disc degeneration.Presented at the annual meeting of the International Society for the Study of the Lumbar Spine, May 12–16, 1991, Heidelberg, Germany     

Articular cartilage and intervertebral disc proteoglycans differ in structure: an electron microscopic study

Articular cartilage and the intervertebral disc tissues have different material and biological properties and different patterns of aging and degeneration. To determine if the proteoglycans of these tissues differ in structure, we used the electron microscopic monolayer technique to compare baboon articular cartilage proteoglycans with baboon annulus fibrosus, transition zone, and nucleus pulposus proteoglycans. Intervertebral disc and articular cartilage proteoglycans differed significantly. Articular cartilage contained large proteoglycan aggregates formed from hyaluronic acid central filaments, multiple monomers, and large nonaggregated monomers. These molecules were identical to those of nasal cartilage, growth plate cartilage, chondrosarcomas, or menisci. In contrast, the intervertebral disc tissues contained only nonaggregated proteoglycan monomers and clusters of monomers without apparent central filaments. Intervertebral disc nonaggregated monomers were shorter and more variable in length than those from articular cartilage, and nucleus pulposus nonaggregated monomers were even shorter and more variable in length than transition zone and annulus fibrosus monomers. These observations suggest that significant differences in proteoglycan metabolism exist between articular cartilage and intervertebral disc.     

白细胞介素-6对椎间盘细胞中蛋白多糖代谢影响的实验研究

目的:研究白细胞介素-6(interleukin-6,IL-6)对椎间盘纤维环和髓核细胞中蛋白多糖代谢的影响。方法:自然流产的胎儿4例,4h内无菌取出椎间盘,分别进行纤维环和髓核细胞的体外培养。在纤维环细胞的培养液中分别加入IL-60(对照组)、400、800ng/ml,培养24h后,用Alcian法检测培养液中硫酸软骨素的含量。在培养中的髓核细胞中加入IL-60(对照组)、100、400、800ng/ml,培养24h,然后测量培养液中硫酸软骨素的含量。结果:在纤维环细胞中加入IL-6组较不加IL-6对照组培养液中硫酸软骨素的含量增加,在髓核细胞组中加入IL-6组和对照组的差别无显著性。结论:IL-6可以刺激椎间盘纤维环细胞中蛋白多糖的合成,但对髓核细胞中蛋白多糖的合成没有明显的作用。     

Assessment of functional and behavioral changes sensitive to painful disc degeneration

The development of an in vivo rodent discogenic pain model can provide insight into mechanisms for painful disc degeneration. Painful disc degeneration in rodents can be inferred by examining responses to external stimuli, observing pain‐related behaviors, and measuring functional performance. This study compared the sensitivity of multiple pain and functional assessment methods to disc disruption for identifying the parameters sensitive to painful disc degeneration in rats. Disc degeneration was induced in rats by annular injury with saline injection. The severity of disc degeneration, pain sensitivity, and functional performance were compared to sham and naïve control rats. Saline injection induced disc degeneration with decreased disc height and MRI signal intensity as well as more fibrous nucleus pulposus, disorganized annular lamellae and decreased proteoglycan. Rats also demonstrated increased painful behaviors including decreased hindpaw mechanical and thermal sensitivities, increased grooming, and altered gait patterns with hindpaw mechanical hyperalgesia and duration of grooming tests being most sensitive. This is the first study to compare sensitivities of different pain assessment methods in an in vivo rat model of disc degeneration. Hindpaw mechanical sensitivity and duration of grooming were the most sensitive parameters to surgically induced degenerative changes and overall results were suggestive of disc degeneration associated pain. © 2015 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 33:755–764, 2015.     

Both expression of cytokines and posterior annulus fibrosus rupture are essential for pain behavior changes induced by degenerative intervertebral disc: An experimental study in rats

The aim of this study was to analyze the relationship between intervertebral disc degeneration and low back pain (LBP). Rat L4/5 disc degeneration model was established by annular puncture using a 0.4 mm needle anteriorly or posteriorly. In both anterior and posterior puncture models, magnetic resonance imaging (MRI) and histological analyses revealed marked disc degeneration 2 weeks after puncture. Cytokine expression was up‐regulated in different level in nucleus pulposus (NP) from 3 days after puncture. Pain behavioral tests indicated that the anterior disc puncture did not induce pain behavior changes, whereas the posterior disc puncture resulted in mechanical allodynia from 1 day to 21 days after injury. Besides, cytokine expression was significantly increased in dorsal root ganglion (DRG) at 1 and 2 weeks after posterior puncture, but not after the anterior puncture. These findings indicate the NP of the degenerative disc expresses different levels of inflammatory cytokines, and posterior disc puncture produced mechanical allodynia. The expression phase of cytokines in the NP was accordance with mechanical hyperalgesia in the posterior disc puncture model. Both expression of cytokines and posterior annulus fibrosus (AF) rupture in degenerative intervertebral disc are essential for pain behavior changes. © 2013 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 32:262–272, 2014.     

Changes with age in proteoglycan synthesis in cells cultured in vitro from the inner and outer rabbit annulus fibrosus. Responses to interleukin-1 and interleukin-1 receptor antagonist protein

STUDY DESIGN: Proteoglycan synthesis was examined in cells isolated from the inner and outer annulus fibrosus of young and old rabbits. Their responses to interleukin-1 alpha and interleukin-1 receptor antagonist protein were investigated. OBJECTIVES: To evaluate the age-related changes and the anatomically related differences in the function of intervertebral disc cells. SUMMARY OF BACKGROUND DATA: Proteoglycan content in the human intervertebral disc decreases with age. Age-related changes in intervertebral disc cell function, however, have not been fully investigated. METHODS: Japanese white rabbits aged 2 months (young group) and 3 years (old group) were used. The inner and outer layer of the annulus fibrosus were separated. The proteoglycan synthesis and release were measured in cells cultured with or without human recombinant interleukin-1 alpha and interleukin-1 receptor antagonist protein. RESULTS: The proteoglycan synthesis significantly decreased and the release rate significantly increased in the old rabbits, compared with the young ones. In the inner annulus, the inhibition of proteoglycan synthesis due to interleukin-1 alpha was greater in the old rabbits than in the young ones. In the old rabbits, interleukin-1-induced inhibition was more pronounced in the inner annulus than in the outer annulus. Interleukin-1 receptor antagonist protein suppressed inhibition of proteoglycan synthesis by interleukin-1 alpha in the two layers in both age groups. CONCLUSIONS: Both the decline in proteoglycan synthesis and the increased cell sensitivity to interleukin-1 alpha with age may contribute to the degradation of discs. The increase in cell response to interleukin-1 alpha in the inner annulus of rabbits may explain why the inner annulus and nucleus pulposus degrade earlier than the outer annulus in human discs. Interleukin-1 receptor antagonist protein could be useful in inhibiting the degradation of the disc.     

Abundance of calpain and aggrecan-cleavage products of calpain in degenerated human intervertebral discs

Objective

To assess the expression of calpains and calpain-induced aggrecan fragmentation in early and advanced stages of degeneration of human intervertebral discs (IVDs).

Design

Disc tissue samples of 55 patients (mean age, 51.2 ± 22.3 years) who underwent intervertebral fusion were divided into groups with early and advanced degeneration based on the Thompson magnetic resonance imaging (MRI) scale. In advanced degeneration group, five patients (mean age, 35.5 ± 11.4 years) of lumbar disc herniation (LDH) were included. Protein levels of m- and μ-calpains and their inhibitor calpastatin were assayed, and immunohistochemical techniques were used to localize and quantify the production of the enzymes. To investigate calpain activity, we assayed purified aggrecan fragmentation in disc tissue by Western blotting and immunohistochemistry with VPGVA antibody, which recognizes the m-calpain generated neo-epitope GVA.

Results

Discs at early stages of degeneration expressed low levels of m- and μ-calpains and calpastatin, and few cells expressed degenerative enzymes. At more advanced stages of degeneration, the expression and number of cells immunopositive for m-calpain, μ-calpain and calpastatin were significantly higher. Further finding showed that anti-GVA-reactive aggrecan fragments were significantly higher in discs at advanced compared with early stages of degeneration. Herniated disc samples showed stronger expression and more cells immunopositive for calpains, calpastatin and GVA in the nucleus pulposus than in the annulus fibrous.

Conclusions

The expression of calpains, together with m-calpain-induced degradation products of extracellular matrix, was correlated with the degree of disc degeneration in human IVD tissue. These findings suggest that calpains may be involved in IVD degeneration via proteoglycan (PG) cleavage.     

Disc degeneration in magnetic resonance imaging. A comparative biochemical, histologic, and radiologic study in cadaver spines

Magnetic resonance imaging (MRI) findings of 89 autopsied intervertebral discs from 22 cadaveric lumbar spines were correlated with biochemical composition, conventional radiography, and histologic structure to study the nature of disc intensity changes seen in MRI. Discs with a low signal intensity on T2-weighted MRI were characterized by shortening of relaxation times, dehydration, and decreases in total proteoglycan content and chondroitin-keratan sulfate ratios in the nucleus pulposus. This corresponded well with previously published studies. In histologic structure, no obvious differences between MRI findings were found. In conclusion, a low signal intensity in a lumbar disc on T2-weighted MRI probably reflects a true biochemical disc degeneration, but its relation to structural degenerative changes is uncertain. Therefore, MRI seems to be a sensitive and a specific imaging modality for detecting pathologic biochemical disc changes in the spine of a young adult.     

Changes in the nucleus pulposus of the intervertebral disc in bipedal mice. A light and electron microscopic study

Bipedal mice were produced by clipping the forelimbs and tails of mice within one week of birth. Using light and electron microscopy, the nucleus pulposus of the lumbar intervertebral disc in the bipedal mice was compared with that in normal mice at three, six, and 12 months of age. In normal neonatal mice, the nucleus pulposus is composed of densely packed notochordal cells, which undergo degenerative changes and decrease in number with age. In the bipedal mice, degenerative changes in the nucleus pulposus were accelerated, and herniation of the nucleus pulposus occurred frequently. At the same time, active chondrocytes associated with cartilage matrix appeared in the nucleus pulposus. This sequence of morphologic changes in the nucleus pulposus of the bipedal mice resembles the age-related changes that occur in the nucleus pulposus of the human intervertebral disc. These morphologic changes can be accelerated by creating abnormal mechanical stress. Chondrocytes in the nucleus pulposus may develop from surrounding cartilaginous tissue--cartilage plates and annulus fibrosus.