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. 2010 Dec 1;4(1):31–41. doi: 10.1242/dmm.006403

Degeneration and regeneration of the intervertebral disc: lessons from development

Lachlan J Smith 1, Nandan L Nerurkar 1, Kyung-Suk Choi 2, Brian D Harfe 2,*, Dawn M Elliott 1,*
PMCID: PMC3008962  PMID: 21123625

Abstract

Degeneration of the intervertebral discs, a process characterized by a cascade of cellular, biochemical, structural and functional changes, is strongly implicated as a cause of low back pain. Current treatment strategies for disc degeneration typically address the symptoms of low back pain without treating the underlying cause or restoring mechanical function. A more in-depth understanding of disc degeneration, as well as opportunities for therapeutic intervention, can be obtained by considering aspects of intervertebral disc development. Development of the intervertebral disc involves the coalescence of several different cell types through highly orchestrated and complex molecular interactions. The resulting structures must function synergistically in an environment that is subjected to continuous mechanical perturbation throughout the life of an individual. Early postnatal changes, including altered cellularity, vascular regression and altered extracellular matrix composition, might set the disc on a slow course towards symptomatic degeneration. In this Perspective, we review the pathogenesis and treatment of intervertebral disc degeneration in the context of disc development. Within this scope, we examine how model systems have advanced our understanding of embryonic morphogenesis and associated molecular signaling pathways, in addition to the postnatal changes to the cellular, nutritional and mechanical microenvironment. We also discuss the current status of biological therapeutic strategies that promote disc regeneration and repair, and how lessons from development might provide clues for their refinement.

Introduction

Low back pain affects up to 85% of people at some point during their lives, resulting in healthcare and related costs in the United States of $100 billion every year (Andersson, 1999; Katz, 2006). Degeneration of the intervertebral discs is strongly implicated as a cause of low back pain (Bogduk, 1991; Freemont, 2009). The intervertebral discs are partially movable joints that connect each of the vertebral bodies in the spine, functioning both to transfer loads and impart mobility. The etiology of disc degeneration has proven challenging to characterize because it is poorly defined and its progression is closely linked to aging (Adams and Roughley, 2006; Urban and Roberts, 2003). Disc degeneration is perhaps best defined as a cascade that begins with changes to the cellular microenvironment within the substructures of the disc that progresses over decades to structural breakdown and functional impairment (Freemont, 2009; Urban and Roberts, 2003).

Current treatments for discogenic low back pain are predominantly conservative, involving, for example, physiotherapy and anti-inflammatory medications (Mirza and Deyo, 2007). In cases in which surgical intervention is warranted, the current gold standard is spinal fusion (Mirza and Deyo, 2007); however, fusion seeks only to alleviate painful symptoms without restoring disc mechanics or structure, recurrent episodes of pain are common and adjacent levels of the spine can experience accelerated degeneration requiring additional surgery (Ghiselli et al., 2004; Hanley et al., 2010). More recently, disc arthroplasty (artificial disc replacement) has been used to restore mobility; however, these implants do not recapitulate the mechanical function of the native joint, are subject to wear and failure, and resection is a complex surgical procedure (Hanley et al., 2010). There is, therefore, a strong need for therapies that both alleviate painful symptoms and restore disc structure and mechanical function by directly addressing the underlying biological causes of disc degeneration.

Although disc degeneration is not commonly present until adulthood (Miller et al., 1998), changes to the cellular microenvironment of the disc begin within just a few years of birth (Boos et al., 2002). Developmentally, the disc is a unique structure formed from cells of at least two disparate embryonic origins: the notochord and the somites. These lineages give rise to a tissue that is complex and specialized in terms of its microstructure, mechanical function and cell types. In this Perspective, we begin by providing a short overview of disc degeneration and current treatment strategies. We then provide a detailed review of embryonic development of the disc and the subsequent postnatal changes that precede and potentially predispose the disc to clinically significant degeneration later in life. We conclude with a synergistic discussion, examining how an understanding of the mechanisms that underlie development might influence therapeutic strategies for repair and regeneration of degenerate discs, and suggest directions for future research.

Structure and function of the intervertebral disc

The intervertebral disc consists of multiple, structurally distinct anatomical regions (Fig. 1). The central nucleus pulposus (NP) contains large quantities of the proteoglycan aggrecan, which aggregates along chains of hyaluronan (Urban, 1996). The glycosaminoglycan side chains of these proteoglycans carry a fixed negative charge and generate an osmotic swelling pressure within an irregular meshwork of collagen II fibrils. The NP is contained peripherally by the annulus fibrosus (AF), which has a heterogeneous composition and architecture (Humzah and Soames, 1988). The highly organized outer regions of the AF consist of distinct lamellae, which are composed of bundles of collagen I fibers oriented at oblique angles that alternate within each consecutive lamella to form an angle-ply structure (Cassidy et al., 1989; Marchand and Ahmed, 1990). In the inner AF, there is a transition to collagen II that, together with increasing proteoglycan concentration, gives rise to a less fibrous and less organized structure (Humzah and Soames, 1988). Two thin endplates of hyaline cartilage extend superiorly and inferiorly over the inner AF and NP to interface with the vertebral bodies, and function to regulate nutrient diffusion between the disc and the vertebral bodies (Rajasekaran et al., 2004; Urban et al., 2004). In the outer regions of the AF, collagen fibers anchor directly into the vertebral bone.

Fig. 1.

Fig. 1.

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Schematic representations of the adult intervertebral disc. (A) Mid-sagittal cross-section showing anatomical regions. (B) Three-dimensional view illustrating AF lamellar structure.

The foremost function of the intervertebral disc is mechanical: it transfers loads, dissipates energy and facilitates joint mobility. The NP and AF structures act synergistically to distribute and transmit loads between the vertebral bodies (Heuer et al., 2008; Johannessen et al., 2006; O’Connell et al., 2007a). When the disc is compressed, hydrostatic pressure is generated within the NP, which is constrained peripherally by the AF, generating tensile circumferential stresses within the lamellar structure (Heuer et al., 2008; O’Connell et al., 2007a). Compressive loads are also supported directly by the inner AF, which is rich in proteoglycans (Roughley et al., 2006; Vresilovic et al., 2006). The angle-ply structure and nonlinear properties of the AF facilitate both joint mobility and stability in multiple modalities, including bending and rotation, and combinations thereof (Guerin and Elliott, 2007; Heuer et al., 2008; Schmidt et al., 2007).

The adult disc is almost completely avascular (Nerlich et al., 2007), so resident cells must survive and function in an environment that is low in nutrients and oxygen (Urban et al., 2004). Cell density in the adult disc is very low, averaging 9000 cells/mm3 in the AF and 4000 cells/mm3 in the NP. These values are considerably less than other cartilaginous tissues (Maroudas et al., 1975). Cells in the outer AF are fusiform fibroblast-like cells, whereas those in the inner AF are more rounded (Bruehlmann et al., 2002). Cells in the NP begin as large vacuolated cells that resemble those of the embryonic notochord; however, early in postnatal life there is a transition to smaller, less metabolically active cells (Urban et al., 2000). The potential significance of this transition in NP cell phenotype will be a focus of this Perspective.

Pathogenesis of intervertebral disc degeneration

With advancing age comes pronounced changes in the composition of the disc extracellular matrix (Antoniou et al., 1996; Roughley, 2004). Decreasing aggrecan content in the NP leads to reduced hydration (Buckwalter, 1995), leading in turn to impaired mechanical function (Boxberger et al., 2006; Costi et al., 2008). A less hydrated, more fibrous NP is unable to evenly distribute compressive forces between the vertebral bodies. The forces are instead transferred non-uniformly to the surrounding AF (Adams et al., 1996), which can result in altered AF mechanical properties (Acaroglu et al., 1995; O’Connell et al., 2009) and progressive structural deterioration, including the formation of circumferential and radial tears (Vernon-Roberts, 1988). On occasion, radial tears can progress to a posterior radial bulge or herniation of NP material (Vernon-Roberts, 1988), resulting in painful symptoms. Decreased disc height is also commonly associated with advanced disc degeneration (Videman et al., 2003) and results in painful compression of surrounding structures. Examples of discs with advancing degrees of degeneration, as visualized by magnetic resonance imaging, are shown in Fig. 2.

Fig. 2.

Fig. 2.

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Magnetic resonance images illustrating different stages of human lumbar disc degeneration. (A) A healthy disc exhibiting distinct AF lamellae (AF) and central NP region (NP). (B) A disc exhibiting early stages of degeneration, including moderate height reduction, decreased NP signal intensity and inward bulging of AF lamellae (*). (C) A disc exhibiting advanced stages of degeneration, including severely reduced height, large fissure (*) and generalized structural deterioration. Images obtained using 7T Siemens scanner and a turbo spin echo sequence at 200 μm isotropic voxel resolution.

Multiple interdependent factors, including altered mechanical loading (Stokes and Iatridis, 2004), reduced nutrient supply (Urban et al., 2004) and hereditary factors (Battie and Videman, 2006), have been implicated in the initiation and progression of the degenerative cascade. Changes to disc extracellular matrix composition with age are attributable to alterations in function and increased death of the cells that make up the disc (Zhao et al., 2007). The cellular microenvironment of the disc becomes progressively more hostile, and is characterized by upregulated levels of proinflammatory cytokines and associated catabolic enzymes (Le Maitre et al., 2007). This is in part due to a reduction in the diffusion of nutrients through the endplates that accompanies thinning and calcification; the reasons for these endplate changes are not well understood (Rajasekaran et al., 2004; Urban et al., 2004). Mechanical loading might also play a direct role in the progression of disc degeneration. Cell survival and matrix synthesis are both sensitive to compressive stress (Maclean et al., 2004; Walsh and Lotz, 2004). Although some mechanical stimulation is necessary to induce nutrient diffusion and to promote matrix synthesis, excessive loading can result in localized tissue injury that is slow to repair and alters strain distribution throughout the extracellular matrix of the entire disc (Stokes and Iatridis, 2004). Finally, hereditary factors also play a role in an individual’s susceptibility to disc degeneration (Battie and Videman, 2006). Twin studies suggest that genetics predispose individuals to disc degeneration (Sambrook et al., 1999). Population studies for candidate genes and genome-wide assays are advancing this idea, although the fact that disc degeneration is a multi-factorial process and because large sample sizes are needed for such studies, genetic analyses have been challenging (Chan et al., 2006). Additionally, undertaking gene analyses (PCR or microarray) for thousands of individuals becomes prohibitively expensive.

Models of intervertebral disc degeneration

The development and application of model systems in which to study the pathogenesis of disc degeneration and evaluate associated treatments has proved extremely challenging (Alini et al., 2008). Reasons for this include the slow progression of the condition, multifactorial underlying causes and a poor understanding of the circumstances under which degenerative changes are associated with painful symptoms. Nevertheless, the scarce availability of primary human degenerate disc tissue, and the almost nonexistence of healthy tissue for comparison in in vitro studies, means that model systems, despite their limitations, are indispensable for investigating the molecular and cellular pathways that maintain healthy discs and that characterize the degenerative cascade. Indeed, the discs of both large and small animals possess anatomical and biomechanical traits that make them suitable models for studying the human condition (O’Connell et al., 2007b; Beckstein et al., 2008). Techniques for initiating degenerative changes in such model systems include AF injury (Elliott et al., 2008; Yoon et al., 2008), mechanical overload (Iatridis et al., 1999; Kroeber et al., 2002) and enzymatic treatment to reduce NP glycosaminoglycan content (Boxberger et al., 2008; Hoogendoorn et al., 2007). There are also a few animals that develop disc degeneration spontaneously, such as the sand rat and chondrodystrophoid dog (Gruber et al., 2002; Hansen, 1952).

Current treatments for disc degeneration

The broad objectives of any treatments for disc degeneration should be both to alleviate painful symptoms and to restore mechanical function. Biological treatment strategies, when appropriately targeted, have the potential to effectively satisfy both objectives. Depending on the stage of degeneration (Fig. 2) during which treatment strategies are designed to act, they can be classified as regenerative or reparative. In general, regenerative strategies, such as cell, gene and protein therapy, are more amenable to early-stage degeneration that is localized to the NP (Fig. 2B) (Leung et al., 2006; Masuda, 2008; Sakai, 2008; Sobajima et al., 2004; Wallach et al., 2003). Repair strategies are more appropriate for more advanced stages of degeneration that are characterized by structural degradation of both the NP and AF (Fig. 2C) (Kandel et al., 2008; Nerurkar et al., 2010; O’Halloran and Pandit, 2007). In this section we provide a brief overview of current strategies for disc regeneration and repair.

Regeneration

Regenerative strategies for the treatment of disc degeneration are focused on reviving or healing extant disc tissue. This can be done either by altering the phenotype of cells native to the ailing disc or by introducing new cell populations. Injection of growth factors such as bone morphogenetic protein 7 (BMP-7), transforming growth factor-β (TGFβ), growth/differentiation factor 5 (GDF-5) and others into the disc has been widely studied as a means to stimulate extracellular matrix production and cell proliferation (Masuda, 2008). In certain animal models of disc degeneration, treatments have successfully diminished or even reversed degeneration-like characteristics (Masuda, 2008). However, the translation of such treatments to human application and clinical use is hampered by the inability to accurately recreate the progressive, life-long degenerative transformation of the disc in an animal model (Alini et al., 2008). Moreover, the potential success of anabolic factors injected directly into the disc might be limited, both owing to the short biological half-life of the factors and their rapid diffusion away from the delivery site. Alternatively, cell populations within the disc can be manipulated through gene therapy approaches, which involve the delivery of genes into cells through viral-vector-mediated gene transfer (Sobajima et al., 2004). Finally, a more recent regenerative approach under investigation is cell therapy, whereby cells are delivered locally to the degenerated disc. The purpose of these cells is to either provide signaling cues that ameliorate the effects of disc degeneration, or adopt and/or maintain disc-like phenotypes themselves, producing extracellular matrix intended to re-establish healthy disc function (Leung et al., 2006; Sakai, 2008).

Repair

Reparative strategies are focused on either augmenting or replacing degenerate disc tissue to re-establish healthy disc function. Although there are several non-biological reparative methods available, a recent focus in this area is on tissue engineering. The appeal of tissue engineering strategies is that, unlike non-biological materials that can wear with time, cell-generated tissues retain their capacity for remodeling and growth. The prevailing paradigm of tissue engineering is that cells on a biomaterial substrate or scaffold can be coaxed into forming new tissue when the appropriate stimuli (biological or physical) are provided. Hydrogels such as alginate-, collagen- and hyaluronan-based gels, among others, have been shown to support the survival of mature NP cells and to be conducive to matrix deposition (O’Halloran and Pandit, 2007). Although NP tissue engineering has been a particular focus over the years, interest has more recently turned to the AF and to whole disc composite tissues (Bowles et al., 2010; Mizuno et al., 2006; Nerurkar et al., 2010; Nesti et al., 2008). Most of these studies have used either disc cells or mesenchymal stem cells. Although experiments involving in vitro formation of disc-like structures have been used to make significant advances, important challenges remain to be addressed, including translation of these technologies to large animal models for pre-clinical trials and meeting in vivo nutritional requirements.

Disc development: embryogenesis and postnatal growth

In contrast to the challenges encountered in establishing model systems that accurately recapitulate the complex cascade that leads to symptomatic disc degeneration, model systems have recently facilitated a rapid expansion of our understanding of intervertebral disc development. For example, mice have been used to fate map cell populations, and other small and large in vivo models have been used to study structural maturation and extracellular matrix patterning. In addition, many in vitro models have been used to study microenvironmental mediators of cell phenotype and matrix synthesis. These model systems have enabled the identification of growth factors that stimulate extracellular matrix synthesis during embryonic tissue formation (Pelton et al., 1990; Dahia et al., 2009; Baffi et al., 2006; Baffi et al., 2004; Sohn et al., 2010), transcriptional programs involved in cell differentiation and matrix patterning (Peters et al., 1999; DiPaola et al., 2005; Wallin et al., 1994; Barrionuevo et al., 2006; Smits and Lefebvre, 2003), and the unique gene expression signatures that identify the resident cell phenotypes (Minogue et al., 2010; Chen et al., 2006). Understanding how these factors function during normal disc development could contribute to the successful advancement of regenerative and reparative treatment strategies for disc degeneration. Furthermore, model systems have been used to uncover multiple postnatal changes within the disc microenvironment, including a transition in cell phenotype (Peacock, 1952; Trout et al., 1982a; Hunter et al., 2004), vascular regression (Nerlich et al., 2007) and altered matrix synthesis (Cappello et al., 2006; Aguiar et al., 1999; Erwin et al., 2006; Erwin and Inman, 2006), which, by altering the mechanical and nutritional microenvironment, might together predispose the disc to degenerative changes later in life. Within this context, in the following sections we review in detail the embryonic formation of the disc tissue structures, the associated molecular signaling pathways and important aspects of subsequent postnatal growth.

Embryogenesis

Embryonic development of the vertebral column centers on the notochord, a rod-like mesoderm-derived structure (Fleming et al., 2001; Stemple, 2005). For development of the intervertebral disc, the notochord is important both as a signaling center that mediates cell migration, differentiation and survival, and as the structure that physically gives rise to the NP (Choi et al., 2008; Peacock, 1951; Walmsley, 1953). Embryonic morphogenesis of the disc, as well as key molecules implicated in this process, are illustrated schematically in Fig. 3.

Fig. 3.

Fig. 3.

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Schematic representation of embryonic morphogenesis of the mammalian intervertebral disc. Colors represent origins and fates of cell populations. Also indicated are key morphogens and transcriptional regulators implicated in the growth and differentiation of the disc structures at each developmental stage. (A) The notochord adjacent to pairs of paraxial somites, which contain sclerotome cells. (B) Sclerotome cells condense around the notochord. (C) Cells adopt a metameric pattern of more condensed (green) and less condensed (brown) regions that give rise to the disc and vertebral bodies, respectively. (D) The notochord contracts within the vertebral body rudiments and expands within the future intervertebral disc to form the NP. (E) Basic structures of the disc are established, and AF cells adopt orientations and alignments that form the template for the lamellar structure. VB, vertebral body.

The AF and NP regions of the disc arise concurrently along distinct developmental pathways. At approximately 30 days fetal gestation in the human (12 days in the mouse), cells of the sclerotome migrate medially from pairs of paraxial somites (Fig. 3A) to condense around the notochord (Fig. 3B) (Hunter et al., 2003a; Peacock, 1951). This condensation adopts a metameric pattern of more condensed and less condensed regions (Fig. 3C), which later give rise to the AF and vertebral bodies, respectively (Aszodi et al., 1998). Cells in the future AF region adopt a fibroblastic morphology. These cells align and orient to form the template for matrix deposition that later defines the AF angle-ply lamellar structure (Fig. 3E) (Rufai et al., 1995). AF cell organization is mediated by cytoskeletal actin filaments. Stress fibers form within these cells with an alignment that presages the mature collagen organization of the AF (Hayes et al., 1999).

Concurrently with AF morphogenesis, the notochord contracts within the forming vertebral body rudiments while simultaneously expanding within the intervertebral regions to form the NP (Aszodi et al., 1998; Pazzaglia et al., 1989; Peacock, 1951). This process of notochord ‘involution’ is illustrated schematically in Fig. 3D, and histologically in Fig. 4. Biomechanical forces have been proposed to play a role in this transformation: swelling of the pre-vertebral chondrogenic condensations might constrict the notochord in these regions, inducing notochord cell migration towards the intervertebral anlagen (Aszodi et al., 1998). This hypothesis is supported by observations in collagen-II-deficient mice, in which vertebral body formation is impaired and the notochord persists as a continuous rod-like structure. The alternating regions of notochordal narrowing and expansion that occur during normal morphogenesis are absent and, consequently, no NP is formed (Aszodi et al., 1998).

Fig. 4.

Fig. 4.

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Stages of notochord transformation into the NP in the mouse embryo. Embryos were stained with Alcian Blue (which marks glycosaminoglycans) and Picrosirius Red (which marks collagen). At embryonic day (E)12.5, the notochord (arrow) runs uninterrupted the length of the vertebral column. Sclerotome cells have condensed perichordially, and metameric patterning of future disc and vertebral body condensations is apparent. At E13.5, the notochord has begun to contract within the vertebral body regions and expand within the disc regions (arrow). At E14.5, the notochord has virtually disappeared from the vertebral bodies, persisting solely in the locations of the future NPs (arrow). In the neonate, lateral expansion of the NP has occurred (arrow) and primary ossification centers are present in the vertebral bodies. At postnatal age 1 month, vertebral bodies are fully ossified and the NP (arrow) contains a glycosaminoglycan-rich extracellular matrix surrounded by the collagenous AF. Scale bars: E12.5, E13.5 and E14.5: 200 μm (top) and 100 μm (bottom); neonate: 400 μm (top) and 200 μm (bottom); 1 month: 500 μm (top) and 400 μm (bottom).

Molecular signaling

Disc embryogenesis occurs in response to a coordinated series of molecular signals that originate from the cells of the notochord and the floor plate of the neural tube (Placzek, 1995). Sonic hedgehog (Shh) is a signaling molecule that performs diverse roles in regulating skeletal morphogenesis by providing positional information and directing cell differentiation (Ehlen et al., 2006; McMahon et al., 2003). Patterning of the somites is regulated by opposing gradients of Shh and Wnt signaling, with Shh being specifically responsible for definition of the sclerotome (Ehlen et al., 2006). Shh operates synergistically with noggin, a BMP antagonist, during induction of the sclerotome (McMahon et al., 1998). Noggin is initially expressed by cells of the notochord (McMahon et al., 1998) before becoming localized to the developing AF where it remains until birth, potentially acting to block BMP signaling that originates from the vertebral bodies (DiPaola et al., 2005).

Pax genes encode transcription factors that regulate proliferation, differentiation, apoptosis, cell migration and stem cell maintenance. In particular, Pax expression is important for specifying and maintaining tissue boundaries (Frost et al., 2008; Wallin et al., 1994), and as such might be responsible for delineating the more and less condensed regions of cells that will give rise to the discs and vertebral bodies, respectively (Smith and Tuan, 1994). Of the Pax gene family, Pax1 and Pax9 specifically have been implicated in the development of the intervertebral disc (Peters et al., 1999). In their absence, both intervertebral discs and vertebral bodies fail to develop; in their place forms an irregular, cartilaginous rod that is interrupted by ventral extensions of the neural arches (Peters et al., 1999). Pax1 expression in the sclerotome is mediated by Shh and noggin signaling that originates from the notochord (Fan and Tessier-Lavigne, 1994; Furumoto et al., 1999; McMahon et al., 1998). Prior to formation of the disc and vertebral body anlagens, almost all sclerotome cells express Pax1. Following disc formation, Pax1 is localized solely to the disc anlagen (the precursor of the AF) surrounding the notochord as it transforms into the NP (DiPaola et al., 2005; Wallin et al., 1994). There is also evidence that Pax1 mediates signaling from the sclerotome back to the notochord: in Pax1 mutants, notochords are enlarged and have increased rates of cell proliferation (Wallin et al., 1994). As such, it has been suggested that Pax1, as a mediator of notochordal cell proliferation, regulates contraction and expansion of the notochord as it transforms into the NP.

Members of the Sox (Sry-related high-mobility-group box) gene family perform diverse functions during development (Schepers et al., 2002; Wegner, 2009). Among these, Sox5, Sox6 and Sox9 are specifically implicated in chondrogenesis (Schepers et al., 2002), and all three seem to be important for disc development. Sox5 and Sox6 are expressed in both sclerotome-derived and notochordal cells (Smits and Lefebvre, 2003). In mice lacking both Sox5 and Sox6, the notochordal sheath fails to form, probably due to associated downregulation of genes encoding cartilage matrix components such as collagen II and aggrecan (Smits and Lefebvre, 2003). The absence of this sheath results in downstream consequences, including: notochordal cell apoptosis during perichordal condensation of the sclerotome; aberrant removal of notochordal cells from the intervertebral regions compared with the vertebral regions; and, ultimately, failure of the NP to form. Additionally, there is delayed and impaired differentiation of cartilage in the inner AF (Smits and Lefebvre, 2003). Sox9 is expressed in all primordial cartilage during embryogenesis, coincident with collagen II expression (Bi et al., 1999), including in the sclerotome and notochord (Barrionuevo et al., 2006). Although mice lacking the Sox9 gene initially develop a notochord, it later disintegrates (Barrionuevo et al., 2006), perhaps due to lack of matrix formation within the notochordal sheath. Absence of the notochord and associated signaling henceforth impairs development of the sclerotome (Barrionuevo et al., 2006).

TGFβ signaling has also been implicated in the metameric patterning of the discs and vertebral bodies. TGFβ signaling is important for regulating cell proliferation and differentiation, and extracellular matrix production during skeletal development, with different TGFβ isoforms exhibiting tissue-specific expression profiles (Millan et al., 1991). TGFβ3 has been shown to be strongly localized to the perichordal condensations that give rise to the AF and vertebral bodies. As condensation advances, this expression pattern becomes localized to the disc anlagen, showing clear demarcation with respect to the adjacent vertebral bodies (Pelton et al., 1990). Conditional deletion of TGFβ receptor 2 (TGFβ-r2) in cells expressing collagen II results in incomplete formation of the NP and inner AF, and partial mineralization of the disc region. Cells in the AF exhibit a more chondrogenic phenotype and are poorly organized. This suggests that TGFβ-r2 plays a role both in defining the boundaries between the disc and the vertebral bodies, and in defining and maintaining AF cell phenotype and organization (Baffi et al., 2006; Baffi et al., 2004; Sohn et al., 2010). There is evidence that disc cells continue to respond to TGFβ signaling during postnatal growth (Dahia et al., 2009).

Postnatal vascular regression

Poor nutritional supply to the cells of the avascular intervertebral disc has been implicated in the pathogenesis of degeneration with age. In humans, during the early postnatal years, blood vessels that have penetrated the AF and cartilage endplates from as early as 35 weeks gestation begin to recede, eventually leaving the disc as a completely avascular structure (Nerlich et al., 2007; Urban and Roberts, 1995). Possible reasons for vascular regression include decreased nutrient requirements following the initial period of rapid growth or, more likely, the inability of circulatory pressure to compete with large physiological stresses in the surrounding extracellular matrix. Following regression, there is evidence that the pathways followed by blood vessels are never fully remodeled into the surrounding microarchitecture, and that they remain as translamellar bridging elements (Melrose et al., 2008; Smith et al., 2010); this idea is consistent with the fact that the disc has a poor ability to remodel and repair (Buckwalter, 1995). It is likely that these vascular remnants influence AF mechanics in response to radial and shear deformations; however, it is unclear whether this influence would assist or impair the function of the disc.

Changing NP cell phenotype

As discussed above, altered cellularity is a hallmark of disc degeneration. In fact, changes to the resident cell populations, and specifically to those of the NP, begin to occur very early in life. Soon after birth, the cells that populate the NP exhibit morphological characteristics that are similar to the cells that populate its notochord precursor (Peacock, 1952; Wolfe et al., 1965; Trout et al., 1982a; Trout et al., 1982b). Because of these similarities, these cells have classically been referred to as ‘notochordal-like’ in reference to their putative origin. Notochordal-like cells in the postnatal NP are large (30–40 μm in diameter), frequently appear in clusters and possess actin-filament-bounded intracellular vacuoles that occupy more than 25% of the cell area (Hunter et al., 2003b; Hunter et al., 2004). These vacuoles are a trait common to cells of the embryonic notochord; here, they seem to contain secreted glycosaminoglycans, enabling the cells to generate an osmotic swelling pressure that contributes to the elongation and straightening of the notochord (Adams et al., 1990).

In the first 10 years following birth, the number of notochordal-like cells declines, and eventually these cells disappear (Peacock, 1952; Trout et al., 1982a; Hunter et al., 2004). Concurrently, a second population of smaller cells appears, classically referred to as ‘chondrocyte-like’ owing to apparent phenotypic and morphological similarities with cartilage chondrocytes (Urban and Roberts, 1995). Hereafter, these cells will be referred to as ‘mature NP cells’ because they should not be confused with cartilage chondrocytes. In comparison with notochordal-like cells, the mature NP cells are smaller (∼10 μm in diameter) and lack intracellular vacuoles (Hunter et al., 2004).

The rate at which the transition between cell types occurs varies by species: in humans, notochordal-like NP cells persist only for the first few years of life and have long disappeared by skeletal maturity. In other species, such as rats, these cells persist well beyond skeletal maturity (Hunter et al., 2003a; Hunter et al., 2004). The origin of mature NP cells has been the subject of debate (Risbud et al., 2010; Shapiro and Risbud, 2010): whereas some studies suggest that these cells are recruited from adjacent tissues such as the endplates (Kim et al., 2003), there is a solid and growing body of experimental evidence that all cell types within the adult NP are descended directly from the embryonic notochord (Risbud et al., 2010). A recent study used tamoxifen-inducible Shh-Cre-ERT2 mice to fate map descendents of embryonic notochord cells, exploiting the fact that these cells express Shh, whereas those of the sclerotome do not (Choi et al., 2008). The results clearly demonstrated that all cell types resident in the adult mouse NP are descended directly from the notochord.

Notochordal-like cells and mature NP cells exhibit some gene-expression profile similarities, and also some differences. Although both cell types have been found to express the typical chondrogenic markers aggrecan, collagen II and Sox9 to a similar extent (Chen et al., 2006; Kim et al., 2009; Sive et al., 2002), the relative expression of collagen I, as well as biglycan, decorin and lumican, which are small leucine-rich proteoglycans that are important for collagen fibrillogenesis, is higher for mature NP cells than notochordal cells (Chen et al., 2006). Expression of these factors is consistent with the extracellular matrix changes that are observed with aging and a transition to a more fibrous structure. Putative markers of mature NP cells – such as cytokeratins 8, 18 and 19, snaptosomal-associated protein 25 (SNAP-25), cadherin-2 and sclerostin domain-containing protein 1 (SOSTDC1) – are all also expressed by notochordal-like cells, in many cases at higher levels (Minogue et al., 2010). There is some evidence, however, that the overall number of cells expressing these markers decreases after 30 years of age (Weiler et al., 2010). Expression of the embryonic notochordal cell marker brachyury (T) by both notochordal-like and mature NP cells has been suggested to indicate their common notochordal lineage (Minogue et al., 2010).

The factors that underlie the transition in NP cell type are not well understood; however, changes to both the mechanical and nutritional microenvironment have been implicated. Mechanical forces within the disc increase considerably after birth, particularly with the onset of bipedal locomotion. It is possible that this additional mechanical stress induces apoptosis or chondrogenic-like differentiation of notochordal cells. Indeed, compressive loading has been shown to mediate chondrogenic differentiation of other cell types, such as mesenchymal stem cells (Huang et al., 2010). Compressive loading in a rabbit model decreased the number of notochordal-like cells and increased the number of mature NP cells (Guehring et al., 2010). Cells of the NP must survive and function in a low nutrient and low oxygen environment, which becomes progressively moreso following postnatal vascular regression. Furthermore, as a result of their higher metabolic activity, the nutritional requirements of notochordal-like cells are significantly greater than those of mature NP cells (Guehring et al., 2009). A low nutrient environment might therefore induce notochordal-like cell apoptosis or differentiation towards a cellular phenotype with a lower nutrient demand (Rastogi et al., 2009).

Matrix synthesis

A key factor in early disc degeneration is the decrease in NP proteoglycan content. Notochordal-like cells have been shown to synthesize matrix in a manner distinct from mature NP cells (Cappello et al., 2006). Proteoglycans synthesized by notochordal-like cells are evenly distributed between the inter- and pericellular regions, compared with mature NP cells, in which the majority of proteoglycans are intercellular. Additionally, the rate at which proteoglycans migrate to the intercellular regions is significantly greater for notochordal-like cells than for mature NP cells (Cappello et al., 2006).

The matrix-producing potential of notochordal-like cells in vitro seems to be enhanced in a low oxygen environment that replicates that of the native tissue (Erwin et al., 2009). Notochordal-like cells can influence the matrix-synthesis behavior of mature NP cells (Aguiar et al., 1999; Erwin et al., 2006; Erwin and Inman, 2006). Co-culture of bovine mature NP cells and canine notochordal-like cells results in significantly higher levels of proteoglycan synthesis than for either of these cell types in isolation (Aguiar et al., 1999). Canine notochordal-like cells have been shown to secrete connective tissue growth factor (CTGF) in culture (Erwin et al., 2006). Bovine mature NP cells cultured in notochordal-like cell conditioned medium exhibit increased expression of aggrecan in a dose-dependent manner, a result replicated by recombinant CTGF-supplemented medium (Erwin and Inman, 2006). Notochordal-like cells also seem to have the capacity to mediate the matrix-production characteristics of non-NP cell types. Mesenchymal stem cells cultured in media conditioned using porcine notochordal-like cells synthesize higher quantities of glycosaminoglycans than those cultured either without conditioned media or in the presence of TGFβ3 (Korecki et al., 2010).

Improving treatments for disc degeneration: lessons from development

Through identification of important growth factors and transcriptional regulators that are present during the progressive conversion from notochord and sclerotome cells to mature NP and AF cells, respectively, it might be possible to target and modulate specific genes associated with cell survival, differentiation and matrix deposition to advance biological therapies for disc degeneration. For example, the expression of TGFβ3 in perichordal condensations of AF progenitor cells during AF morphogenesis suggests that this molecule is a promising candidate for restoration of AF architecture and function following degeneration-associated tears and fissures. Indeed, organ culture studies of rat intervertebral discs identified that TGFβ3 improved cell viability and matrix retention in vitro (Risbud et al., 2006). In addition, application of TGFβ3 to adult bovine AF cells cultured on electrospun nanofibrous polymer scaffolds resulted in robust extracellular matrix production and improved mechanical properties in vitro (Nerurkar et al., 2007). This approach was recently employed to generate nanofibrous biologic laminates that replicated the angle-ply form and mechanical function of the native AF (Nerurkar et al., 2009).

The transcription factor Sox9, which is associated with chondrogenic differentiation and collagen II synthesis, is expressed throughout the disc structures during embryogenesis (Barrionuevo et al., 2006) and in the newborn AF (Gruber et al., 2005). A decrease in Sox9 expression has been associated with disc degeneration (Gruber et al., 2005), suggesting that it could also be a potential therapeutic target. Indeed, preliminary studies investigating the use of Sox9 gene therapy support this idea: transduced cells from degenerate human discs showed enhanced collagen II production (Paul et al., 2003). These results support the future therapeutic potential of this and other transcriptional regulators, although associations between disc degeneration and altered expression of many of these factors remain to be elucidated.

Recent advances in notochordal cell biology have demonstrated that these cells, through secretion of factors such as CTGF, can enhance matrix synthesis by other cell types, and even direct mesenchymal stem cells towards an NP-cell-like phenotype (Korecki et al., 2010). Such cellular conditioning has the potential to optimize the phenotype of cells used in both NP cell therapy and in NP tissue engineering.

As our understanding of the physical forces associated with disc development improves, it will be possible to tailor therapeutic approaches such that AF and NP tissue engineering might become distinguished from ligament and cartilage tissue engineering, respectively. At present, however, little is known about the role of these forces, either in the segmentation of the notochord and its transformation into the NP, or in the generation of an angle-ply alignment in the AF. Most NP tissue engineering endeavors have relied on entrapping cells within hydrogel scaffolds to maintain the rounded cell morphology present in vivo (O’Halloran and Pandit, 2007; Yang and Li, 2009). Additionally, motivated by the large swelling pressure in the notochord and later in the NP, studies have shown that hydrostatic pressure can modulate the phenotype and matrix production of mature NP cells when encapsulated in hydrogels (Hutton et al., 1999; Kasra et al., 2006). On the basis of the observation that cell alignment in the developing AF precedes ordered matrix deposition, some tissue engineering strategies have focused first on aligning cells, either through the use of microgrooved channels (Johnson et al., 2006) or aligned scaffolds (Mauck et al., 2009). Furthermore, studies have demonstrated that, similarly to the process in the developing AF, alignment of AF cells results in deposition of aligned collagen as well (Johnson et al., 2006; Nerurkar et al., 2008). In the future, it might be possible to design and implement deformational loading bioreactors that are specifically tailored to recapitulate the physical environment of the developing spine.

Future directions

Despite many years of research, the etiology of discogenic low back pain remains poorly understood, and palliative therapies do not restore healthy disc structure or mechanical function. Development of the intervertebral disc involves the coalescence of different cell types under the direction of complex molecular interactions. The resulting structures must function synergistically in an environment that is subjected to continuous mechanical perturbation and in the presence of poor nutrient supply, throughout the lifetime of an individual. It is likely that early postnatal changes, including vascular regression, altered NP cell phenotype and altered extracellular matrix composition, despite representing a necessary adaptation to a changing biochemical and biomechanical microenvironment, set the disc on a slow but relentless course towards degeneration. Future work in this area should build on current understanding in order to establish the mechanisms by which postnatal changes affect disc degeneration, as well as establishing the direct consequences of altered extracellular matrix synthesis and molecular signaling on this process. Improved understanding of these factors will lay the foundation for the emergence of exciting new regenerative or reparative biological treatments for this debilitating condition.

Acknowledgments

L.J.S., N.L.N. and D.M.E. were supported by grants AR055568-S1, EB02425 and AR050950 from the NIH, and by the Penn Center for Musculoskeletal Disorders. B.D.H. and K-S.C. were supported by grants AG029353 and AR055568 from the NIH. The authors thank Jonathon Yoder and Sung Moon for obtaining the MRI images included in this paper.

Footnotes

COMPETING INTERESTS

The authors declare no competing or financial interests.

REFERENCES

  1. Acaroglu E.R., Iatridis J.C., Setton L.A., Foster R.J., Mow V.C., Weidenbaum M. (1995). Degeneration and aging affect the tensile behavior of human lumbar anulus fibrosus. Spine 20, 2690–2701 [DOI] [PubMed] [Google Scholar]
  2. Adams D.S., Keller R., Koehl M.A. (1990). The mechanics of notochord elongation, straightening and stiffening in the embryo of Xenopus laevis. Development 110, 115–130 [DOI] [PubMed] [Google Scholar]
  3. Adams M.A., Roughley P.J. (2006). What is intervertebral disc degeneration, and what causes it? Spine 31, 2151–2161 [DOI] [PubMed] [Google Scholar]
  4. Adams M.A., McNally D.S., Dolan P. (1996). ‘Stress’ distributions inside intervertebral discs. The effects of age and degeneration. J. Bone Joint Surg. Br. 78, 965–972 [DOI] [PubMed] [Google Scholar]
  5. Aguiar D.J., Johnson S.L., Oegema T.R. (1999). Notochordal cells interact with nucleus pulposus cells: regulation of proteoglycan synthesis. Exp. Cell Res. 246, 129–137 [DOI] [PubMed] [Google Scholar]
  6. Alini M., Eisenstein S.M., Ito K., Little C., Kettler A.A., Masuda K., Melrose J., Ralphs J., Stokes I., Wilke H.J. (2008). Are animal models useful for studying human disc disorders/degeneration? Eur. Spine J. 17, 2–19 [DOI] [PMC free article] [PubMed] [Google Scholar]
  7. Andersson G.B. (1999). Epidemiological features of chronic low-back pain. Lancet 354, 581–585 [DOI] [PubMed] [Google Scholar]
  8. Antoniou J., Steffen T., Nelson F., Winterbottom N., Hollander A.P., Poole R.A., Aebi M., Alini M. (1996). The human lumbar intervertebral disc: evidence for changes in the biosynthesis and denaturation of the extracellular matrix with growth, maturation, ageing, and degeneration. J. Clin. Invest. 98, 996–1003 [DOI] [PMC free article] [PubMed] [Google Scholar]
  9. Aszodi A., Chan D., Hunziker E., Bateman J.F., Fassler R. (1998). Collagen II is essential for the removal of the notochord and the formation of intervertebral discs. J. Cell Biol. 143, 1399–1412 [DOI] [PMC free article] [PubMed] [Google Scholar]
  10. Baffi M.O., Slattery E., Sohn P., Moses H.L., Chytil A., Serra R. (2004). Conditional deletion of the TGF-beta type II receptor in Col2a expressing cells results in defects in the axial skeleton without alterations in chondrocyte differentiation or embryonic development of long bones. Dev. Biol. 276, 124–142 [DOI] [PubMed] [Google Scholar]
  11. Baffi M.O., Moran M.A., Serra R. (2006). Tgfbr2 regulates the maintenance of boundaries in the axial skeleton. Dev. Biol. 296, 363–374 [DOI] [PMC free article] [PubMed] [Google Scholar]
  12. Barrionuevo F., Taketo M.M., Scherer G., Kispert A. (2006). Sox9 is required for notochord maintenance in mice. Dev. Biol. 295, 128–140 [DOI] [PubMed] [Google Scholar]
  13. Battie M.C., Videman T. (2006). Lumbar disc degeneration: epidemiology and genetics. J. Bone Joint Surg. Am. 88, 3–9 [DOI] [PubMed] [Google Scholar]
  14. Beckstein J.C., Sen S., Schaer T.P., Vresilovic E.J., Elliott D.M. (2008). Comparison of animal discs used in disc research to human lumbar disc: axial compression mechanics and glycosaminoglycan content. Spine 33, E166–E173 [DOI] [PubMed] [Google Scholar]
  15. Bi W., Deng J.M., Zhang Z., Behringer R.R., de Crombrugghe B. (1999). Sox9 is required for cartilage formation. Nat. Genet. 22, 85–89 [DOI] [PubMed] [Google Scholar]
  16. Bogduk N. (1991). The lumbar disc and low back pain. Neurosurg. Clin. N. Am. 2, 791–806 [PubMed] [Google Scholar]
  17. Boos N., Weissbach S., Rohrbach H., Weiler C., Spratt K.F., Nerlich A.G. (2002). Classification of age-related changes in lumbar intervertebral discs: 2002 Volvo Award in basic science. Spine 27, 2631–2644 [DOI] [PubMed] [Google Scholar]
  18. Bowles R.D., Williams R.M., Zipfel W.R., Bonassar L.J. (2010). Self-assembly of aligned tissue-engineered annulus fibrosus and intervertebral disc composite via collagen gel contraction. Tissue Eng. Part A. 16, 1339–1348 [DOI] [PMC free article] [PubMed] [Google Scholar]
  19. Boxberger J.I., Sen S., Yerramalli C.S., Elliott D.M. (2006). Nucleus pulposus glycosaminoglycan content is correlated with axial mechanics in rat lumbar motion segments. J. Orthop. Res. 24, 1906–1915 [DOI] [PubMed] [Google Scholar]
  20. Boxberger J.I., Auerbach J.D., Sen S., Elliott D.M. (2008). An in vivo model of reduced nucleus pulposus glycosaminoglycan content in the rat lumbar intervertebral disc. Spine 33, 146–154 [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Bruehlmann S.B., Rattner J.B., Matyas J.R., Duncan N.A. (2002). Regional variations in the cellular matrix of the annulus fibrosus of the intervertebral disc. J. Anat. 201, 159–171 [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. Buckwalter J.A. (1995). Aging and degeneration of the human intervertebral disc. Spine 20, 1307–1314 [DOI] [PubMed] [Google Scholar]
  23. Cappello R., Bird J.L., Pfeiffer D., Bayliss M.T., Dudhia J. (2006). Notochordal cell produce and assemble extracellular matrix in a distinct manner, which may be responsible for the maintenance of healthy nucleus pulposus. Spine 31, 873–882 [DOI] [PubMed] [Google Scholar]
  24. Cassidy J.J., Hiltner A., Baer E. (1989). Hierarchical structure of the intervertebral disc. Connect. Tissue Res. 23, 75–88 [DOI] [PubMed] [Google Scholar]
  25. Chan D., Song Y., Sham P., Cheung K.M. (2006). Genetics of disc degeneration. Eur. Spine J. 15, S317–S325 [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Chen J., Yan W., Setton L.A. (2006). Molecular phenotypes of notochordal cells purified from immature nucleus pulposus. Eur. Spine J. 15, S303–S311 [DOI] [PMC free article] [PubMed] [Google Scholar]
  27. Choi K.S., Cohn M.J., Harfe B.D. (2008). Identification of nucleus pulposus precursor cells and notochordal remnants in the mouse: implications for disk degeneration and chordoma formation. Dev. Dyn. 237, 3953–3958 [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Costi J.J., Stokes I.A., Gardner-Morse M.G., Iatridis J.C. (2008). Frequency-dependent behavior of the intervertebral disc in response to each of six degree of freedom dynamic loading: solid phase and fluid phase contributions. Spine 33, 1731–1738 [DOI] [PMC free article] [PubMed] [Google Scholar]
  29. Dahia C.L., Mahoney E.J., Durrani A.A., Wylie C. (2009). Intercellular signaling pathways active during intervertebral disc growth, differentiation, and aging. Spine 34, 456–462 [DOI] [PubMed] [Google Scholar]
  30. DiPaola C.P., Farmer J.C., Manova K., Niswander L.A. (2005). Molecular signaling in intervertebral disk development. J. Orthop. Res. 23, 1112–1119 [DOI] [PubMed] [Google Scholar]
  31. Ehlen H.W., Buelens L.A., Vortkamp A. (2006). Hedgehog signaling in skeletal development. Birth Defects Res. C Embryo Today 78, 267–279 [DOI] [PubMed] [Google Scholar]
  32. Elliott D.M., Yerramalli C.S., Beckstein J.C., Boxberger J.I., Johannessen W., Vresilovic E.J. (2008). The effect of relative needle diameter in puncture and sham injection animal models of degeneration. Spine 33, 588–596 [DOI] [PubMed] [Google Scholar]
  33. Erwin W.M., Inman R.D. (2006). Notochord cells regulate intervertebral disc chondrocyte proteoglycan production and cell proliferation. Spine 31, 1094–1099 [DOI] [PubMed] [Google Scholar]
  34. Erwin W.M., Ashman K., O’Donnel P., Inman R.D. (2006). Nucleus pulposus notochord cells secrete connective tissue growth factor and up-regulate proteoglycan expression by intervertebral disc chondrocytes. Arthritis Rheum. 54, 3859–3867 [DOI] [PubMed] [Google Scholar]
  35. Erwin W.M., Las Heras F., Islam D., Fehlings M.G., Inman R.D. (2009). The regenerative capacity of the notochordal cell: tissue constructs generated in vitro under hypoxic conditions. J. Neurosurg. Spine 10, 513–521 [DOI] [PubMed] [Google Scholar]
  36. Fan C.M., Tessier-Lavigne M. (1994). Patterning of mammalian somites by surface ectoderm and notochord: evidence for sclerotome induction by a hedgehog homolog. Cell 79, 1175–1186 [DOI] [PubMed] [Google Scholar]
  37. Fleming A., Keynes R.J., Tannahill D. (2001). The role of the notochord in vertebral column formation. J. Anat. 199, 177–180 [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Freemont A.J. (2009). The cellular pathobiology of the degenerate intervertebral disc and discogenic back pain. Rheumatology 48, 5–10 [DOI] [PubMed] [Google Scholar]
  39. Frost V., Grocott T., Eccles M.R., Chantry A. (2008). Self-regulated Pax gene expression and modulation by the TGFbeta superfamily. Crit. Rev. Biochem. Mol. Biol. 43, 371–391 [DOI] [PubMed] [Google Scholar]
  40. Furumoto T.A., Miura N., Akasaka T., Mizutani-Koseki Y., Sudo H., Fukuda K., Maekawa M., Yuasa S., Fu Y., Moriya H., et al. (1999). Notochord-dependent expression of MFH1 and PAX1 cooperates to maintain the proliferation of sclerotome cells during the vertebral column development. Dev. Biol. 210, 15–29 [DOI] [PubMed] [Google Scholar]
  41. Ghiselli G., Wang J.C., Bhatia N.N., Hsu W.K., Dawson E.G. (2004). Adjacent segment degeneration in the lumbar spine. J. Bone Joint Surg. Am. 86, 1497–1503 [DOI] [PubMed] [Google Scholar]
  42. Gruber H.E., Johnson T., Norton H.J., Hanley E.N., Jr (2002). The sand rat model for disc degeneration: radiologic characterization of age-related changes: cross-sectional and prospective analyses. Spine 27, 230–234 [DOI] [PubMed] [Google Scholar]
  43. Gruber H.E., Norton H.J., Ingram J.A., Hanley E.N. (2005). The SOX9 transcription factor in the human disc: decreased immunolocalization with age and disc degeneration. Spine 30, 625–630 [DOI] [PubMed] [Google Scholar]
  44. Guehring T., Wilde G., Sumner M., Grunhagen T., Karney G.B., Tirlapur U.K., Urban J.P. (2009). Notochordal intervertebral disc cells: sensitivity to nutrient deprivation. Arthritis Rheum. 60, 1026–1034 [DOI] [PubMed] [Google Scholar]
  45. Guehring T., Nerlich A., Kroeber M., Richter W., Omlor G.W. (2010). Sensitivity of notochordal disc cells to mechanical loading: an experimental animal study. Eur. Spine J. 19, 113–121 [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Guerin H.L., Elliott D.M. (2007). Quantifying the contributions of structure to annulus fibrosus mechanical function using a nonlinear, anisotropic, hyperelastic model. J. Orthop. Res. 25, 508–516 [DOI] [PubMed] [Google Scholar]
  47. Hanley E.N., Jr, Herkowitz H.N., Kirkpatrick J.S., Wang J.C., Chen M.N., Kang J.D. (2010). Debating the value of spine surgery. J. Bone Joint Surg. Am. 92, 1293–1304 [DOI] [PubMed] [Google Scholar]
  48. Hansen H.J. (1952). A pathologic-anatomical interpretation of disc degeneration in dogs. Acta Orthop. Scand. 20, 280–293 [DOI] [PubMed] [Google Scholar]
  49. Hayes A.J., Benjamin M., Ralphs J.R. (1999). Role of actin stress fibres in the development of the intervertebral disc: cytoskeletal control of extracellular matrix assembly. Dev. Dyn. 215, 179–189 [DOI] [PubMed] [Google Scholar]
  50. Heuer F., Schmidt H., Wilke H.J. (2008). Stepwise reduction of functional spinal structures increase disc bulge and surface strains. J. Biomech. 41, 1953–1960 [DOI] [PubMed] [Google Scholar]
  51. Hoogendoorn R.J., Wuisman P.I., Smit T.H., Everts V.E., Helder M.N. (2007). Experimental intervertebral disc degeneration induced by chondroitinase ABC in the goat. Spine 32, 1816–1825 [DOI] [PubMed] [Google Scholar]
  52. Huang A.H., Farrell M.J., Kim M., Mauck R.L. (2010). Long-term dynamic loading improves the mechanical properties of chondrogenic mesenchymal stem cell-laden hydrogel. Eur. Cell Mater. 19, 72–85 [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Humzah M.D., Soames R.W. (1988). Human intervertebral disc: structure and function. Anat. Rec. 220, 337–356 [DOI] [PubMed] [Google Scholar]
  54. Hunter C.J., Matyas J.R., Duncan N.A. (2003a). The notochordal cell in the nucleus pulposus: a review in the context of tissue engineering. Tissue Eng. 9, 667–677 [DOI] [PubMed] [Google Scholar]
  55. Hunter C.J., Matyas J.R., Duncan N.A. (2003b). The three-dimensional architecture of the notochordal nucleus pulposus: novel observations on cell structures in the canine intervertebral disc. J. Anat. 202, 279–291 [DOI] [PMC free article] [PubMed] [Google Scholar]
  56. Hunter C.J., Matyas J.R., Duncan N.A. (2004). Cytomorphology of notochordal and chondrocytic cells from the nucleus pulposus: a species comparison. J. Anat. 205, 357–362 [DOI] [PMC free article] [PubMed] [Google Scholar]
  57. Hutton W.C., Elmer W.A., Boden S.D., Hyon S., Toribatake Y., Tomita K., Hair G.A. (1999). The effect of hydrostatic pressure on intervertebral disc metabolism. Spine 24, 1507–1515 [DOI] [PubMed] [Google Scholar]
  58. Iatridis J.C., Mente P.L., Stokes I.A., Aronsson D.D., Alini M. (1999). Compression-induced changes in intervertebral disc properties in a rat tail model. Spine 24, 996–1002 [DOI] [PubMed] [Google Scholar]
  59. Johannessen W., Cloyd J.M., O’Connell G.D., Vresilovic E.J., Elliott D.M. (2006). Trans-endplate nucleotomy increases deformation and creep response in axial loading. Ann. Biomed. Eng. 34, 687–696 [DOI] [PubMed] [Google Scholar]
  60. Johnson W.E., Wootton A., El Haj A., Eisenstein S.M., Curtis A.S., Roberts S. (2006). Topographical guidance of intervertebral disc cell growth in vitro: towards the development of tissue repair strategies for the anulus fibrosus. Eur. Spine J. 15, S389–S396 [DOI] [PMC free article] [PubMed] [Google Scholar]
  61. Kandel R., Roberts S., Urban J.P. (2008). Tissue engineering and the intervertebral disc: the challenges. Eur. Spine J. 17, 480–491 [DOI] [PMC free article] [PubMed] [Google Scholar]
  62. Kasra M., Merryman W.D., Loveless K.N., Goel V.K., Martin J.D., Buckwalter J.A. (2006). Frequency response of pig intervertebral disc cells subjected to dynamic hydrostatic pressure. J. Orthop. Res. 24, 1967–1973 [DOI] [PubMed] [Google Scholar]
  63. Katz J.N. (2006). Lumbar disc disorders and low-back pain: socioeconomic factors and consequences. J. Bone Joint Surg. Am. 88, 21–24 [DOI] [PubMed] [Google Scholar]
  64. Kim J.H., Deasy B.M., Seo H.Y., Studer R.K., Vo N.V., Georgescu H.I., Sowa G.A., Kang J.D. (2009). Differentiation of intervertebral notochordal cells through live automated cell imaging system in vitro. Spine 34, 2486–2493 [DOI] [PubMed] [Google Scholar]
  65. Kim K.W., Lim T.H., Kim J.G., Jeong S.T., Masuda K., An H.S. (2003). The origin of chondrocytes in the nucleus pulposus and histologic findings associated with the transition of a notochordal nucleus pulposus to a fibrocartilaginous nucleus pulposus in intact rabbit intervertebral discs. Spine 28, 982–990 [DOI] [PubMed] [Google Scholar]
  66. Korecki C.L., Taboas J.M., Tuan R.S., Iatridis J.C. (2010). Notochordal cell conditioned medium stimulates mesenchymal stem cell differentiation toward a young nucleus pulposus phenotype. Stem Cell Res. Ther. 1, 18. [DOI] [PMC free article] [PubMed] [Google Scholar]
  67. Kroeber M.W., Unglaub F., Wang H., Schmid C., Thomsen M., Nerlich A., Richter W. (2002). New in vivo animal model to create intervertebral disc degeneration and to investigate the effects of therapeutic strategies to stimulate disc regeneration. Spine 27, 2684–2690 [DOI] [PubMed] [Google Scholar]
  68. Le Maitre C.L., Pockert A., Buttle D.J., Freemont A.J., Hoyland J.A. (2007). Matrix synthesis and degradation in human intervertebral disc degeneration. Biochem. Soc. Trans. 35, 652–655 [DOI] [PubMed] [Google Scholar]
  69. Leung V.Y., Chan D., Cheung K.M. (2006). Regeneration of intervertebral disc by mesenchymal stem cells: potentials, limitations, and future direction. Eur. Spine J. 15, S406–S413 [DOI] [PMC free article] [PubMed] [Google Scholar]
  70. Maclean J.J., Lee C.R., Alini M., Iatridis J.C. (2004). Anabolic and catabolic mRNA levels of the intervertebral disc vary with the magnitude and frequency of in vivo dynamic compression. J. Orthop. Res. 22, 1193–1200 [DOI] [PubMed] [Google Scholar]
  71. Marchand F., Ahmed A.M. (1990). Investigation of the laminate structure of lumbar disc anulus fibrosus. Spine 15, 402–410 [DOI] [PubMed] [Google Scholar]
  72. Maroudas A., Stockwell R.A., Nachemson A., Urban J. (1975). Factors involved in the nutrition of the human lumbar intervertebral disc: cellularity and diffusion of glucose in vitro. J. Anat. 120, 113–130 [PMC free article] [PubMed] [Google Scholar]
  73. Masuda K. (2008). Biological repair of the degenerated intervertebral disc by the injection of growth factors. Eur. Spine J. 17, 441–451 [DOI] [PMC free article] [PubMed] [Google Scholar]
  74. Mauck R.L., Baker B.M., Nerurkar N.L., Burdick J.A., Li W.J., Tuan R.S., Elliott D.M. (2009). Engineering on the straight and narrow: the mechanics of nanofibrous assemblies for fiber-reinforced tissue regeneration. Tissue Eng. Part B Rev. 15, 171–193 [DOI] [PMC free article] [PubMed] [Google Scholar]
  75. McMahon A.P., Ingham P.W., Tabin C.J. (2003). Developmental roles and clinical significance of hedgehog signaling. Curr. Top. Dev. Biol. 53, 1–114 [DOI] [PubMed] [Google Scholar]
  76. McMahon J.A., Takada S., Zimmerman L.B., Fan C.M., Harland R.M., McMahon A.P. (1998). Noggin-mediated antagonism of BMP signaling is required for growth and patterning of the neural tube and somite. Genes Dev. 12, 1438–1452 [DOI] [PMC free article] [PubMed] [Google Scholar]
  77. Melrose J., Smith S.M., Appleyard R.C., Little C.B. (2008). Aggrecan, versican and type VI collagen are components of annular translamellar crossbridges in the intervertebral disc. Eur. Spine J. 17, 314–324 [DOI] [PMC free article] [PubMed] [Google Scholar]
  78. Millan F.A., Denhez F., Kondaiah P., Akhurst R.J. (1991). Embryonic gene expression patterns of TGF beta 1, beta 2 and beta 3 suggest different developmental functions in vivo. Development 111, 131–143 [DOI] [PubMed] [Google Scholar]
  79. Miller J.A.A., Schmatz C., Schultz A.B. (1988). Lumbar disc degeneration: correlation with age, sex and spine level in 600 autopsy specimens. Spine 13, 173–178 [PubMed] [Google Scholar]
  80. Minogue B.M., Richardson S.M., Zeef L.A., Freemont A.J., Hoyland J.A. (2010). Transcriptional profiling of bovine intervertebral disc cells: implications for identification of normal and degenerate human intervertebral disc cell phenotypes. Arthritis Res. Ther. 12, R22. [DOI] [PMC free article] [PubMed] [Google Scholar]
  81. Mirza S.K., Deyo R.A. (2007). Systematic review of randomized trials comparing lumbar fusion surgery to nonoperative care for treatment of chronic back pain. Spine 32, 816–823 [DOI] [PubMed] [Google Scholar]
  82. Mizuno H., Roy A.K., Zaporojan V., Vacanti C.A., Ueda M., Bonassar L.J. (2006). Biomechanical and biochemical characterization of composite tissue-engineered intervertebral discs. Biomaterials 27, 362–370 [DOI] [PubMed] [Google Scholar]
  83. Nerlich A.G., Schaaf R., Walchli B., Boos N. (2007). Temporo-spatial distribution of blood vessels in human lumbar intervertebral discs. Eur. Spine J. 16, 547–555 [DOI] [PMC free article] [PubMed] [Google Scholar]
  84. Nerurkar N.L., Elliott D.M., Mauck R.L. (2007). Mechanics of oriented electrospun nanofibrous scaffolds for annulus fibrosus tissue engineering. J. Orthop. Res. 25, 1018–1028 [DOI] [PubMed] [Google Scholar]
  85. Nerurkar N.L., Mauck R.L., Elliott D.M. (2008). ISSLS prize winner: integrating theoretical and experimental methods for functional tissue engineering of the annulus fibrosus. Spine 33, 2691–2701 [DOI] [PMC free article] [PubMed] [Google Scholar]
  86. Nerurkar N.L., Baker B.M., Sen S., Wible E.E., Elliott D.M., Mauck R.L. (2009). Nanofibrous biologic laminates replicate the form and function of the annulus fibrosus. Nat. Mater. 8, 986–992 [DOI] [PMC free article] [PubMed] [Google Scholar]
  87. Nerurkar N.L., Elliott D.M., Mauck R.L. (2010). Mechanical design criteria for intervertebral disc tissue engineering. J. Biomech. 43, 1017–1030 [DOI] [PMC free article] [PubMed] [Google Scholar]
  88. Nesti L.J., Li W.J., Shanti R.M., Jiang Y.J., Jackson W., Freedman B.A., Kuklo T.R., Giuliani J.R., Tuan R.S. (2008). Intervertebral disc tissue engineering using a novel hyaluronic acid-nanofibrous scaffold (HANFS) amalgam. Tissue Eng. Part A 14, 1527–1537 [DOI] [PMC free article] [PubMed] [Google Scholar]
  89. O’Connell G.D., Johannessen W., Vresilovic E.J., Elliott D.M. (2007a). Human internal disc strains in axial compression measured noninvasively using magnetic resonance imaging. Spine 32, 2860–2868 [DOI] [PubMed] [Google Scholar]
  90. O’Connell G.D., Vresilovic E.J., Elliott D.M. (2007b). Comparison of animals used in disc research to human lumbar disc geometry. Spine 32, 328–333 [DOI] [PubMed] [Google Scholar]
  91. O’Connell G.D., Guerin H.L., Elliott D.M. (2009). Theoretical and experimental evaluation of human annulus fibrosus degeneration. J. Biomech. Eng. 131, 111007. [DOI] [PMC free article] [PubMed] [Google Scholar]
  92. O’Halloran D.M., Pandit A.S. (2007). Tissue-engineering approach to regenerating the intervertebral disc. Tissue Eng. 13, 1927–1954 [DOI] [PubMed] [Google Scholar]
  93. Paul R., Haydon R.C., Cheng H., Ishikawa A., Nenadovich N., Jiang W., Zhou L., Breyer B., Feng T., Gupta P., et al. (2003). Potential use of Sox9 gene therapy for intervertebral degenerative disc disease. Spine 28, 755–763 [PMC free article] [PubMed] [Google Scholar]
  94. Pazzaglia U.E., Salisbury J.R., Byers P.D. (1989). Development and involution of the notochord in the human spine. J. R. Soc. Med. 82, 413–415 [DOI] [PMC free article] [PubMed] [Google Scholar]
  95. Peacock A. (1951). Observations on the prenatal development of the intervertebral disc in man. J. Anat. 85, 260–274 [PMC free article] [PubMed] [Google Scholar]
  96. Peacock A. (1952). Observations on the postnatal development of the intervertebral disc in man. J. Anat. 86, 162–179 [PMC free article] [PubMed] [Google Scholar]
  97. Pelton R.W., Dickinson M.E., Moses H.L., Hogan B.L. (1990). In situ hybridization analysis of TGF beta 3 RNA expression during mouse development: comparative studies with TGF beta 1 and beta 2. Development 110, 609–620 [DOI] [PubMed] [Google Scholar]
  98. Peters H., Wilm B., Sakai N., Imai K., Maas R., Balling R. (1999). Pax1 and Pax9 synergistically regulate vertebral column development. Development 126, 5399–5408 [DOI] [PubMed] [Google Scholar]
  99. Placzek M. (1995). The role of the notochord and floor plate in inductive interactions. Curr. Opin. Genet. Dev. 5, 499–506 [DOI] [PubMed] [Google Scholar]
  100. Rajasekaran S., Babu J.N., Arun R., Armstrong B.R., Shetty A.P., Murugan S. (2004). ISSLS prize winner: a study of diffusion in human lumbar discs: a serial magnetic resonance imaging study documenting the influence of the endplate on diffusion in normal and degenerate discs. Spine 29, 2654–2667 [DOI] [PubMed] [Google Scholar]
  101. Rastogi A., Thakore P., Leung A., Benavides M., Machado M., Morschauser M.A., Hsieh A.H. (2009). Environmental regulation of notochordal gene expression in nucleus pulposus cells. J. Cell Physiol. 220, 698–705 [DOI] [PubMed] [Google Scholar]
  102. Risbud M.V., Di Martino A., Guttapalli A., Seghatoleslami R., Denaro V., Vaccaro A.R., Albert T.J., Shapiro I.M. (2006). Toward an optimum system for intervertebral disc organ culture: TGF-beta 3 enhances nucleus pulposus and anulus fibrosus survival and function through modulation of TGF-beta-R expression and ERK signaling. Spine 31, 884–890 [DOI] [PubMed] [Google Scholar]
  103. Risbud M.V., Schaer T.P., Shapiro I.M. (2010). Toward an understanding of the role of notochordal cells in the adult intervertebral disc: from discord to accord. Dev. Dyn. 239, 2141–2148 [DOI] [PMC free article] [PubMed] [Google Scholar]
  104. Roughley P.J. (2004). Biology of intervertebral disc aging and degeneration: involvement of the extracellular matrix. Spine 29, 2691–2699 [DOI] [PubMed] [Google Scholar]
  105. Roughley P.J., Melching L.I., Heathfield T.F., Pearce R.H., Mort J.S. (2006). The structure and degradation of aggrecan in human intervertebral disc. Eur Spine J. 15, S326–S332 [DOI] [PMC free article] [PubMed] [Google Scholar]
  106. Rufai A., Benjamin M., Ralphs J.R. (1995). The development of fibrocartilage in the rat intervertebral disc. Anat. Embryol. (Berl.) 192, 53–62 [DOI] [PubMed] [Google Scholar]
  107. Sakai D. (2008). Future perspectives of cell-based therapy for intervertebral disc disease. Eur. Spine J. 17, 452–458 [DOI] [PMC free article] [PubMed] [Google Scholar]
  108. Sambrook P.N., MacGregor A.J., Spector T.D. (1999). Genetic influences on cervical and lumbar disc degeneration: a magnetic resonance imaging study in twins. Arthritis Rheum. 42, 366–372 [DOI] [PubMed] [Google Scholar]
  109. Schepers G.E., Teasdale R.D., Koopman P. (2002). Twenty pairs of sox: extent, homology, and nomenclature of the mouse and human sox transcription factor gene families. Dev. Cell. 3, 167–170 [DOI] [PubMed] [Google Scholar]
  110. Schmidt H., Kettler A., Heuer F., Simon U., Claes L., Wilke H.J. (2007). Intradiscal pressure, shear strain, and fiber strain in the intervertebral disc under combined loading. Spine 32, 748–755 [DOI] [PubMed] [Google Scholar]
  111. Shapiro I.M., Risbud M.V. (2010). Transcriptional profiling of the nucleus pulposus: say yes to notochord. Arthritis Res. Ther. 12, 117. [DOI] [PMC free article] [PubMed] [Google Scholar]
  112. Sive J.I., Baird P., Jeziorsk M., Watkins A., Hoyland J.A., Freemont A.J. (2002). Expression of chondrocyte markers by cells of normal and degenerate intervertebral discs. Mol. Pathol. 55, 91–97 [DOI] [PMC free article] [PubMed] [Google Scholar]
  113. Smith C.A., Tuan R.S. (1994). Human PAX gene expression and development of the vertebral column. Clin. Orthop. Relat. Res. 302, 241–250 [PubMed] [Google Scholar]
  114. Smith L.J., Schaer T., Liechty K., Elliott D.M. (2010). Developmental origins of the annulus fibrosus lamellar cross bridge network. In Transactions of the 56th Annual Meeting of the Orthopaedic Research Society, p. 420 New Orleans, LA [Google Scholar]
  115. Smits P., Lefebvre V. (2003). Sox5 and Sox6 are required for notochord extracellular matrix sheath formation, notochord cell survival and development of the nucleus pulposus of intervertebral discs. Development 130, 1135–1148 [DOI] [PubMed] [Google Scholar]
  116. Sobajima S., Kim J.S., Gilbertson L.G., Kang J.D. (2004). Gene therapy for degenerative disc disease. Gene Ther. 11, 390–401 [DOI] [PubMed] [Google Scholar]
  117. Sohn P., Cox M., Chen D., Serra R. (2010). Molecular profiling of the developing mouse axial skeleton: a role for Tgfbr2 in the development of the intervertebral disc. BMC Dev. Biol. 10, 29. [DOI] [PMC free article] [PubMed] [Google Scholar]
  118. Stemple D.L. (2005). Structure and function of the notochord: an essential organ for chordate development. Development 132, 2503–2512 [DOI] [PubMed] [Google Scholar]
  119. Stokes I.A., Iatridis J.C. (2004). Mechanical conditions that accelerate intervertebral disc degeneration: overload versus immobilization. Spine 29, 2724–2732 [DOI] [PMC free article] [PubMed] [Google Scholar]
  120. Trout J.J., Buckwalter J.A., Moore K.C., Landas S.K. (1982a). Ultrastructure of the human intervertebral disc. I. Changes in notochordal cells with age. Tissue Cell 14, 359–369 [DOI] [PubMed] [Google Scholar]
  121. Trout J.J., Buckwalter J.A., Moore K.C. (1982b). Ultrastructure of the human intervertebral disc. II. Cells of the nucleus pulposus. Anat. Rec. 207, 307–314 [DOI] [PubMed] [Google Scholar]
  122. Urban J. (1996). Disc biochemistry in relation to function. In The Lumbar Spine (ed. Wiesel S.W., Weinstein J.N., Herkowitz H.N., Dvorak J., Bell G.), pp. 271–280 Philadelphia: Saunders [Google Scholar]
  123. Urban J.P., Roberts S. (1995). Development and degeneration of the intervertebral discs. Mol. Med. Today. 1, 329–335 [DOI] [PubMed] [Google Scholar]
  124. Urban J.P., Roberts S. (2003). Degeneration of the intervertebral disc. Arthritis Res. Ther. 5, 120–130 [DOI] [PMC free article] [PubMed] [Google Scholar]
  125. Urban J.P., Smith S., Fairbank J.C. (2004). Nutrition of the intervertebral disc. Spine 29, 2700–2709 [DOI] [PubMed] [Google Scholar]
  126. Urban J.P.G., Roberts S., Ralphs J.R. (2000). The nucleus of the interverterbal disc from development to degeneration. Am. Zool. 40, 53–61 [Google Scholar]
  127. Vernon-Roberts B. (1988). Disc pathology and disease states. In The Biology of the Intervertebral Disc (ed. Ghosh P.), pp. 73–119 CRC Press [Google Scholar]
  128. Videman T., Battie M.C., Gibbons L.E., Maravilla K., Manninen H., Kaprio J. (2003). Associations between back pain history and lumbar MRI findings. Spine 28, 582–588 [DOI] [PubMed] [Google Scholar]
  129. Vresilovic E.J., Johannessen W., Elliott D.M. (2006). Disc mechanics with trans-endplate partial nucleotomy are not fully restored following cyclic compressive loading and unloaded recovery. J. Biomech. Eng. 128, 823–829 [DOI] [PubMed] [Google Scholar]
  130. Wallach C.J., Gilbertson L.G., Kang J.D. (2003). Gene therapy applications for intervertebral disc degeneration. Spine 28, S93–S98 [DOI] [PubMed] [Google Scholar]
  131. Wallin J., Wilting J., Koseki H., Fritsch R., Christ B., Balling R. (1994). The role of Pax-1 in axial skeleton development. Development 120, 1109–1121 [DOI] [PubMed] [Google Scholar]
  132. Walmsley R. (1953). The development and growth of the intervertebral disc. Edinb. Med. J. 60, 341–364 [PMC free article] [PubMed] [Google Scholar]
  133. Walsh A.J., Lotz J.C. (2004). Biological response of the intervertebral disc to dynamic loading. J. Biomech. 37, 329–337 [DOI] [PubMed] [Google Scholar]
  134. Wegner M. (2009). All purpose Sox: The many roles of Sox proteins in gene expression. Int. J. Biochem. Cell Biol. 42, 381–390 [DOI] [PubMed] [Google Scholar]
  135. Weiler C., Nerlich A., Schaaf R., Bachmeier B.E., Wuertz K., Boos N. (2010). Immunohistochemical identification of notochordal cell markers in cells in the aging human lumbar intervertebral disc. Eur. Spine. J. 19, 1761–1770 [DOI] [PMC free article] [PubMed] [Google Scholar]
  136. Wolfe H.J., Pustchar W.G.J., Vickery A.L. (1965). Role of the notochord in human intervertebral disk. I. Human and infant. Clin Orthop Relat Res. 39, 205–212 [PubMed] [Google Scholar]
  137. Yang X., Li X. (2009). Nucleus pulposus tissue engineering: a brief review. Eur. Spine J. 18, 1564–1572 [DOI] [PMC free article] [PubMed] [Google Scholar]
  138. Yoon S.H., Miyazaki M., Hong S.W., Tow B., Morishita Y., Hu M., Ahn S.J., Wang J.C. (2008). A porcine model of intervertebral disc degeneration induced by annular injury characterized with magnetic resonance imaging and histopathological findings. Laboratory investigation. J. Neurosurg. Spine 8, 450–457 [DOI] [PubMed] [Google Scholar]
  139. Zhao C.Q., Wang L.M., Jiang L.S., Dai L.Y. (2007). The cell biology of intervertebral disc aging and degeneration. Ageing Res. Rev. 6, 247–261 [DOI] [PubMed] [Google Scholar]

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