INTRODUCTION. Intervertebral disc (IVD) degeneration is not completely understood because of the lack of relevant models. In vivo models are inappropriate because animals are quadrupeds. IVD is composed of the Nucleus Pulposus (NP) and the Annulus Fibrosus (AF), an elastic tissue that surrounds NP. AF consists of concentric lamellae made of collagen I and glycosaminoglycans with fibroblast-like cells located between layers. In this study, we aimed to develop a novel 3D in vitro model of Annulus Fibrosus to study its degeneration. For this purpose, we reproduced the microenvironment of AF cells using 3D printing. METHOD. An ink consisting of dense collagen (30 mg.mL. -1. ) and tyramine-functionalized hyaluronic acid (THA) at 7.5 mg.mL. -1. was first designed by modulating pH and [NaCl] in order to inhibit the formation of polyionic complexes between collagen and THA. Then, composite inks were printed in different gelling baths to form collagen hydrogels. Last, THA photocrosslinking using eosin and green light was performed to strengthen hydrogels. Selected 3D printed constructs were then cellularized with fibroblasts. RESULTS. The physicochemical study revealed that collagen/THA solutions (4:1 ratio) used at pH 5 with 200 mM NaCl were homogenous. In addition, collagen fibrils were observed in these solutions. The dense composite collagen/THA inks printed in a 2X PBS bath rapidly gelled and the photo-crosslinking increased the mechanical properties by 2 to reach 25 kPa (Young's modulus). Then, 3D printing parameters were optimized (85 kPa, extrusion, 4.5 mm/s speed and 80% fill-in percentage) to generate flat and anisotropic lamellae observed by polarized light microscopy. For the in vitro study, several anisotropic layers were printed and fibroblasts seeded between them. Cells adhered to layers, spread, proliferate and aligned along the axis of printed layers. CONCLUSION. Taken together, these results show it is possible to reproduce in vitro the main AF's biochemical and physical properties

Introduction. Analogous to articular cartilage, changes in spatial chondrocyte organisation have been proposed to be a strong indicator for local tissue degeneration and destruction in the intervertebral disc (IVD). While a progressive structural and functional degradation of the extracellular (ECM) and pericellular (PCM) matrix occurs in osteoarthritic cartilage, these processes have not yet been biomechanically elucidated in the IVD. We aimed to evaluate the local stiffness of the ECM and PCM in the anulus fibrosus of the IVD on the basis of local cellular spatial organisation. Method. Using atomic force microscopy, we measured the elastic modulus of the local ECM and PCM in human disc samples using the spatial chondrocyte patterns as an image-based biomarker. Result. By measuring tissue from 30 patients, we found a significant difference in the elastic moduli of the PCM in clusters when compared to the healthy patterns single cells (p=0.029), pairs (p=0.016), and string formations (p=0.010) whereas the values of the elastic moduli of the ECM only reached statistical significance when clusters were compared with string formations. The ECM/PCM ratio ranged from 0.62 to 0.89. Overall, the reduced elastic moduli in clusters demonstrates that cluster formation is not only a morphological phenomenon describing disc degeneration, but it marks a compromised biomechanical functioning. Conclusion. This study is the first to describe and quantify the differences in the elastic moduli of the ECM in relation to the PCM in the anulus fibrosus of the IVD by means of atomic force microscopy on the basis of spatial chondrocyte organisation. Advanced disc degeneration is accompanied by a biomechanically compromised tissue functioning

Background. Chronic low back pain is strongly linked to degeneration of the intervertebral disc (IVD), which currently lacks any targeted treatments. This study explores NPgel, a biomaterial combined with notochordal cells (NC), developmental precursor cells, as a potential solution. NCs, known for anti-catabolic effects on IVD cells, present a promising avenue for regenerating damaged IVD tissue. Methods. Bovine IVDs underwent enzymatic degeneration before NPgel (+/- NC) injection. Degenerated bovine IVDs were cultured under biomechanical loading for 21 days. Histology and immunohistochemistry assessed NC survival, phenotype, and matrix production. Within an in vivo sheep pilot study, NPgel (+/- NC) was injected into degenerated IVDs, blood was taken, and immune cell activation was monitored via flow cytometry over three months post-injection. Results. Within the ex vivo model, IVDs injected with NPgel (+/- NC) exhibited increased matrix expression and deposition. Viable NCs were detected post-culture, indicating survival and matrix production. In the in vivo model, NPgel injection into sheep IVDs did not significantly increase activation of immune cells compared to controls, suggesting no systemic inflammatory effects. Conclusion. NPgel, combined with NCs, shows promise for IVD regeneration. Ex vivo findings indicate NPgel supports NC survival and matrix production. Moreover, in vivo results demonstrate the absence of systemic immunogenic responses post-NPgel injection. This suggests NPgel's potential as a carrier for NCs in IVD regeneration therapy. These findings underscore NPgel's candidacy for further investigation in addressing chronic low back pain associated with IVD degeneration. Subsequent research, including long-term efficacy and safety evaluations, is imperative for clinical translation. Conflicts of interest. There are no conflicts of interest. Sources of funding. iPSpine, grant # 825925, Horizon 2020

Aims

To systematically evaluate whether bracing can effectively achieve curve regression in patients with adolescent idiopathic scoliosis (AIS), and to identify any predictors of curve regression after bracing.

Back pain is a leading cause of disability worldwide and it is primarily considered to be triggered by intervertebral disc (IVD) degeneration (IVDD). Current treatments may improve pain and mobility, but carry high costs and fail to address IVD repair or regeneration. As no effective therapeutic approach has been proposed to restore inflamed and degenerated IVDs, there is the urgent need to clarify the key pathomechanism of IVDD, the involvement of inflammation, particularly complement activation in matrix catabolism, and how to target them towards tissue repair/regeneration. Mesenchymal stem cell (MSC)-based therapies have become the focus of several regenerative IVD studies. Although patients in clinical trials reported less pain after cell therapy, the long-term success of cell engraftment is unclear due to the hostile IVD environment. The mechanism-of-action of MSCs is mostly dependent on the secreted soluble factors. Moreover, priming of MSC with interleukin (IL)-1β modulates the secretome content, improving its anti-inflammatory and regenerative effect on IVDD organ culture models. MSC-derived extracellular vesicles (EVs) have also been shown to modulate human IVD cells towards a healthy IVD phenotype in vitro. However, the mechanisms involved in the effect of secretome and EVs, particularly with regard to immunomodulation and matrix metabolism, are not fully understood. Our work investigates the effects of secretome and EVs secreted by IL-1β-primed MSCs to impair IVD matrix degradation and/or improve matrix formation in IVDD

Mechanical loading is important to maintain the homeostasis of the intervertebral disc (IVD) under physiological conditions but can also accelerate cell death and tissue breakdown in a degenerative state. Bioreactor loaded whole organ cultures are instrumental for investigating the effects of the mechanical environment on the IVD integrity and for preclinical testing of new therapies under simulated physiological conditions. Thereby the loading parameters that determine the beneficial or detrimental reactions largely depend on the IVD model and its preparation. Within this symposium we are discussing the use of bovine caudal IVD culture models to reproduce tissue inflammation or matrix degradation with or without bioreactor controlled mechanical loading. Furthermore, the outcome parameters that define the degenerative state of the whole IVD model will be outlined. Besides the disc height, matrix integrity, cell viability and phenotype expression, the tissue secretome can provide indications about potential interactions of the IVD with other cell types such as neurons. Finally, a novel multiaxial bioreactor setup capable of mimicking the six degrees-of-freedom loading environment of IVDs will be introduced that further advances the relevance of preclinical ex-vivo testing

Degeneration of the intervertebral disc (IVD), and subsequent low back pain, is an almost inevitable cause of disability. The underlying mechanisms are complex and current therapeutic strategies mainly focus on symptomatic relief rather than on the intrinsic regeneration of the IVD. This talk will provide an overview of special anatomical features and the composition of the IVD as well as its cellular microenvironment. Selected promising conceptional regenerative approaches will be discussed

The use of mesenchymal stem cell (MSCs) for intervertebral disc (IVD) regeneration has been extensively explored in the last two decades. MSCs are potent cell types that can be easily and safely harvested due to their abundancy and availability. Moreover, they are characterized by the capacity to differentiate towards IVD cells as well as release growth factors to support resident cell metabolism and recruit local progenitor cells to induce endogenous repair of degenerated IVDs. This talk will outline the characteristics of the main MSC sources and their effect towards IVD regeneration based on available preclinical and clinical evidence. In addition, innovative aspects of MSC-derived cell-free therapies will also be discussed

Intervertebral discs (IVD) provide flexibility to the back and ensure functional distributions of the spinal loads. They are avascular, and internal diffusion-dependent metabolic transport is vital to supply nutrients to disc cells1, but interactions with personalized IVD shapes and mechanics remain poorly explored. Poromechanical finite element models of seven personalized lumbar IVD geometries, with mean heights ranging from 8 to 16 mm were coupled with a reactive oxygen, glucose and lactate transport model linked with tissue deformations and osmosis . In previous studies, reduced formulations of the divergence of the solute flux (∇ .J = ∇ . (D∇ C) = ∇ D. ∇ C +D∇ 2C) ignored the dependence of the diffusion on the deformation gradients, ∇ D. ∇C. We simulated this phenomenon to explore its significance in mechano-metabolic -transport couplings, in the different geometries, over 24h of simulated rest (8h) and physical activity (16h). ∇ D. ∇ C affected the daily variations of glucose concentrations in IVD thinner than 12 mm but with neglectable variation ranges, while not considering ∇ D. ∇ C in taller discs only slightly overestimated the glucose concentration. Most importantly, tall IVD had nearly 60% less glucose than thin IVD, with local drops below the concentration of 0.5 mM, considered to be critical for disc cells3, in the anterior nucleus pulposus. On the one hand, previous reduced formulations for mechanometabolic-transport models of the IVD seem acceptable, even for patient-specific modelling. On the other hand, tall IVD might suffer from unfortunate combinations of deformation-dependent solute diffusion and large diffusion distances, which may favor early. Acknowledgements: Catalan Government and European Commission (2020 BP 00282; ERC-2021-CoG-O-Health-101044828)

Intervertebral disc (IVD) degeneration is a pathological process often associated with chronic back pain and considered a leading cause of disability worldwide. 1. During degeneration, progressive structural and biochemical changes occur, leading to blood vessel and nerve ingrowth and promoting discogenic pain. 2. In the last decades, several cytokines have been applied to IVD cells in vitro to investigate the degenerative cascade. Particularly, IL-10 and IL-4 have been predicted as important anabolic factors in the IVD according to a regulatory network model based in silico approach. 3. Thus, we aim to investigate the potential presence and anabolic effect of IL-10 and IL-4 in human NP cells (in vitro) and explants (ex vivo) under hypoxia (5% O2) after a catabolic induction. Primary human NP cells were expanded, encapsulated in 1.2% alginate beads (4 × 106 cells/ml) and cultured for two weeks in 3D for phenotype recovery while human NP explants were cultured for five days. Afterwards, both alginate and explant cultures were i) cultured for two days and subsequently treated with 10 ng/ml IL-10 or IL-4 (single treatments) or ii) stimulated with 0.1 ng/ml IL-1β for two days and subsequently treated with 10 ng/ml IL-10 or IL-4 (combined treatments). The presence of IL-4 receptor, IL-4 and IL-10 was confirmed in human intact NP tissue (Fig 1). Additionally, IL-4 single and combined treatments induced a significant increase of proinflammatory protein secretion in vitro (Fig. 2A-C) and ex vivo (Fig. 2D and E). In contrast, no significant differences were observed in the secretome between IL-10 single and combined treatments compared to control group. Overall, IL-4 containing treatments promote human NP cell and explant catabolism in contrast to previously reported IL-4 anti-inflammatory performance. 4. Thus, a possible pleiotropic effect of IL-4 could occur depending on the IVD culture and environmental condition. Acknowledgements: This project was supported by the Marie Skłodowska Curie International Training Network “disc4all” under the grant agreement #955735. For any figures and tables, please contact the authors directly

Stem cell therapy for the intervertebral disc (IVD) is highly debated but holds great promises. From previous studies, it is known that notochordal cells are highly regenerative and may stimulate other differentiated cells to produce more matrix. Lately, a particular tissue-specific progenitor cell population has been identified in the centre of the intervertebral disc (IVD. The current hope is that these nucleus pulposus progenitor cells (NPPC) could play a particular role in IVD regeneration. Current evidence confirms the presence of these cells in murine, canine, bovine and in the human fetal/surgical samples. Noteworthy, one of the main markers to identify these cells, i.e., Tie2, is a typical marker for endothelial cells. Thus, it is not very clear what their origin and their role might be in the context of developmental biology. In human surgical specimens, their presence is, even more, obscured depending on the donor's age and the condition of the IVD and other yet unknown factors. Here, I revisit the recent literature on regenerative cells identified for the IVD in the past decades. Current evidence how these NPPC can be isolated and detected in various species and tissues will be recapitulated. Future directions will be provided on how these progenitor cells could be used for regenerative medicine and tissue engineering

Low back pain (LBP) is a worldwide leading cause of disability. Treatment of intervertebral disc (IVD) with stem cells has been used on degenerate discs (IDD), cause of around 40% of LBP cases. Despite pain reduction, clinical studies' follow-up have not shown a structural IVD improvement. A valid alternative may be the use of notocordal cells (NC) or their precursors. Mesendoderm progenitor cells (MEPC) have the ability to replicate and differentiate toward NC. In this preliminary study we evaluated in a preclinical IDD model the viability and NC differentiation of MEPC derived from induced pluripotent stem cells (iPSC). MEPC derived from iPSC were developed during the iPSpine project (# 825925), thawed, plated for 24h on laminin and labeled with PKH26. Two adult sheep were subjected to nucleotomy of five lumbar discs for the induction of IDD. After 5 weeks, 3 degenerated discs were treated with MEPC at 3 different doses (low, medium and high). One sheep was sacrificed after 7 days and one after 30 days. Clinical parameters were collected to evaluate the safety of treatment. Discs were analysed using histological techniques. Survival (PKH26), proliferation (PCNA), notocordal cell differentiation (Brachyury, Cytokeratin 8/18/19, Sox9, Foxa2) and endodermal differentiation (Sox17) were evaluated. At 7 days from treatment, both sheep lost about 20% of body weight. Only in discs treated with the highest dose PKH26 stained cells were alive up to 30 days. These cells turn out to be: proliferating (PCNA); positive for Brachyury, cytokeratin 8/18/19 and Foxa2; positive for SOX17 in a small percentage. This preliminary study shows that MEPC, derived from iPSC and injected into ovine discs degenerated by nucleotomy, are able to survive up to 30 days and differentiate within the disc predominantly towards the notocordal phenotype

This study investigates the relationships between Intervertebral Disc (IVD) morphology and biomechanics using patient-specific (PS) finite element (FE) models and poromechanical simulations. 169 3D lumbar IVD shapes from the European project MySpine (FP7-269909), spanning healthy to Pfirrmann grade 4 degeneration, were obtained from MRIs. A Bayesian Coherent Point Drift algorithm aligned meshes to a previously validated structural FE mesh of the IVD. After mesh quality analyses and Hausdorff distance measurements, mechanical simulations were performed: 8 and 16 hours of sleep and daytime, respectively, applying 0.11 and 0.54 MPa of pressure on the upper cartilage endplate (CEP). Simulation results were extracted from the anterior (ATZ) and posterior regions (PTZ) and the center of the nucleus pulposus (CNP). Data mining was performed using Linear Regression, Support Vector Machine, and eXtreme Gradient Boosting techniques. Mechanical variables of interest in DD, such as pore fluid velocity (FLVEL), water content, and swelling pressure, were examined. The morphological variables of the simulated discs were used as input features. Local morphological variables significantly impacted the local mechanical response. The local disc heights, respectively in the mid (mh), anterior (ah), and posterior (ph) regions, were key factors in general. Additionally, fluid transport, reflected by FLVEL, was greatly influenced (r2 0.69) by the shape of the upper and lower cartilage endplates (CEPs). This study suggests that disc morphology affects Mechanical variables of interest in DD. Attention should be paid to the antero-posterior distribution and local effects of disc heights. Surprisingly, the CEP morphology remotely affected the fluid transport in NP volumes around mid-height, and mechanobiological implications shall be explored. In conclusion, patient-specific IVD modeling has strong potential to unravel important correlations between IVD phenotypes and local tissue regulation. Acknowledgments: European Commission: Disc4All-MSCA-2020-ITN-ETN GA: 955735; O-Health-ERC-CoG-2021-101044828

Intervertebral disc (IVD) degeneration is inadequately understood due to the lack of in vitro systems that fully mimic the mechanical and biological complexity of this organ. We have recently made an advancement by developing a bioreactor able to simulate physiological, multiaxial IVD loading and maintain the biological environment in ex vivo IVD models [1]. To validate this new bioreactor system, we simulated natural spine movement by loading 12 bovine IVDs under a combination of static compression (0.1 MPa), cyclic flexion/extension (±3˚, ±6˚ or 0-6˚) and cyclic torsion (±2˚, ±4˚ or 0-4˚) for more than 10’000 (0.2 Hz) or 100’000 (1 Hz) cycles over 14 days. A higher number of cycles increased the release of glycosaminoglycans and nitric oxide, as an inflammation marker, whereas fewer cycles maintained these two factors at physiological levels. All applied protocols upregulated the expression of MMP13 in the outermost annulus fibrosus (AF), indicating a collagen degradation response. This was supported by fissures observed in the AF after a longer loading duration. Increasing loading cycles induced high cell death in the nucleus pulposus and inner AF, while with fewer cycles, high cell viability was maintained in all IVD regions, irrespective of the magnitude of rotation. Less frequent multiaxial loading maintains IVD homeostasis while more frequent loading initiates an IVD degenerative profile. Specifically, the morphological and molecular changes were localized in the AF, which can be associated with combined flexion/extension and torsion. More loading cycles induced region-specific cell death and a higher release of extracellular matrix molecules from the innermost IVD regions, likely associated with longer exposure to static compression. Altogether, we demonstrated the advantages of the multiaxial bioreactor to study region-specific response in the IVD, which will allow a more profound investigation of IVD degeneration under different combinations of motions

Intervertebral disc (IVD) degeneration is responsible for severe clinical symptoms including chronic back pain. Galectins are a family of carbohydrate-binding proteins, some of which can induce functional disease markers in IVD cells and other musculoskeletal diseases. Galectins −4 and −8 were shown to trigger disease-promoting activity in chondrocytes but their effects on IVD cells have not been investigated yet. This study elucidates the role of galectin-4 and −8 in IVD degeneration. Immunohistochemical evidence for the presence of galectin-4 and −8 in the IVD was comparatively provided in specimens of 36 patients with spondylochondrosis, spondylolisthesis, or spinal deformity. Confocal microscopy revealed co-localization of galectin-4 and −8 in chondrocyte clusters of degenerated cartilage. The immunohistochemical presence of galectin-4 correlated with histopathological and clinical degeneration scores of patients, whereas galectin-8 did not show significant correlations. The specimens were separated into annulus fibrosus (AF), nucleus pulposus (NP) and endplate, which was confirmed histologically. Separate cell cultures of AF and NP (n=20) were established and characterized using cell type-specific markers. Potential binding sites for galectins including sialylated N-glycans and LacdiNAc structures were determined in AF and NP cells using LC/ESI-MS-MS. To assess galectin functions, cell cultures were treated with recombinant galectin-4 or −8, in comparison to IL-1β, and analyzed using RT-qPCR and In-cell Western blot. In vitro, both galectins triggered the induction of functional disease markers (CXCL8 and MMP3) on mRNA level and activated the nuclear factor-kB pathway. NP cells were significantly more responsive to galectin-8 and Il-1β than AF cells. Phosphorylation of p-65 was time-dependently induced by both galectins in both cell types to a comparable extent. Taken together, this study provides evidence for a functional role of glycobiological processes in IVD degeneration and highlights galectin-4 and −8 as regulators of pro-inflammatory and degrative processes in AF and NP cells

Intervertebral disc (IVD) degeneration occurs with aging, leading to low back pain (LBP), which is one of the leading conditions of disability worldwide. With the lack of effective treatment, decellularized extracellular matrix (dECM) – based biomaterials have been proposed for IVD regeneration. However, the impact of donor ages on tissue repair had never been explored before in the disc field. Therefore, we aimed to address this question. For that, a decellularization protocol for bovine nucleus pulposus (NP) of different aged donors (fetus, young and old) was optimized by testing several detergents (SDS and Triton). The process efficiency was evaluated in terms of DNA and cell removal, as well as ECM preservation. Afterwards, dECMs were repopulated with bovine NP cells and cultured ex vivo. At day 7, cell behavior, ECM de novo synthesis and remodeling were evaluated [1]. Moreover, dECMs’ inflammatory response was assessed after in vivo CAM assay. Finally, inflammatory and angiogenic cytokines were analyzed in the conditioned media-derived from dECMs by using a cytokine array. As results, an optimal decellularization protocol (SDS 0.1%, 1h), efficient at removing cells and DNA from bovine NPs, while preserving ECM cues of native tissues, was developed. After repopulation, aggrecan increased in younger NPs, while collagen 2 decreased which may be indicative of matrix remodeling [1]. After in vivo CAM assay, fetal dECMs showed the highest inflammatory response. Finally, no statistically significant changes of cytokines were detected in the matrices, despite for a trend of higher IFN-α, IFN-γ and LIF in fetal dECMs, IL-1β in young dECMs and Decorin in old dECMs. Overall, this work uncovered the importance of tissue donor ages for tissue regenerative purpose, opening new avenues for the development of appropriate therapeutic strategies for IVD degeneration. Acknowledgments: FCT, EUROSPINE, ON Foundation

Intervertebral disc (IVD) degeneration (IDD) involves imbalance between the anabolic and the catabolic processes that regulate the extracellular matrix of its tissues. These processes are complex, and improved integration of knowledge is needed. Accordingly, we present a nucleus pulposus cell (NPC) regulatory network model (RNM) that integrates critical biochemical interactions in IVD regulation and can replicate experimental results. The RNM was built from a curated corpus of 130 specialized journal articles. Proteins were represented as nodes that interact through activation and inhibition edges. Semi-quantitative steady states (SS) of node activations were calculated. Then, a full factorial sensitivity analysis (SA) identified which out of the RNM 15 cytokines, and 4 growth factors affected most the structural proteins and degrading enzymes. The RNM was further evaluated against metabolic events measured in non-healthy human NP explant cultures, after 2 days of 1ng/ml IL-1B catabolic induction. The RNM represented successfully an anabolic basal SS, as expected in normal IVD. IL-1B was able to increase catabolic markers and angiogenic factors and decrease matrix proteins. Such activity was confirmed by the explant culture measurements. The SA identified TGF-β and IL1RA as the two most powerful rescue mediators. Accordingly, TGFβ signaling-based IDD treatments have been proposed and IL-1RA gene therapy diminished the expression of proteases. It resulted challenging to simulate rescue strategies by IL-10, but interestingly, IL-1B could not induce IL-10 expression in the explant cultures. Our RNM was confronted to independent in vitro measurements and stands for a unique model, to integrate soluble protein signaling and explore IDD. Acknowledgements: European Commission (Disc4All-ITN-ETN-955735)

Intervertebral disc (IVD) degeneration is the most frequent cause of Low Back Pain (LBP) affecting nearly 80% of the population [1]. Current treatments fail to restore a functional IVD or to provide a long-term solution, so, there is an urgent need for novel therapeutic strategies. We have defined the IVD extracellular matrix (ECM) profile, showing that the pro-regenerative molecules Collagen type XII and XIV, are uniquely expressed during fetal stages [2]. Now we propose the first fetal injectable biomaterial to regenerate the IVD. Fetal decellularized IVD scaffolds were recellularized with adult IVD cells and further implanted in vivo to evaluate their anti-angiogenic potential. Young decellularized IVD scaffolds were used as controls. Finally, a large scale protocol to produce a stable, biocompatible and easily injectable fetal IVD-based hydrogel was developed. Fetal scaffolds were more effective at promoting Aggrecan and Collagen type II expression by IVD cells. In a Chorioallantoid membrane assay, only fetal matrices showed an anti-angiogenic potential. The same was observed in vivo when the angiogenesis was induced by human NP cells. In this context, human NP cells were more effective in GAG synthesis within a fetal microenvironment. Vaccum-assisted perfusion decellularized IVDs were obtained, with high DNA removal and sGAG retention. Hydrogel pre-solution passed through 21-30G needles. IVD cells seeded on the hydrogels initially decreased metabolic activity, but increased up to 70% at day 7, while LDH assay revealed cytotoxicity always below 30%. This study will open new avenues for the establishment of a disruptive treatment for IVD degeneration with a positive impact on the angiogenesis associated with LBP, and on the improvement of patients’ quality of life. Acknowledgements: Financial support was obtained from EUROSPINE, ON Foundation and FCT (Fundação para a Ciência e a Tecnologia)

Aims

This study aimed, through bioinformatics analysis and in vitro experiment validation, to identify the key extracellular proteins of intervertebral disc degeneration (IDD).

Injury of the intervertebral disc (IVD) can occur for many reasons including structural weakness due to disc degeneration. A common disc injury is herniation. A herniated nucleus can compress spinal nerves, causing pain, and nucleus depressurisation changes mechanical behaviour. Many studies have investigated in vitro IVD injuries including endplate fracture, incisions, and nucleotomy. There is, however, a lack of consensus on how the biomechanical behaviour of spinal motion segments is affected. The aim of this study was to induce defined changes to IVDs of spine specimens in vitro and apply 6 degree of freedom testing to evaluate the effect of these changes. Six porcine lumbar spinal motion segments were harvested from organically farmed pigs. Posterior structures were removed to produce isolated spinal disc specimens. Specimens were potted in Wood's metal, ensuring the midplane of the IVD remained horizontal. After potting, specimens were sprayed with 0.9% saline, wrapped in saline-soaked tissue and plastic wrap to prevent dehydration. A 400N axial preload was equilibrated for 30 minutes before testing. Specimens were tested intact and after a partial nucleotomy removing ~0.34g of nuclear material with a curette through an annular incision. Stiffness tests were performed using the University of Bath's custom 6-axis spine simulator with coordinate axes and displacement amplitudes. Tests comprised five cycles with data acquired at 100Hz. Stiffness matrices were evaluated from the last three motion cycles using the linear least squares method. Stiffness matrices for intact and nucleotomy tests were compared. No significant differences in shear, axial or torsional stiffnesses were noted. Nucleotomy caused significantly higher stiffness in lateral bending and flexion-extension with increased linearity and the load-displacement behaviour in these axes displayed no neutral zone (NZ). Induced changes were designed to replicate posterolaterally herniated discs. Unaffected shear, axial and torsional stiffnesses suggest the annulus is crucial in these axes. However, reduced ROM and NZ after nucleotomy suggests bending is most affected by herniation. Increased linearity and lack of defined NZ in these axes demonstrates herniation causes major changes to the viscoelastic behaviour of spine specimens in response to loading