Aims. CRP is an acute-phase protein that is used as a biomarker to follow severity and progression in infectious and inflammatory diseases. Its pathophysiological mechanisms of action are still poorly defined. CRP in its pentameric form exhibits weak anti-inflammatory activity. The monomeric isoform (mCRP) exerts potent proinflammatory properties in chondrocytes, endothelial cells, and leucocytes. No data exist regarding mCRP effects in human intervertebral disc (IVD) cells. This work aimed to verify the pathophysiological relevance of mCRP in the aetiology and/or progression of IVD degeneration. Methods. We investigated the effects of mCRP and the signalling pathways that are involved in cultured human primary annulus fibrosus (AF) cells and in the human nucleus pulposus (NP) immortalized cell line HNPSV-1. We determined messenger RNA (mRNA) and protein levels of relevant factors involved in inflammatory responses, by quantitative real-time polymerase chain reaction (RT-qPCR) and western blot. We also studied the presence of mCRP in human AF and NP tissues by immunohistochemistry. Results. We demonstrated that mCRP increases nitric oxide synthase 2 (NOS2), cyclooxygenase 2 (COX2), matrix metalloproteinase 13 (MMP13), vascular cell adhesion molecule 1 (VCAM1), interleukin (IL)-6, IL-8, and Lipocalin 2 (LCN2) expression in human AF and NP cells. We also showed that nuclear factor-κβ (NF-κβ), extracellular signal-regulated kinase 1/2 (ERK1/2), and phosphoinositide 3-kinase (PI3K) are at play in the intracellular signalling of mCRP. Finally, we demonstrated the presence of mCRP in human AF and NP tissues. Conclusion. Our results indicate, for the first time, that mCRP can be localized in IVD tissues, where it triggers a proinflammatory and catabolic state in degenerative and healthy IVD cells, and that NF-κβ signalling may be implicated in the mediation of this mCRP-induced state. Cite this article: Bone Joint Res 2023;12(3):189–198

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.

Aims

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

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

Background. An improved understanding of intervertebral disc (IVD) structure and function is required for treatment development. Loading induces micro-fractures at the interface between the nucleus pulposus (NP) and the annulus fibrosus (AF), which is hypothesized to induce a cascade of cellular changes leading to degeneration. However, there is limited understanding of the structural relationship between the NP and AF at this interface and particularly response to load. Here, X-ray scattering is utilised to provide hierarchical morphometric information of collagen structure across the IVD, especially the interface region under load. Methodology. IVDs were imaged using the I22 SAXS/WAXS beamline at Diamond Light Source. Peaks associated with the D-banded structure of collagen fibrils were fitted to quantify their azimuthal distribution, as well the magnitude and direction of internal strains under static and applied strain (0–20%). Results. IVD tissue regions exhibited structural “AF-like” and “NP-like” fingerprints. Demonstrating high internal strains on collagen fibres particularly within the NP region of the disc. AF and NP regions showed distinct collagen orientation and internal strains with an apparent lack of bracing structure seen at the interface between the differential mechanical tissues. X-ray scattering under tensile strain provided structural information at high resolution, with clear differences observed between normal and degenerate discs under load. Conclusion. X ray scattering has been utilised to develop an improved understanding of collagen structure across the intervertebral disc which can be utilised to gain an increased understanding of load induced propagation of micro fissures and disc degeneration. Conflict of Interest: No conflict of interest. Funding: BioPro Network, UCL for funding this study through support from the MRC (MR/R025673/1)

Backgrounds and aim. Low back pain resulting from Intervertebral disc (IVD) degeneration is a serious worldwide problem, with poor treatment options available. Notochordal (NC) cells, are a promising therapeutic cell source with anti-catabolic and regenerative effect, however, their behaviour in the harsh degenerate environment is unknown. Thus, we aimed to investigate and compare their physiological behaviour in in vitro niche that mimics the healthy and degenerated intervertebral disc environment. Methodology. Porcine NC cells were encapsulated in 3D alginate beads to maintain their phenotype then cultured in media to mimic the healthy and degenerate disc environment, together with control NC media for 1 week. Following which viability using PI and Calcein AM, RNA extraction and RT-PCR for NC cell markers, anabolic and catabolic genes analysed. Proteomic analysis was also performed using Digiwest technology. Results. A small increase in cell death was observed in degenerated media compared to standard and healthy media, with a further decrease seen when cultured with IL-1β. Whilst no significant differences were seen in phenotypic marker expression in NCs cultured in any media at gene level (ACAN, KRT8, KRT18, FOXA2, COL1A1 and Brachyury). Preliminary Digiwest analysis showed increased protein production for Cytokeratin 18, src and phosphorylated PKC but a decrease in fibronectin in degenerated media compared to standard media. Discussion. Studying the behaviour of the NCs in in vitro conditions that mimic the in vivo healthy or degenerate niche will help us to better understand their potential for therapeutic approaches. The initial work has been then translated to investigate the potential use of iPSCs differentiated into notochordal like cells as potential regenerative cell sources. Conflicts of interest: No conflicts of interest. Sources of funding: This project has received funding from the European Union Horizon 2020 research and innovation programme under grant agreement No 825925

Objectives. Low back pain is strongly associated with degeneration of the intervertebral disc (IVD). During degeneration, altered matrix synthesis and increased matrix degradation, together with accompanied cell loss is seen particularly in the nucleus pulposus (NP). It has been proposed that notochordal (NC) cells, embryonic precursors for the cells within the NP, could be utilized for mediating IVD regeneration. However, injectable biomaterials are likely to be required to support their phenotype and viability within the degenerate IVD. Therefore, viability and phenotype of NC cells were analysed and compared within biomaterial carriers subjected to physiological oxygen conditions over a four-week period were investigated. Methodology. Porcine NC cells were incorporated into three injectable hydrogels: NPgel (a L-pNIPAM-co-DMAc hydrogel), NPgel with decellularized NC-matrix powder (dNCM) and Albugel (an albumin/ hyaluronan hydrogel). The NCs and biomaterials constructs were cultured for up to four weeks under 5% oxygen (n=3 biological repeats). Histological, immunohistochemical and glycosaminoglycans (GAG) analysis were performed to investigate NC viability, phenotype and extracellular matrix synthesis and deposition. Results. Histological analysis revealed that NCs survive in the biomaterials after four weeks and maintained cell clustering in NPgel, Albugel and dNCM/NPgel. NPgel and Albugel maintained NC cell markers and extracellular matrix. NC containing constructs excreted more GAGs over the four weeks than the acellular controls. Conclusion. NC cells maintain their phenotype and characteristic features in vitro when encapsulated into biomaterials. NC cells and biomaterial construct could potentially become a therapy to treat and regenerate the IVD. Conflicts of interest: No conflicts of interest. Sources of funding: This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 825925

Introduction. Musculoskeletal diseases are the biggest cause of morbidity worldwide, with low back pain (LBP) being the leading cause. Forty percent of LBP cases are caused by disease of shock absorbers in the spine known as intervertebral discs (IVDs). The IVDs enable the spine to twist and bend, whilst absorbing load during normal daily activities. The durability of this tissue is sustained by the cells of the spine and so during disease or mechanical damage these cells can behave abnormally further damaging the disc and stimulating local nerves causing extreme pain. Degradation of the intervertebral disc (IVD) currently has no preventative treatment; an injectable hydrogel biomaterial could reinforce disc mechanical properties and promote tissue regeneration. Methods and Results. We present an injectable range of hydrogel biomaterials made from water, clay and polymer that set at 37°C. The materials were made at 80°C polymerised in water and stored at 70°C to remain liquid. The physical properties of the materials were assessed using various methods, including mechanical assessment using temperature-controlled rheometry to monitor the liquid-hydrogel transition. Conclusion. Results showed that by changing three factors within the formulation we can produce a range of materials with suitable mechanical and morphological properties for a variety of tissues of the spine. These types of biomaterials have the potential to provide the first efficacious early-mid stage treatment for IVD disease and reduce the cost of LBP on our health services. Conflicts of interest: CS and CLM are named inventors on the patent for NPgel/BGel. Funded by the Medical Research Council and Versus Arthritis UK: SNiPER

Study purpose and background. Novel regenerative therapies have the potential to restore function and relieve pain in patients with low back pain (LBP) caused by intervertebral disc (IVD) degeneration. We have previously shown that stimulation of adipose-derived stem cells (ASCs) with growth differentiation factor-6 (GDF6) promotes differentiation into nucleus pulposus (NP) cells of the IVD, which have potential for IVD regeneration. We have also shown that GDF6 stimulation activates the Smad1/5/8 and ERK1/2 signalling cascades. The aim of this study was to progress our understanding of the immediate/early response mechanisms in ASCs (N=3) which may direct GDF6-induced differentiation. Methods and results. RNAseq was used to perform transcriptome-wide analysis across a 12-hour time course, post-stimulation. Gene ontology analysis revealed greater transcription factor and biological processes activity at 2hrs than at the 6hr and 12hr time points, where molecular and cellular activities appeared to stabilise. Interestingly, a number of lineage determining genes were identified as differentially expressed and work is ongoing to investigate whether the early response genes are maintained throughout differentiation, or whether they are responsible for early NP lineage commitment. Conclusion. This study is the first transcriptome-wide analysis on GDF6-mediated stimulation of ASCs, elucidating important early response mechanisms involved in directing appropriate differentiation. Identification of additional key markers and signalling pathways of differentiation will allow improved selection of ASCs for IVD regeneration. ‘No conflicts of interest’. Funding sources: NIHR Manchester Biomedical Research Centre and The RoseTrees Trust

Background. Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP). We have developed an injectable hydrogel (NPgel), which following injection into bovine IVD explants, integrates with IVD tissue and promotes disc cell differentiation of delivered mesenchymal stem cells (MSCs) without growth factors. Here, we investigated the injection of NPgel+MSCs into IVD explants under degenerate culture conditions. Methods and Results. The NPgel integrated with bovine and human degenerate Nucleus Pulposus (NP) tissue and hMSCs produced matrix components: aggrecan, collagen type II and chondroitin sulphate in standard and degenerate culture conditions. Significantly increased cellular immunopositivty for aggrecan was observed within native NP cells surrounding the site where NPgel+MSCs were injected (P≤0.05). In NP explants a significant decrease in catabolic factors were observed where NPgel+MSCs was injected in comparison to controls. Conclusions. In agreement with our previous findings NPgel was sufficient alone to induce NP cell differentiation of MSCs following injection into NP tissue explants. Here, we have shown that viability is maintained even in degenerate conditions. Injection of NPgel with MSCs increased aggrecan expression and reduced MMP3 and IL-1R1 expression by native NP cells. The NPgel with incorporated MSCs has the potential to regenerate the NP and provide mechanical support, whilst reducing the catabolic phenotype of degenerate NP cells, as a treatment strategy for IVD degeneration. No conflicts of interest. Sources of funding: Funded by ARUK and MRC

Background. Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP). Degenerate discs are associated with accelerated cellular senescence. Cell senescence is associated with a secretory phenotype characterised by increased production of catabolic enzymes and cytokines. However to date, the mechanism of cell senescence within disc degeneration is unclear. Senescence can be induced by increased replication or induced by stress such as reactive oxygen species or cytokines. This study investigated the association of cellular senescence with markers of DNA damage and presence of cytoplasmic DNA (which in cancer cells has been shown to be a key regulator of the secretory phenotype), to determine mechanisms of senescence in disc degeneration. Methods and Results. Immunohistochemistry for the senescence marker: p16. INK4A. was firstly utilised to screen human intervertebral discs for discs displaying at least 30% immunopostivity. These discs were then subsequently analysed for immunopostivity for DNA damage markers γH2AX and cGAS and the presence of cytoplasmic DNA. The number of immunopositive cells for p16. INK4A. positively correlated with the expression of γH2AX and cGAS. Senescent cells were also associated with the presence of cytoplasmic DNA. Conclusions. These new findings elucidated a role of cGAS and γH2AX as a link from genotoxic stress to cytokine expression, which is associated with senescent cells. The findings indicate that cellular senescence in vivo is associated with DNA damage and presence of cytoplasmic DNA. Whether this DNA damage is a result of replicative senescence or stress induced is currently being investigated in vitro. No conflicts of interest. Sources of funding: Funded by ARUK and MRC

Introduction. Injectable hydrogels via minimally invasive surgery offer benefits to the healthcare system, reduced risk of infection, scar formation and the cost of treatment. Development of new treatments with the use of novel biomaterials requires significant pre-clinical testing and must comply with regulations before they can reach the bedside. In the European economic area (EEA) one of the first hurdles of this process is attaining the CE marking which protects the health, safety and environmental aspects of a product. Implanted materials fall under the class III medical device EU745 regulation standards. To attain the CE marking for a product parties must provide evidence of the materials safety with an investigational medicinal product dossier (IMPD). Methods and Results. We have been working to develop a new thermoresponsive injectable biomaterial hydrogel (NPgel) for the treatment of intervertebral disc (IVD) disease. A large part of the IMPD requires information on how the hydrogel physical properties change over time in bodily conditions. We have been studying 6 batches of NPgel over 18 months, tracking the materials wet/ dry weight, structure and composition. To date we have found that NPgel in liquids more similar to the body (with protein and salts) appear to be stable and safe, whilst those in distilled water swell and disintegrate over time. Subtle long-term changes to the material composition were found and we are currently investigating its ramifications. Conclusion. The study highlights the need to test materials in detail in physiologically representative environments before approaching the bedside and demonstrates promise for NPgel as a suitable CE candidate. Conflicts of interest: CS and CLM are named inventors on the patent for NPgel/BGel. Funded by the Medical Research Council and Versus Arthritis UK: SNiPER

Introduction. We have developed a new synthetic hydrogel that can be injected directly into the intervertebral disc (IVD) without major surgery. Designed to improve fixation of joint prosthesis, support bone healing or improve spinal fusion, the liquid may support the differentiation of native IVD cells towards osteoblast-like cells cultured within the hydrogel. Here we investigate the potential of this gel system (Bgel) to induce bone formation within intervertebral disc tissue. Methods. IVD tissue obtained from patients undergoing discectomy, or cadaveric samples, were cultured within a novel explant device. The hydrogel was injected, with and without mesenchymal stem cells (MSCs), and cultured under hypoxia, to mimic the degenerate IVD environment, for 4 weeks. Explants were embedded to wax and native cellular migration into the hydrogel was investigated, together with cellular phenotype and matrix deposition. Results. Increased collagen deposition was seen in tissue explants injected with Bgel, with evidence of elevated native cell migration towards the hydrogel. Increased collagen staining was seen in explants injected with Bgel together with MSCs. Alizarin red staining was utilised to investigate calcium deposition. Tissue explants, in the absence of Bgel, showed limited calcium deposition. This was increased in hydrogel-treated samples, with large clumping regions in the tissue that was injected with Bgel and MSCs. Conclusion. The injection of our synthetic hydrogel into disc tissue explants increased the amount of collagen and calcium deposition. This was further enhanced by the incorporation of MSCs, suggesting the promotion of bone formation. Current work is investigating phenotypic markers for bone formation within these tissues. CS and CLM have a patent on the hydrogel system described in this abstract. Funded by EPSRC and Grow MedTech

Purpose of study and background. Low back pain affects 80% of the population at some point in their lives with 40% of cases attributed to intervertebral disc (IVD) degeneration. A number of potential regenerative approaches are under investigation worldwide, however their translation to clinic is currently hampered by an appropriate model for testing prior to clinical trials. Therefore, a more representative large animal model for IVD degeneration is needed to mimic human degeneration. Here we investigate a caprine IVD degeneration model in a loaded disc culture system which can mimic the native loading environment of the disc. Methods and Results. Goat discs were excised and cultured in a bioreactor under diurnal, simulated-physiological loading (SPL) conditions, following 3 days pre load, IVDs were degenerated enzymatically for 2hrs and subsequently loaded for 10 days under physiological loading. A PBS injected group was used as controls. Disc deformation was continuously monitored and changes in disc height recovery quantified using stretched-exponential fitting. Histological staining was performed on caprine discs to assess extracellular matrix production and immunohistochemistry performed to determine expression of catabolic protein expression. The injection of collagenase and cABC induced mechanical behavior akin to that seen in human degeneration. A decrease in collagens and glycosaminoglycans (GAGs) was seen in enzyme injected discs, which was accompanied by increased cellular expression for degradative enzymes and catabolic cytokines. Conclusion. This model provides a reproducible model of IVD degeneration which mimics human degeneration. This model allows the testing of biomaterials and other potential treatments of IVD degeneration on a scale more representative of the human disc. There are no conflicts of interest. Funded by MRC and Versus Arthritis

Introduction. The intervertebral disc (IVD) is a highly hydrated and hyperosmotic tissue, water and salt content fluctuate daily due to mechanical loading. Resident IVD cells must adapt to this ever-changing osmotic environment, to maintain normal behaviour. However, during IVD degeneration the disc becomes permanently dehydrated and cells can no longer perform their correct function. Here, we investigated how human nucleus pulposus (NP) cells respond to altered osmolality with regards to cell size and the rate of water permeability, along with the potential involvement of aquaporins (AQPs) and transient receptor potential vanilloid (TRPV) membrane channels. Methods. Water permeability of NP cells exposed to altered osmolality (225–525mOsm/kg) in the presence or absence of AQP and TRPV channel inhibitors was investigated with the cell-permeable calcein-AM fluorescent dye, and cell size determined using microscopy and flow cytometry. Results. Human NP cells modulate their size and water permeability in response to altered osmolality. Inhibiting channel proteins, specifically AQP4, modified NP cell responses to altered osmolality. Conclusion. IVD cells must regulate their size in order to survive and function within an osmotically challenging environment. Here, we demonstrated that NP cells alter their size and permeability in response to altered osmolality which enables them to adapt to their environment. Furthermore these processes were shown to be dependent at least in part by AQP4 expression, which we have previously shown to be decreased during disc degeneration. This potentially highlights novel ways to restore NP cell and overall IVD function by modulating AQPs in the disc. No conflicts of interest. Funded by BMRC, Sheffield Hallam University

Background. Degeneration of the intervertebral disc (IVD) is a leading cause of lower back pain, and a significant clinical problem. Inflammation mediated by IL-1β and TNF-α drives IVD degeneration through promoting a phenotypic switch in the resident nucleus pulposus (NP) cells towards a more catabolic state, resulting in extracellular matrix degradation. Bone marrow mesenchymal stem cells (MSCs) produce bioactive factors that modulate local tissue microenvironments and their anti-inflammatory potential has been shown in numerous disease models. Thus MSCs offer a potential therapy for IVD degeneration. In a clinical setting, adipose-derived stem cells (ASCs) might represent an alternative and perhaps more appealing cell source. However, their anti-inflammatory properties remain poorly understood. Methods. Here we assess the anti-inflammatory properties of donor-matched human ASCs and MSCs using qPCR and western blotting. Results. We demonstrate that stimulating ASCs or MSCs with IL-1β and/or TNF-α elicits a strong anti-inflammatory response with increased expression of IL-1 receptor antagonist (IL-1Ra), cyclooxygenase-2 (COX-2) and the tissue protective protein tumour-necrosis factor stimulated gene-6 (TSG-6). ASCs produced significantly higher levels of IL-1Ra and TSG-6 than their matched MSCs at both gene and protein levels, indicating that ASCs are potentially a more potent anti-inflammatory cell type. This anti-inflammatory response was also observed upon co-culture with degenerate NP cells without exogenous cytokine. Signalling analyses suggested this difference between cell types might be mediated through differences in the activation of inflammation-associated transcription factors. Conclusion. These data indicate that the anti-inflammatory properties of ASCs may be useful in developing future therapies for IVD degeneration. No conflicts of interest. Sources of funding: EPSRC-MRC Centre for Doctoral Training in Regenerative Medicine (EP/L014904/1)

Background and Purpose. Intervertebral disc (IVD) degeneration is a prominent cause of low back pain. IVD cells expressing angiopoietin-1 receptor Tie2 represent a progenitor cell population which decreases with progression of IVD degeneration. Homing of mesenchymal stem cells (MSCs) is a physiological mechanism aiming to enhance the regenerative capacity of the IVD. The purpose of this study was to assess the effect of MSC homing on the Tie2 positive IVD progenitor cell population, the IVD cell viability, and the proliferative phenotype of the IVD cells. Methods and Results. Human MSCs were isolated from bone marrow aspirates and labelled with fluorescent dye. Whole IVDs with endplates were harvested from bovine tails; MSCs were placed on the endplates. Human traumatic, degenerative and healthy IVD tissues were obtained from patients and organ donors. MSCs were added onto tissue samples. After 5 days, IVD cells were isolated. Percentages of Tie2 positive, DAPI positive (dead) and Ki-67 positive (proliferative) IVD cells were determined. MSC homing or co-culture significantly increased the proportion of Tie2 positive progenitor IVD cells in bovine and 7/10 human IVDs, decreased the fraction of dead IVD cells in bovine and 7/10 human IVDs, and induced a proliferative phenotype in bovine and 5/6 human IVDs. Conclusion. Stimulation of bovine and human IVDs by MSC homing resulted in an enhanced population of Tie2 positive IVD progenitor cells, induced a proliferative response and reduced IVD cell death. Hence, the interaction with recruited MSCs may contribute to an improved survival of IVD cells, helping to reverse or slow down an ongoing degenerative process. Conflicts of interest: The authors declare no conflicts of interest. Sources of funding: AO Foundation and AOSpine International

Introduction. Injectable hydrogels via minimally invasive surgery reduce the risk of infection, scar formation and the cost of treatment. Degradation of the intervertebral disc (IVD) currently has no preventative treatment. An injectable hydrogel material could restore disc height, reinforce local mechanical properties, and promote tissue regeneration. We present a hydrogel material Laponite. ®. associated poly(N-isopropylacrylamide)-co-poly(dimethylacrylamide) (NPGel). Understanding how the components of this hydrogel system influence material properties, is crucial for tailoring treatment strategies for the IVD and other tissues. Methods & Results. The effect of hydrogel wt./wt., clay and co-monomer percentages were assessed using a box-Behnken design. Rheometry, SEM, FTIR and swelling was used to measure changes in material properties in simulated physiological conditions. Rheometry revealed gelation temperature of hydrogel materials could be modified with dimethyl-acrylamide co-monomer; however, final maximum mechanical properties remained unaffected. Increasing the weight % and clay % increased resultant mechanical properties from ∼500–2500 G' (Pa), increased viscosity, but retained the ability to flow through a 26G needle at 39°C. Discussion & Conclusions. By increasing the weight and clay percentage of the material we can attain greater mechanical properties, this could be beneficial for orthopaedic or even dental applications. By modifying the co-monomer percentage, we can control gelation temperature important for ensuring the material is fully set at 37°C, this could also be utilised to locally deliver drugs from the implanted material. Our current work is focused on comparing our NPGel material formulation with human IVD tissue. Acknowledgements. We would like to thank Arthritis Research UK grant number 21497 for supporting this research. No conflicts of interest. Sources of Funding: Funded by Arthritis Research UK grant number 21497

Background. While the human embryonic, foetal and juvenile intervertebral disc (IVD) is composed of large vacuolated notochordal cells, these morphologically distinct cells are lost with skeletal maturity being replaced by smaller nucleus pulpous cells. Notochordal cells are thought to be fundamental in maintaining IVD homeostasis and, hence, their loss in humans may be a key initiator of degeneration, leading ultimately to back pain. Therefore, it is essential to understand the human notochordal cell phenotype to enable the development of novel biological/regenerative therapies. Methods. CD24+ notochordal cells and CD24- sclerotomal cells were sorted from enzymatically-digested human foetal spines (7.5–14 WPC, n=5) using FACS. Sorting accuracy was validated using qPCR for known notochordal markers and Affymetrix cDNA microarrays performed. Differential gene expression was confirmed (qPCR) and Interactive Pathway Analysis (IPA) performed. Results. CD24+ve notochordal cells (mean 10.4%) and CD24-ve sclerotomal cells (mean 60.9% CD24-) were successfully sorted. Higher expression of notochordal markers CD24 and brachyury was identified in CD24+ve cells. Hierarchical clustering and PCA mapping revealed distinct differences in the gene expression profile of CD24+ and CD24- cells. Top notochordal markers were CD24, STMN2. RTN1, PRPH and CXCL12. IPA identified IL-1 receptor antagonist (IL-1RN) and noggin as master regulators of notochordal cell phenotype. Conclusions. This study has, for the first time, defined human foetal notochordal cell phenotype and identified important pathways and upstream regulators. In particular, IL-1RN and noggin are of interest as master regulators of notochordal cell function, suggesting vital roles for these molecules in IVD development and homeostasis. Conflicts of interest. No conflicts of interest. Sources of funding. We would like to acknowledge UKRMP Acellular Hub, MRC, NIHR Musculoskeletal BRU and The Rosetrees Trust for funding this research

Introduction. During development the central disc contains large, vacuolated notochordal (NC) cells which in humans are replaced by mature nucleus pulposus (NP) cells during aging, but are maintained in certain breeds of dogs. During degeneration the disc becomes less hydrated which affects its normal function. Aquaporins (AQP) are a family of 13 transmembrane channel proteins that allow passage of water and are responsible for maintaining water homeostasis. AQP1, 2, 3 and 5 have been identified in the intervertebral disc (IVD). Here, expression of AQPs in human and canine IVDs to determine expression in NC v/s NP cells and whether expression changes during degeneration. Methods. Gene expression of all 13 AQPs, were investigated in 102 human NP samples using RT-qPCR. AQPs which were expressed at gene level were further investigated by Immunohistochemistry in human and canine IVD samples. Results. At gene level, AQP0, 1, 2, 3, 4, 5, 6, 7 and 9 were expressed in both non-degenerate and degenerate tissue. For the first time, protein expression of AQP0, 4, 6, 7 and 9 was identified in human IVD tissue, AQP 1, 4 and 5 protein expression decreased during degeneration whilst AQP 7 was increased. AQPs were also expressed in canine IVD tissue, particularly within NC cell populations. Conclusion. Hydration of the IVD is vital for its correct biomechanical function and water loss is associated with degeneration. The presence of many AQP isoforms within NC and NP cells may suggest multiple roles related to the development, survival and adaptation of native cells, and physiology of the healthy IVD. No conflicts of interest. Funded by BMRC, Sheffield Hallam University