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. 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

Background. Current clinical treatment for spinal instability requires invasive spinal fusion with cages and screw instrumentation. We previously reported a novel injectable hydrogel (Bgel), which supports the delivery and differentiation of mesenchymal stem cells (MSCs) to bone forming cells and supports bone formation in vivo. Here, we investigated whether this system could be utilised to induce bone formation within intervertebral disc tissue as a potential injectable spinal fusion approach. Methodology. Bovine and Human Nucleus pulpous tissue explants were injected with Bgel with and without MSCs. Tissue samples were cultured under hypoxia (5%) in standard culture media for 4 weeks. Cell viability, histological assessment of matrix deposition, calcium formation, and cell phenotype analysis using immunohistochemistry for NP matrix and bone markers. Results. Following injection of B-gel into tissue explants following culture for 4 weeks, cells were visualized within the regions of the B-gel. Demonstrating that native cells were able to migrate into regions of B-gel. Increased collagen deposition was seen in tissue explants injected with Bgel, with increased collagen type I and X but decreased collagen type II staining in explants injected with Bgel. Tissue explants, in the absence of Bgel, showed limited calcium deposition, which was increased in B-gel injected explants. Furthermore, disc cells increased expression of bone markers (alkaline phosphatase & osteocalcin), but decreased NP matrix (Aggrecan and Collagen type II) following Bgel injection. Conclusion. This system could have potential to support spinal fusion via direct injection into the disc. Conflict of interest: C Le Maitre & C Sammon are inventors on the hydrogel discussed. Funding: This work was funded by GrowMed Tech Proof of Concept funding

Background. Degeneration of the intervertebral disc (IVD) is a major cause of Low back pain. We have recently reported a novel, injectable liquid L-pNIPAM-co-DMAc hydrogel (NPgel), which promote differentiation of MSCs to nucleus pulposus (NP) cells without the need for additional growth factors. Here, we investigated the behaviour of hMSCs incorporated within the hydrogel injected into NP tissue. Methods. hMSCs were injected either alone or within NPgel, into bovine NP tissue explants and maintained at 5% O. 2. for up to 6wks. Media alone and acellular NPgel were also injected into NP explants to serve as controls. Cell viability was assessed by Caspase 3 immunohistochemistry and the phenotype of injected hMSC was assessed by histology and immunohistochemistry. Mechanical properties were also assessed via dynamic mechanical analysis (DMA). Results. No significant difference in the elastic modulus was observed between NPgel injected NP tissue and media injected controls. CFSe positive hMSCs were identified in all injected tissue samples and cell viability was maintained. Where hMSCs were delivered via NPgel, the hydrogel integrated with native NP tissue and cells producing NP matrix components: aggrecan; collagen type II and chondroitin sulphate. Conclusion. hMSC incorporated within L-pNIPAM-co-DMAc hydrogel and injected into NP explants, integrate with native NP tissue and promote differentiation towards the NP phenotype; thus potentially could be used to regenerate the NP as a treatment strategy for LBP. No conflict of interest. Funding: BMRC, MERI Sheffield Hallam University

Purpose of study and background. We have previously reported the development of injectable hydrogels for potential disc regeneration (NPgel) or bone formation which could be utilized in spinal fusion (Bgel). As there are multiple sources of mesenchymal stem cells (MSCs), this study investigated the incorporation of patient matched hMSCs derived from adipose tissue (AD) and bone marrow (BM) to determine their ability to differentiate within both hydrogel systems under different culture conditions. Methods and Results. Human fat pad and bone marrow derived MSCs were isolated from femoral heads of patients undergoing hip replacement surgery for osteoarthritis with informed consent. MSCs were encapsulated into either NPgel or Bgel and cultured for up to 6 weeks in 5% (NPgel) or 21% (Bgel) O. 2. Histology and immunohistochemistry was utilized to determine phenotype. Both fat and bone marrow derived MSCs, were able to differentiate into both cell lineages. NPgel culture conditions increased expression of matrix components such as collagen II and aggrecan and NP phenotypic markers FOXF1 and PAX1, whereas Bgel induced expression of collagen I and osteopontin, indicative of osteogenic differentiation. Conclusion. NPgel and Bgel were able to differentiate patient derived MSCs from different sources into both NP and osteogenic lineages, which may give rise to novel treatment strategies for IVD degeneration and spinal fusion, enabling choice for cell source according to patients' circumstances and needs. C Le Maitre and C Sammon hold a patent for the hydrogel described. Funded by MRC and Versus Arthritis

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

Purpose and Background. The intervertebral disc is constantly subjected to forces generated by movement. But degeneration can disrupt normal biomechanics, generating uneven and complex loading patterns. Evidence suggests that these forces are converted into voltages through different mechanisms, such as streaming potentials. This implicates voltage-gated ion channels in the biological remodelling response of the disc to loading. These signalling pathways have not been studied, and this incomplete understanding of disc mechanotransduction may hinder regenerative therapies. The purpose of this study is to identify and determine the role of voltage-gated ion channels in the intervertebral disc and to investigate any changes in degeneration. Methods and Results. Primary bovine and human disc cells were cultured in monolayer or alginate beads for experiments. Cells were treated with altered osmolarity alone or in combination with IL-1β. Ion flux was measured through calcium influx and will be further investigated using the xCelligence RTCA CardioECR. Immunohistochemistry was performed on human and bovine discs to evaluate expression levels of ion channels. RNA was extracted from bovine NP cells and will be analysed through PCR/Microarray for gene expression. Conclusions. Preliminary results show that the Ca. v. 2.2 channel is expressed across the human disc, and is altered by degree of degeneration. Treatment with IL-1β may partly hinder the increase in calcium signalling of disc cells in response to lower osmolarity conditions. The presence of voltage-gated ion channels in the disc has been demonstrated for the first time. The role of these channels will be investigated through measuring ion flux with channel inhibitors across different culture treatments. No conflicts of interest exist. This research was supported by funding from the Society for Back Pain Research through the Travel Award 2019 and from the Irish Research Council under the Government of Ireland Postgraduate Scholarship Programme (GOIPG/2018/2416)

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

Aims

This study was performed to explore the effect of melatonin on pyroptosis in nucleus pulposus cells (NPCs) and the underlying mechanism of that effect.

Background. Stem cell therapy has been suggested as a potential regenerative strategy to treat IVD degeneration and GDF6 has been shown to differentiate adipose-derived stem cells (ASCs) into an NP-like phenotype. However, for clinical translation, a delivery system is required to ensure controlled and sustained GDF6 release. This study aimed to investigate the encapsulation of GDF6 inside novel microparticles (MPs) to control delivery and assess the effect of the released GDF6 on NP-like differentiation of human ASCs. Methods. GDF6 release from PLGA-PEG-PLGA MPs over 14 days was determined using BCA and ELISA. The effect of MP loading density on collagen gel formation was assessed through SEM and histological staining. ASCs were cultured in collagen hydrogels for 14 days with GDF6 delivered exogenously or via microspheres. ASC differentiation was assessed by qPCR for NP markers, glycosaminoglycan production (DMMB) and immunohistochemistry. Results. GDF6 release from MPs was controlled over 14 days equivalently to exogenous addition. SEM and histology confirmed that MPs were distributed throughout gels and that gel formation was not disrupted. In 3D cultures, GDF6 release from microspheres elicited equivalent ASC differentiation and NP-like matrix formation compared to exogenous delivery in media, indicating activity was not affected by MP encapsulation. Conclusions. This study demonstrates the effective encapsulation and controlled delivery of GDF6, which was able to maintain its activity and induce ASC differentiation into an NP-like phenotype and production of an NP-like ECM. Delivery of GDF6 microspheres in combination with ASCs is a promising strategy for IVD regeneration and treatment of back pain. 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

Background. Intervertebral disc (IVD) degeneration is a major cause of Low back pain (LBP). We have reported an injectable hydrogel (NPgel), which following injection into bovine NP explants, integrates with NP tissue and promotes NP cell differentiation of delivered mesenchymal stem cells (MSCs) without growth factors. Here we investigated the injection of NPgel+MSCs into bovine NP explants under degenerate culture conditions to mimic the in vivo environment of the degenerate IVD. Methods. hMSCs were incorporated within liquid NPgel and injected into bovine NP explants alongside controls. Explants were cultured for 6 weeks under hypoxia (5%) with ± calcium 5.0mM CaCl. 2. or IL-1β individually or in combination to mimic the degenerate microenvironment. Cell viability was assessed by caspase 3 immunohistochemistry. Histological and immunohistochemical analysis was performed to investigate altered matrix synthesis and matrix degrading enzyme expression. Results. CFSe positive hMSCs were identified in all NPgel injected explants and cell viability was maintained. The NPgel integrated with NP tissue and hMSCs produced matrix components: aggrecan, collagen type II and chondroitin sulphate in standard and degenerate culture conditions. Increased cellular immunopositivty for aggrecan and collagen type II as well as decreased cellular immunopositivity for degrading enzyme expression was observed within NP tissue removed from the injection site. Conclusion. MSCs incorporated within NPgel could be used to regenerate the NP and restore the healthy NP phenotype of degenerate NP cells as a treatment strategy for LBP. We are currently investigating the survival and differentiation capacity of hMSCs delivered via the NPgel into degenerate human NP explants and thus ascertain the future clinical success of this therapy. Conflicts of Interest: None. Funding: BMRC, MERI Sheffield Hallam University

Introduction. The intervertebral disc (IVD) is a highly hydrated tissue which is reduced during degeneration leading to loss of function. Aquaporins (AQP) are a family of 13 (AQP0-12) transmembrane channel proteins that selectively allow the passage of water and other small molecules in and out of cells and are responsible for maintaining water homeostasis. AQP1, 2, 3 and 5 have been identified in the IVD. Here gene and protein expression of all 13 AQPs was investigated in a large cohort of human IVDs to investigate expression during IVD degeneration. Methods. Gene expression of all 13 AQPs was investigated in non-degenerate and degenerate tissue from 102 human NP samples using RT-qPCR. AQPs which were expressed at gene level were further investigated in 30 IVD samples by Immunohistochemistry. 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 AQP6, 7 and 9 was identified in human IVD tissue, in which AQP2 and 3 were also identified. Conclusion. Hydration of the IVD is vital for its correct biomechanical function and a loss of water is associated with degeneration. The presence of many AQP isoforms within IVDs may suggest multiple roles for these water channels related to the survival and adaptation of NP cells, and physiology of the healthy IVD. The functional role of AQPs within the IVD is yet to be elucidated and thus warrants further investigation. No conflicts of interest. Funded by BMRC, Sheffield Hallam University

The belief that an intervertebral disc must degenerate before it can herniate has clinical and medicolegal significance, but lacks scientific validity. We hypothesised that tissue changes in herniated discs differ from those in discs that degenerate without herniation. Tissues were obtained at surgery from 21 herniated discs and 11 non-herniated discs of similar degeneration as assessed by the Pfirrmann grade. Thin sections were graded histologically, and certain features were quantified using immunofluorescence combined with confocal microscopy and image analysis. Herniated and degenerated tissues were compared separately for each tissue type: nucleus, inner annulus and outer annulus.

Herniated tissues showed significantly greater proteoglycan loss (outer annulus), neovascularisation (annulus), innervation (annulus), cellularity/inflammation (annulus) and expression of matrix-degrading enzymes (inner annulus) than degenerated discs. No significant differences were seen in the nucleus tissue from herniated and degenerated discs. Degenerative changes start in the nucleus, so it seems unlikely that advanced degeneration caused herniation in 21 of these 32 discs. On the contrary, specific changes in the annulus can be interpreted as the consequences of herniation, when disruption allows local swelling, proteoglycan loss, and the ingrowth of blood vessels, nerves and inflammatory cells.

In conclusion, it should not be assumed that degenerative changes always precede disc herniation.

Cite this article: Bone Joint J 2013;95-B:1127–33.

We have treated 175 patients with a chordoma over a ten-year period. Only two had a family history of the condition and we describe these in this paper. In one patient the tumour was at the craniocervical junction and in the other the lesion affected the sacrum. We have undertaken a literature review of familial chordoma and have identified chromosomal abnormalities associated with the condition.