Purpose of study and background. IVD degeneration is a major cause of Low back pain. We have previously reported an injectable hydrogel (NPgel), which induces differentiation of human MSCs to disc cells and integrates with NP tissue following injection in vitro. However, the translation of this potential treatment strategy into clinic is dependent on survival and differentiation of MSCs into disc cells within the degenerate IVD. Here, we investigated the viability and differentiation of hMSCs incorporated into NPgel cultured under conditions mimicking the healthy and degenerate microenvironment of the disc. Methods and Results. MSCs were cultured in NP gel under 5% O. 2. in either: standard culture (DMEM, pH7.4); healthy disc (DMEM, pH7.1); degenerate disc (low glucose DMEM, pH6) or degenerate disc plus IL-1β. Following 4 weeks histological staining and immunohistochemical analysis investigated viability, ECM synthesis and matrix degrading enzyme expression. Here we have shown that viability and NP cell differentiation of MSCs incorporated within NPgel was mostly unaffected by treatment with conditions such as low glucose, low pH and the presence of cytokines, all regarded as key contributors to disc degeneration. In addition, the NPgel was shown to prevent MSCs from displaying a catabolic phenotype with low expression of degradative enzymes, highlighting the potential of NPgel to differentiate hMSCs and protect them from the degenerate disc microenvironment. Conclusion. The NPgel described here not only has the potential to provide mechanical support and deliver MSCs for regeneration of the IVD but also may simultaneously function to protect delivered hMSCs from the catabolic environment in the degenerate IVD. C Le Maitre and C Sammon hold a patent for the hydrogel described. Funded by MRC and Versus Arthritis

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. 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

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

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

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. Mesenchymal stem cells (MSCs) are undergoing evaluation as a potential new therapy for immune and inflammatory-mediated conditions such as IVD degeneration (IDD). Both adipose (ASCs) and bone-marrow (BMSCs) derived MSCs have been widely used in this regard. The optimal tissue source and expansion conditions required to exploit the regenerative capacity of these cells are not yet fully elucidated. In addition the phenotypic response of transplanted cells to the disease environment is not well understood. In this study, ASCs and BMSCs were exposed to a combination of hypoxic conditioning and selected inflammatory mediators, conditions that mimic the microenvironment of the degenerate IVD, in an effort to understand their therapeutic potency for in vivo administration. Methods and Results. Donor-matched ASCs and MSCs were pre-conditioned with either IL-1β (10ng/ml) or TNFα (10ng/ml) for 48 hours under hypoxic conditions (5% O. 2. ). Conditioned media was collected and 45 different immunomodulatory proteins were analysed using human magnetic Luminex® assay. Secreted levels of several key cytokines and chemokines, both pro- and anti-inflammatory, were significantly upregulated in ASCs and BMSCs following the conditioning regime. Under all conditions tested, ASCs expressed significantly higher levels of IL-4, IL-6, IL-10, IL-12, TGF-α, and GCSF compared to BMSCs. Pre-conditioning with TNFα resulted in significantly higher levels of IL-10 while preconditioning with IL-1β resulted in higher levels of IL-6, IL-12 and GCSF. Conclusion. These data suggest that pre-conditioned ASCs may have enhanced therapeutic potential in modulating IVD repair through the increased release of trophic factors that play a role in immunomodulation. Conflicts of interest: None. Sources of funding: Financial support for this research was provided by EU Horizon 2020 RESPINE grant (Project ID# 732163)

Background. Auxetic materials have a negative poisons ratio, and a number of native biological tissues are proposed to possess auxetic properties. One such tissue is annulus fibrosus (AF), the fibrous outer layers of the intervertebral disc (IVD). However, few studies to date have investigated the potential of these materials as tissue engineering scaffolds. Here we describe the potential of manually converted polyurethane (PU) foams as three dimensional cellular scaffolds for AF repair. Methods. Rat MSCs were seeded onto fibronectin coated auxetic foams at a cell density of 6.4 × 10. 3. cells/mm. 3. , and cultured for up to 3 weeks. Cell viability was assessed throughout culture and following culture scanning electron microscopy (SEM) was used to assess morphological characteristics. Histological assessment was performed to assess production of matrix proteins. Results. Cells adhered to the surface auxetic foams and remained viable for the 3 weeks investigated. Histology and SEM demonstrated cells within the full thickness of the auxetic foams, where extracellular matrix was starting to be produced following 3 weeks, including collagens suggesting differentiation of the MSCs. Conclusion. Auxetic PU foams have a significant potential for use in tissue engineering applications, potentially mimicking the multiaxial strains of annulus fibrous tissue. MSCs were shown to adhere, survive and produce matrix within the foams after 3 weeks, future work will focus on longer term studies and in depth analysis of the phenotype of the cells. No conflicts of interest. Funding provided by a grant from Sheffield Children's Hospital NHS trust

Background. We have reported an injectable L-pNIPAM-co-DMAc hydrogel with hydroxyaptite nanoparticles (HAPna) which promotes mesenchymal stem cell (MSC) differentiation to bone cells without the need for growth factors. This hydrogel could potentially be used as an osteogenic and osteoconductive bone filler of spinal cages to improve vertebral body fusion. Here we investigated the biocompatibility and efficacy of the hydrogel in vivo using a proof of concept femur defect model. Methods. Rat sub-cut analysis was performed to investigate safety in vivo. A rat femur defect model was performed to evaluate efficacy. Four groups were investigated: sham operated controls; acellular L-pNIPAM-co-DMAc hydrogel; acellular L-pNIPAM-co-DMAc hydrogel with HAPna; L-pNIPAM-co-DMAc hydrogel with rat MSCs and HAPna. Following 4 weeks, defect site and organs were histologically examined to determine integration, repair and inflammatory response, as well as Micro-CT to assess mineralisation. Results. No inflammatory reactions or toxicity were seen in any animal. Enhanced bone healing was observed in aged exbreeder female rats where hydrogel was injected with increased deposition of collagen type I. Integration of the hydrogel with surrounding bone was observed without the need for delivered MSCs; native cell infiltration was also seen and bone formation was observed within all hydrogel systems investigated. Conclusion. This novel hydrogel is biocompatible, facilitates migration of cells, promotes increased bone formation and integrates with surrounding bone. This system could be injected to fill spaces within and surrounding spinal cages to aid in cage fixation and spinal fusion without the need for harvesting of bone autografts, thus reducing operative risk and surgical cost. Conflicts of Interest: None. Source of Funding: BMRC, MERI Sheffield Hallam University

Introduction. Low back pain is the leading cause of musculoskeletal disease and the biggest cause of morbidity worldwide. Approximately 40% of these are cases are caused by disease of the intervertebral discs (IVDs): the shock absorbing, flexible material located between the bones (vertebrae) along the length of the spine. In severe cases, the spine becomes unstable and it becomes necessary to immobilise or fix the joint in position using a lumbar cage spacer between in the IVD and metal pins with supporting plates in the vertebrae. This is a complex, expensive, major surgery and it is associated with complications, such as spinal fusion failure and inappropriate implant position. These complications have a dramatic impact on the quality of life of the affected patients and the burden to society and the healthcare system is exacerbated. Methods and Results. We present an in vitro study looking at the effect of our Bgel hydrogel on mesenchymal stem cells (MSCs) and their bone forming capacity within lumbar cages: devices used to space the bones apart in the fusion operation, as a mechanism to improve fixation and intra cage bone formation. MSCs were isolated from human hip joint, expanded, seeded within Bgel, cast into well inserts or lumbar cages and cultured for 4 weeks. Using 3D X-ray imaging micro computed tomography (μCT) scans we show that the MSC in the presence Bgel begin to mineralise within the lumbar cages. Histology is currently ongoing and will be presented at the meeting. Conclusion. This study shows the potential to improve current spinal fusion practices with the potential to reduce complications. 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

Aims

Non-coding microRNA (miRNA) in extracellular vesicles (EVs) derived from mesenchymal stem cells (MSCs) may promote neuronal repair after spinal cord injury (SCI). In this paper we report on the effects of MSC-EV-microRNA-381 (miR-381) in a rodent model of SCI.

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

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

This article reviews the current knowledge of the intervertebral disc (IVD) and its association with low back pain (LBP). The normal IVD is a largely avascular and aneural structure with a high water content, its nutrients mainly diffusing through the end plates. IVD degeneration occurs when its cells die or become dysfunctional, notably in an acidic environment. In the process of degeneration, the IVD becomes dehydrated and vascularised, and there is an ingrowth of nerves. Although not universally the case, the altered physiology of the IVD is believed to precede or be associated with many clinical symptoms or conditions including low back and/or lower limb pain, paraesthesia, spinal stenosis and disc herniation.

New treatment options have been developed in recent years. These include biological therapies and novel surgical techniques (such as total disc replacement), although many of these are still in their experimental phase. Central to developing further methods of treatment is the need for effective ways in which to assess patients and measure their outcomes. However, significant difficulties remain and it is therefore an appropriate time to be further investigating the scientific basis of and treatment of LBP.