Introduction. Current strategies to treat back pain address the symptoms but not the underlying cause. Here we are investigating a novel hydrogel material (NPgel) which can promote MSC differentiation to Nucleus pulposus cells. Current in vitro studies have only explored conditions that mimic the native disc microenvironment. Here, we aim to determine the stem cells regenerative capacity under conditions that mimic the degenerate environment seen during disc degeneration. Methods. hMSCs were encapsulated in NPgel and cultured for 4 weeks under hypoxia (5%) with ± calcium (2.5mM and 5.0mM CaCl. 2. ), IL-1β and TNFα either individually or in combination to mimic the degenerate microenvironment. Cell viability was assessed by Alamar blue assay. Histological and immunohistochemical analysis investigated altered matrix and matrix degrading enzyme expression. Results. Viability of hMSCs was maintained under all culture conditions. Matrix deposition of glycosaminoglycans were observed under all conditions, MMP13 expression was upregulated by calcium but not by pro-inflammatory cytokines IL-1β and TNFα. Conclusions. We are developing an in vitro modelling system which can be used to test novel therapies within a degenerate microenvironment. Interestingly, our preliminary findings suggest calcium is a major contributor to regulating MMP13 in this model system. Investigating the degenerate niche will identify targets for inhibition to provide the correct niche to promote regeneration of the IVD. No conflict of interest. Funding: BMRC, MERI Sheffield Hallam University, for joint funding the Daphne Jackson Trust fellowship

Introduction. Within the intervertebral disc (IVD), nucleus pulposus (NP) cells reside within a unique microenvironment. Factors such as hypoxia, osmolality, pH and the presence of cytokines all dictate the function of NP cells and as such the cells must adapt to their environment to survive. Previously we have identified the expression of aquaporins (AQP) within human IVD tissue. AQPs allow the movement of water across the cell membrane and are important in cellular homeostasis. Here we investigated how AQP gene expression was regulated by the microenvironment of the IVD. Methods. Human NP cells were cultured in alginate beads prior to cytokine, osmolality, pH and hypoxia treatments and subsequent RT-qPCR to assess regulation of AQP gene expression. Results. Physiological conditions observed within the native IVD regulated AQP gene expression in human NP cells. Hyperosmotic treatment up-regulated the expression of AQP1 and 5 during hypoxic conditions, whereas AQP4 expression was down-regulated. During hypoxia and physiological pH treatments AQP5 expression was increased. Pro-inflammatory cytokines, increased during IVD degeneration, also altered AQP gene expression. Interleukin-1β (IL-1β) decreased expression of AQP1 and 3 yet up-regulated AQP9, interleukin-6 (IL-6) increased expression of AQP1, 3, and 9 and tumour necrosis factor α (TNFα) upregulated the gene expression of both AQP2 and 9. Conclusion. The microenvironment in which NP cells reside in vivo directly contributes to their correct function and survival. AQP gene expression was differentially regulated under healthy compared to degenerate conditions; this potentially highlights that during IVD degeneration NP cells differentially express AQPs. No conflicts of interest. Funded by BMRC, Sheffield Hallam University

This review provides a concise outline of the advances made in the care of patients and to the quality of life after a traumatic spinal cord injury (SCI) over the last century. Despite these improvements reversal of the neurological injury is not yet possible. Instead, current treatment is limited to providing symptomatic relief, avoiding secondary insults and preventing additional sequelae. However, with an ever-advancing technology and deeper understanding of the damaged spinal cord, this appears increasingly conceivable. A brief synopsis of the most prominent challenges facing both clinicians and research scientists in developing functional treatments for a progressively complex injury are presented. Moreover, the multiple mechanisms by which damage propagates many months after the original injury requires a multifaceted approach to ameliorate the human spinal cord. We discuss potential methods to protect the spinal cord from damage, and to manipulate the inherent inhibition of the spinal cord to regeneration and repair. Although acute and chronic SCI share common final pathways resulting in cell death and neurological deficits, the underlying putative mechanisms of chronic SCI and the treatments are not covered in this review.