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

Spinal deformity surgery carries the risk of neurological injury. Neurophysiological monitoring allows early identification of intraoperative cord injury which enables early intervention resulting in a better prognosis. Although multimodal monitoring is the ideal, resource constraints make surgeon-directed intraoperative transcranial motor evoked potential (TcMEP) monitoring a useful compromise. Our experience using surgeon-directed TcMEP is presented in terms of viability, safety, and efficacy.

Aims

The aim of this retrospective study was to compare the correction achieved using a convex pedicle screw technique and a low implant density achieved using periapical concave-sided screws and a high implant density. We hypothesized that there would be no difference in outcome between the two techniques.

Introduction. Adolescent idiopathic scoliosis (AIS) is associated with low bone mineral density, which could be related to its etiopathogenesis. Apart from bone density, bone micro-architectures are equally important for better understanding of disease initiation and progression in AIS. Quantitative assessment of bone quality is hampered by the invasive nature of investigations, until recently when the high-resolution pQCT (XtremeCT) became available for revolutionary in-vivo microimaging and derivation of bone micro-architectural parameters. Our objective was to use this powerful instrument to study bone qualities in AIS and compare findings with those from healthy controls. Methods. 48 girls with AIS and 84 sex-matched healthy controls were recruited. Cobb angle was measured with standing radiographs, and imaging of the non-dominant distal radius was captured with XtremeCT according to a standard protocol. Results. The mean age was 13·48 years for controls and 13·54 years for patients with AIS (p=0·773). The mean Cobb's angle for AIS was 32·7° (SD 5·8°). Volumetric bone density, cortical thickness, trabecular bone density, meta-trabecular density, inner-trabecular density, bone volume fraction, and trabecular thickness were all lower in patients with AIS than in controls, and differences were statistically significant (p<0·05). Conclusions. This is the first report describing the differences in radiographic bone micro-architectures between patients with AIS and controls. All significant parameters were lower in the AIS group, indicating deranged bony quality that could have an important role in disease initiation or progression in AIS. The exact biomechanical process and how this is related to the etiopathogenesis of AIS warrant further studies. Acknowledgments. This study is supported by RGC-HKSAR (project number 467808 and 468809)

Aims

To investigate metallosis in patients with magnetically controlled growing rods (MCGRs) and characterize the metal particle profile of the tissues surrounding the rod.

Wrong-level surgery is a unique pitfall in spinal surgery and is part of the wider field of wrong-site surgery. Wrong-site surgery affects both patients and surgeons and has received much media attention. We performed this systematic review to determine the incidence and prevalence of wrong-level procedures in spinal surgery and to identify effective prevention strategies. We retrieved 12 studies reporting the incidence or prevalence of wrong-site surgery and that provided information about prevention strategies. Of these, ten studies were performed on patients undergoing lumbar spine surgery and two on patients undergoing lumbar, thoracic or cervical spine procedures. A higher frequency of wrong-level surgery in lumbar procedures than in cervical procedures was found. Only one study assessed preventative strategies for wrong-site surgery, demonstrating that current site-verification protocols did not prevent about one-third of the cases. The current literature does not provide a definitive estimate of the occurrence of wrong-site spinal surgery, and there is no published evidence to support the effectiveness of site-verification protocols. Further prevention strategies need to be developed to reduce the risk of wrong-site surgery.