Abstract. Objectives. Spinal disorders such as back pain incur a substantial societal and economic burden. Unfortunately, there is lack of understanding and treatment of these disorders are further impeded by the inability to assess spinal forces in vivo. The aim of this project is to address this challenge by developing and testing a novel image-driven approach that will assess the forces in an individual's spine in vivo by incorporating information acquired from multimodal imaging (magnetic resonance imaging (MRI) and biplane X-rays) in a subject-specific model. Methods. Magnetic resonance and biplane X-ray imaging are used to capture information about the anatomy, tissues, and motion of an individual's spine as they perform a range of everyday activities. This information is then utilised in a subject-specific computational model based on the finite element method to predict the forces in their spine. The project is also utilising novel machine learning algorithms and in vitro, six-axis mechanical testing on human, porcine and bovine samples to develop and test the modelling methods rigorously. Results & Discussion. MRI sequences have been identified that provide high-quality image data and information on different tissue types which will be used to predict subject-specific disc properties. In-vivo protocols to capture motion analysis, EMG muscle activity, and video X-rays of the spine have been designed with planned data collection of 15 healthy volunteers. Preliminary modelling work has evaluated potential machine learning approaches and quantified the sensitivity of the models developed to material properties. Conclusion. The development and testing of these image-driven subject-specific spine models will provide a new tool for determining forces in the spine. It will also provide new tools for measuring and modelling spine movement and quantifying the properties of the spinal tissues. Acknowledgments. Funding from the EPSRC: EP/V036602/1 (Meakin, Holsgrove & Javadi) and EP/V032275/1 (Holt & Williams). Declaration of Interest. (b) declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported:I declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research project

Patellar tendinosis (PT) is common and can result in prolonged disability, especially in jumping athletes. Recently developed ultra-short-echo (UTE) MRI sequences allow for quantitative evaluation of tendon biostructure with T2* relaxometry. This study evaluated the relationships between changes over time (COT) in quantitative T2*-metrics, qualitative PT grades, and patient reported symptoms within 10 male basketball players from a single collegiate basketball team. All subjects completed weekly VISA-P symptomology questionnaires over the basketball season. Bilateral 3-Tesla MRIs (GE Healthcare) were obtained at pre- and post-season study visits. High-resolution, PD-weighted, FSE sequences were used to qualitatively grade PT. Quantitative T2*-metrics were evaluated using high-resolution, 3D, multi-echo, UTE-MRI sequences. Bilinear exponential fits of SI to corresponding echo time were used to calculate T2*-metrics. All qualitative and quantitative evaluations were region specific (proximal, middle, distal). Linear mixed effects models assessed associations of side and region with T2*-metrics. Spearman correlations evaluated relationships between outcome measures. Within and between study visits, significant side-to-side differences in T2*-metrics were found and were significantly impacted by leg dominance (p<0.05). Pre-season T2*-metrics correlated with COT in T2*-metrics, COT in T2*-metrics correlated with COT in qualitative PT grades, and post-season T2*-metrics correlated with max changes in VISA-P scores (ρ≥0.64). Quantitative T2*-metrics can detect PT and may be capable of predicting the onset of pathology. T2*-metrics could benefit the clinical management of PT: it is sensitive to changes in pathologic severity over time, and therefore can serve as a quantitative metric to guide treatment and evaluate intervention efficacy

Summary. A novel bipolar cooled radiofrequency ablation probe, optimised for bone metastases applications, is shown in two preclinical models to offer a safe and minimally invasive treatment option that can ablate large tissue volumes and preserve the regenerative ability of bone. Introduction. Use of radiofrequency ablation (RFA) in treating of skeletal metastases has been rising, yet its impact on bone tissue is poorly understood. 2–11 RF treatment induces frictional heating and effectively necrotises tissue in a local and minimally invasive manner.1 Bipolar cooled RF (BCRF) is a significant improvement to conventional RF whereby larger regions can be safely treated, protecting sensitive neighbouring tissues from thermal effects. This study aimed to evaluate the safety and feasibility of a novel bipolar RFA probe to create large contained lesions within healthy pig vertebrae and its determine its effects on bone and tumour cells in a rabbit long bone tumour model. Methods. Following a pre-treatment MRI, a BCRF probe was placed transpedicularly into targeted lumbar vertebrae of six Yorkshire pigs. Energy was delivered for 15min at a set temperature of 65°C (n=2 per animal) with a sham control performed at a non-contiguous level (n=1 per animal). Post-treatment neurologic evaluation, MRI and histology were used to characterise the region of effect. Twelve New Zealand White Rabbits received a 200 µl injection of VX2 tumour cells into one femur. On day 14, half of the tumour-bearing and contralateral healthy femora were RF-treated (n=6 per group). RF-treated femora were compared to tumour-bearing and healthy sham groups (n=6 per group) through pre (day 14) and post treatment (day 28) MRI and histology (H&E (for general evaluation), AE1/AE3 (for VX2 tumour cell evaluation), TRAP (for osteoclast evaluation) and TUNEL (for osteocyte evaluation)). Results. In treated porcine spines there were no neurological complications. MR imaging confirmed a 2cm oval shaped ablative zone. External thermocouple measurements indicated output values in the physiological temperature range suggesting treatment was safely confined within targeted vertebrae. Histological results correlated well with the ablation regions determined using MRI sequences in both models. In rabbit femora, large zones of RF ablation (average volume 12.9±5.5 cm3) extended beyond the femur cortex (corresponding to the probe design for human use) into the surrounding soft tissue. The RFA-treated tumour-involved specimens demonstrated a significant reduction in tumour volume compared to sham femora, however a small number of viable tumour cells remained within the ablation volume. Newly formed trabecular structures were also seen in all treated femora. TRAP staining demonstrated a significant reduction in osteoclast number post-RFA in both the tumour-involved and healthy groups. TUNEL staining revealed areas of patchy cortical osteocyte necrosis within the ablation zone. Discussion/Conclusions. The large histologic region of effect created by RFA was consistent with MRI findings in both models. Treatment was contained in the porcine vertebrae without collateral damage to neighbouring sensitive structures. In the femora, while osteoclasts were found to be very susceptible to RFA, a small number of tumour cells and osteocytes in the treated regions remained viable. As the treatment zone did not encompass the full extent of the intramedullary lesions, it is possible that the sporadic VX2 cell viability may be explained by local tumour cell migration. Limited destruction of healthy osteocytes by RFA may be desirable in restoring bone health

In spite of extensive accounts describing the blood supply to the femoral head, the prediction of avascular necrosis is elusive. Current opinion emphasises the contributions of the superior retinacular artery but may not explain the clinical outcome in many situations, including intramedullary nailing of the femur and resurfacing of the hip. We considered that significant additional contribution to the vascularity of the femoral head may exist. A total of 14 fresh-frozen hips were dissected and the medial circumflex femoral artery was cannulated in the femoral triangle. On the test side, this vessel was ligated, with the femoral head receiving its blood supply from the inferior vincular artery alone. Gadolinium contrast-enhanced MRI was then performed simultaneously on both control and test specimens. Polyurethane was injected, and gross dissection of the specimens was performed to confirm the extraosseous anatomy and the injection of contrast. The inferior vincular artery was found in every specimen and had a significant contribution to the vascularity of the femoral head. The head was divided into four quadrants: medial (0), superior (1), lateral (2) and inferior (3). In our study specimens the inferior vincular artery contributed a mean of 56% (25% to 90%) of blood flow in quadrant 0, 34% (14% to 80%) of quadrant 1, 37% (18% to 48%) of quadrant 2 and 68% (20% to 98%) in quadrant 3. Extensive intra-osseous anastomoses existed between the superior retinacular arteries, the inferior vincular artery and the subfoveal plexus.

This review briefly summarises some of the definitive studies of articular cartilage by microscopic MRI (µMRI) that were conducted with the highest spatial resolutions. The article has four major sections. The first section introduces the cartilage tissue, MRI and µMRI, and the concept of image contrast in MRI. The second section describes the characteristic profiles of three relaxation times (T₁, T₂ and T_1ρ) and self-diffusion in healthy articular cartilage. The third section discusses several factors that can influence the visualisation of articular cartilage and the detection of cartilage lesion by MRI and µMRI. These factors include image resolution, image analysis strategies, visualisation of the total tissue, topographical variations of the tissue properties, surface fibril ambiguity, deformation of the articular cartilage, and cartilage lesion. The final section justifies the values of multidisciplinary imaging that correlates MRI with other technical modalities, such as optical imaging. Rather than an exhaustive review to capture all activities in the literature, the studies cited in this review are merely illustrative.