Introduction. Pseudotumor is a known complication of Metal-on-Metal (MOM) total hip arthroplasty (THA). MRI is usually used to visualize pseudotumor formation. However, small pseudotumors close to the THA components may not be observed using MRI due to image distortion by the interaction between the metallic objects and the magnetic fields. The CT image quality also degrades because MOM THA components can induce X-ray beam-hardening effects. Therefore, we evaluated contrast-enhanced (CE) tomosynthesis. Tomosynthesis is known as an X-ray tomography technique that provides images with fewer metal artifacts and lower X-ray doses for the patients. The aim of this report was to investigate the detectability of pseudotumors by tomosynthesis. Case Report. A 71-year-old woman had undergone unilateral cementless large-diameter MOM THA using a couple of Conserve Plus acetabular cup and Profemur Z femoral component (Wright Medical, Memphis, Tennessee) for primary arthritis of the left hip at our hospital. She presented with severe hip, groin and buttock pain and swelling at fifteen months after surgery. Therefore, she was examined MRI and tomosynthesis using Sonialvision-Safire X-ray Radiography/Fluoroscopy System (Shimadzu Corporation, Japan). Plain tomosynthesis was obtained before the contrast media injection and followed by CE-tomosynthesis. Then, subtraction tomosynthesis between plain and CE-tomosynthesis were calculated in order to increase the image contrast. The subtraction tomosynthesis image enhanced the pseudotumor visibility, which was considered to be equal to that depicted using MRI (Fig. 1 and 2). However, using MRI, cystic lesions in the pseudotumor appeared as a very high signal in the T2 weighted images, whereas CE-tomosynthesis resulted in no image contrast (Fig. 3). The tomosynthesis image resulted in less image distortion and fewer metal artifacts than MRI, even in the area close to the hip implants. Discussion. MRI results in a wide variety of soft tissue contrast when imaging pseudotumors. However, MRI produces distorted images near MOM THA components. As such, CE-tomosynthesis is a promising imaging technique for detecting small, early-stage pseudotumors. Tomosynthesis also has the advantage of delivering a lower X-ray dose to the patients and providing a better spatial resolution than CT in the coronal plane

Introduction. Fifteen percent of the primary total knee arthroplasties (TKA) fails within 20 years. Among the main causes for revision surgery are instability and patellofemoral pain. Currently, the diagnostic pathway requires various diagnostic techniques to reveal the original cause for the failed knee prosthesis and is therefore time consuming and inefficient. Accordingly, there is a growing demand for a diagnostic tool that is able to simultaneously visualize soft tissue structures, bone and TKA. Magnetic resonance imaging (MRI) is capable of visualising all the structures in the knee although a trade- off needs to be made between metal artefact reducing capacities and image quality. Low-field MRI (0.25T) results in less metal artefacts and a lower image quality compared with high-field MRI (1.5T). The aim of this study is to develop a MRI imaging guide to image the problematic TKA and to evaluate this guide by comparing low-field and high-field MRI on a case study. Method. Based on literature and current differential diagnostic pathways a guide to diagnose patellofemoral pain, instability, malposition and signs of infection or fracture with MRI was developed. Therefore, methods as Insall Salvati, patellar tilt angle and visibility of fluid and soft tissues were chosen. Visibility was scored on a VAS scale from 0 to 100mm (0mm zero visibility, 100mm excellent visibility). Subsequently, this guide is used to analyse MRI scans made of a volunteer (female, 61 years, right knee) with primary TKA (Biomet, Zimmer) in sagittal, coronal and transversal direction with a FSE PD metal artefact reducing (MAR) sequence (TE/TR 12/1030ms, slice thickness 4.0mm, FOV 260×260×120mm. 3. , matrix size 224×216) on low-field MRI (Esaote G-scan Brio, 0.25T) and with a FSE T. 1. -weighted high bandwidth MAR sequence (TE/TR 6/500ms, slice thickness 3.0mm, FOV 195×195×100mm. 3. , matrix size 320×224) on high-field MRI (Avanto 1.5T, Siemens). Scans were analysed three times by one observer and the intra observer reliability was calculated with a two-way random effects model intra class correlation coefficient (ICC). Results. Due to less metal artefacts on the low-field MRI scans the angle, distance and ratio measurements were more consistent: Insall Salvati low-field 0.97–0.99, Insall Salvati high-field 1.05–1.12, patellar tilt angle low-field 2.1–2.8°, patellar tilt angle high-field 2.4–7.6°. Over all, the VAS scores are higher on the high-field MRI scans; VAS medial collateral ligament high-field 26–45, VAS medial collateral ligament low-field 24–34, VAS popliteus tendon high-field 15–27, VAS popliteus tendon low-field 2–7. The ICC values of the VAS scores, angle measurements and ratio measurements were excellent, ICC > 0.9. The ICC values of the distance measurements were moderate, ICC > 0.6. Conclusion. MRI offers possibilities to simultaneously differentiate underlying causes of the failed knee prosthesis. The structures of interest were more clearly visible on the high-field MRI scans due to higher image contrast. The angle, distance and ratio measurements were more consistent on the low-field MRI scans due to less metal artefacts. Further research should focus on a larger group of patients with complaints after TKA to verify the analysis methods

Introduction. Advanced medical imaging techniques have allowed the understanding of the patterns of relative bone motions at human joints. 1. However, poor imaging contrasts of soft tissues have not allowed the full understanding of various glenohumeral ligaments (GHL) functions during glenohumeral joint (GHJ) manoeuvres. This is presently a significant limitation to research as these structures are said to be responsible for the passive stability of the GHJ. 2. Furthermore, the repairs of GHJ instability often take recourse to these structures. 3. Earlier studies have presented a model that numerically reconstructs or simulates GHJ motions. 4. and how the locus of bony attachment points of the GHLs on a dynamic GHJ could be numerically tagged and trailed. 5. The aim of this study was to advance these previous findings by developing an algorithm that allows the quantification of GHL lengths at any instantaneous position of the GHJ. Materials and Method. CT scan of a set of humerus and scapula was reconstructed into two individual surface meshes of interconnected nodes, each node having a unique vectorial identification in space. The two attachment nodes (a and b) of a GHL were identified on the bones. 5. Least squares geometric sphere was fitted upon the humeral head (HH) and its centre (c) and radius (r) quantified. 6. Vectors a, b and c were applied to represent the ‘dominant ligament plane’ concomitant with the 2D ‘dominant plane’ of Runciman (1993). 7. This plane defined the path through which the ligament wrapped on the HH. The point of initial or end of contact of GHL on the HH was defined as the point on HH where a line from c intercepts the ligament at 90°. Total GHL length was calculated as the sum of its three segments, namely: (1) Proximal segment – a straight line from its glenoid attachment node to the point of initial contact (2) Wrap segment – an arc of (r) radius of curvature from initial to end contact points (3) Distal segment – a straight line from end contact point to the humeral node of attachment. The wrap segment was further refined by adjusting ligament contacts along this path to the actual surface contour of the HH by integrating all the surface nodes along the path. The algorithm was tested for short incremental steps of GHJ abduction, flexion, rotation and translations on the Amadi et al's kinematics simulation model. 4. . Results. From plotted graphs of 5 simulated GHL, lengths increased or decreased smoothly as the rotations and translations were increased or decreased at a constant rate, respectively. Some GHJ motion directions resulted in contrasting stretching or folding effects on different ligaments in a mathematically reasonable manner. Conclusion. This numerical application would allow the quantification of functional loading of each GHL during simulated or reconstructed GHJ motion and hence provide understanding of how the various GHL may be treated during surgical repairs