Summary. This work proposes a novel, automatic method to obtain an anatomical reconstruction for 3D segmented bones with large acetabular defects. The method works through the fitting of a Statistical Shape Model to the non-defect parts of the bone. Introduction. Patient-specific implants can be used to treat patients with large acetabular bone defects (IIa-c, IIIb, Paprosky 1994). These implants require a full 3D preoperative planning that includes segmentation of volumetric images (CT or MRI), extraction of the 3D shape, reconstruction of the bone defect into its anatomic (non-defect) state, design of an implant with a perfect fit and optimal placement of the screws. The anatomic reconstruction of the bone defect will play a key role in diagnosing the amount of bone loss and in the design of the implant. Previous reconstruction methods rely on a healthy contralateral (Gelaude 2007); however this is not always available (e.g. partial scan or implant present). Statistical shape models (SSM) of healthy bones can help to increase the accuracy and usability of the reconstruction and will decrease the manual labor and user dependency. Skadlubowicz (2009) illustrated the use of an SSM to reconstruct pelvic bones with tumor defects; however tumors generally affect a smaller region of the bone so that the reconstruction will be easier than in large acetabular bone defects. Also, the tumor reconstruction method uses 80 manually indicated landmarks, while the proposed method only uses 14. Patients & Methods. CT-scans from subjects with a healthy hemi-pelvis (15 male, 33 female, mean age: 69±20) were used to generate an SSM. The CT-scans were segmented using Mimics (Materialise NV, Belgium) to create a triangulated mesh. Preprocessing of the meshes ensured that the triangulation was smooth and uniform to help solve the corresponding point problem. An algorithm based on Redert (1999) was used to morph the template hemi-pelvis onto each dataset entity, creating a dataset with corresponding points. From this dataset the SSM was calculated using principal component analysis, so that the principal components serve as parameters for the mathematical model of the hemi-pelvis. To fit the SSM to a new defect hemi-pelvis, a matching algorithm was used. The algorithm varies the Principal Components independently optimizing the distance of the non-defect parts of the defect hemi-pelvis to the SSM sample. To validate the reconstruction method, 6 healthy bone meshes were used to generate a synthetic defect in the acetabular region. The original mesh was used as ‘golden standard’ to measure the reconstruction error. To illustrate the clinical use of the reconstruction method, one hemi-pelvis with a substantial defect was reconstructed. Results. The correspondence error for the morphing algorithm was 4.68±0.78 mm. The leave-one-out error for the SSM was 1.30±0.96 mm. The reconstruction error for the non-defect part was 1.44±1.13mm and for the reconstructed part 2.15±1.53mm. Discussion/Conclusion. The proposed method performs comparable to the contralateral method and the tumor reconstruction method, without the need of a healthy contralateral geometry. Consequently, the validation and the clinical illustration show that the proposed method is promising for automatic reconstruction of large acetabular defects

Introduction. The medial patellofemoral ligament (MPFL) is the main stabilizer of the patella and therefore mostly reconstructed in the surgical correction of patellofemoral dislocation. Various biomechanical and clinical studies have been conducted on MPFL reconstruction, while the patellofemoral contact pressure (PFCP) which is indicated as one of the predictors of retropatellar osteoarthritis was neglected. Therefore, the aim of this study was to investigate how different MPFL reconstruction approaches affect PFCP. Material & Methods. After radiographic examination and preparation six human cadaveric knee joints (52.1 ± 8.4yrs) were placed in a 6-DOF knee simulator. Three flexion-extension cycles (0–90°) were applied, while the extensor muscles (175N) and an axial joint load (200N) were simulated. PFCP was measured in knee flexion of 0°, 30° and 90° using a calibrated pressure measurement system (K-Scan, Tekscan Inc., USA). The following MPFL conditions were examined: native (P. nat. ), anatomical reconstruction (P. a. ), proximal and distal patellar single-bundle reconstruction (P. p. , P. d. ), proximal and ventral femoral reconstruction (F. p. , F. v. ). The cohesive gracillis graft of each knee was used for MPFL reconstruction. Further, the effect of three different graft pre-tensioning levels (2N, 10N, 20N) on the PFCP were compared. Nonparametric statistical analysis was performed using SPSS (IBM Inc., USA). Results. In 0° knee flexion median PFCP of the native state (P. nat. =0.46MPa) was significantly higher (p=0.04) compared to the ventral femoral fixation state (F. v. =0.24MPa). No significant differences were observed in 30° knee flexion. In 90° knee flexion PCFP of both femoral reconstructions (F. p. =1.26MPa, F. v. =1.12MPa) were significantly higher (p<0.04) compared to the native state (P. nat. =0.43MPa). Graft pre-tensioning had no significant impact (p>0.27) on the PFCP in 0°, 30° and 90° knee flexion for all pre-tensioning levels. Discussion. We investigated the PFCP of different MPFL reconstructions and compared them during continuous joint motion from 0° to 90° knee flexion. While a non-anatomical graft fixation on the femoral side leads to an excessive increase of PFCP (293%), a non-anatomical positioning on the patellar side only showed minor impact on the PFCP. An anatomical MPFL reconstruction showed comparable PFCP to the native joint. In contrast to the literature, we did not find a significant influence of graft pre-tensioning from 2N up to 20N on the PFCP. With respect to all study findings we would recommend to use the anatomical footprints for MPFL reconstruction and a moderate graft pre-tensioning of 2N

Introduction. Stemless shoulder implants have recently gained increasing popularity. Advantages include an anatomic reconstruction of the humerus with preservation of bone stock for upcoming revisions. Several implant designs have been introduced over the last years. However, only few studies evaluated the impact of the varying designs on the load transfer and bone remodeling. The aim of this study was to compare the differences between two stemless shoulder implant designs using the micro finite element (µFE) method. Materials and Methods. Two cadaveric human humeri (low and high bone mineral density) were scanned with a resolution of 82µm by high resolution peripheral quantitative computer tomography (HR-pQCT). Images were processed to allow virtual implantation of two types of reverse-engineered stemless humeral implants (Implant 1: Eclipse, Arthrex, with fenestrated cage screw and Implant 2: Simpliciti, Tornier, with three fins). The resulting images were converted to µFE models consisting of up to 78 million hexahedral elements with isotropic elastic properties based on the literature. These models were subjected to two loading conditions (medial and along the central implant axis) and solved for internal stresses with a parallel solver (parFE, ETH Zurich) on a Linux Cluster. The bone tissue stresses were analysed according to four subregions (dividing plane: sagittal and frontal) at two depths starting from the bone-implant surface and the distal region ending distally from the tip of Implant 1 (proximal, distal). Results. Medial loads produced higher bone tissue stresses when loading was applied along the implant axis. This was more prominent in the lower density bone, causing more than 3 times higher stresses in the highest region for both implants. Bone tissue stresses were also shown to be higher in the low density specimen, especially in the distal zone. The maximum bone tissue stress ratio for low/high density bone reached 4.4 below Implant 1 and 2.2 below Implant 2, occurring both with a medially-directed load. For both implants, the highest bone tissue stresses were predicted in the distal region than in the proximal region, with larger distal-to-proximal stress ratios below Implant 1 than Implant 2 (3.8 and 1.7, respectively). Discussion. Our µFE analyses show that the implant anchorage design clearly influences load transfer to the periprosthetic bone. The long fenestrated cage screw of Implant 1 showed more direct distal stress transfer, which may lead to stress shielding in the proximal region, in a larger extent than Implant 2 which tends to distribute loads more evenly. Furthermore, periprosthetic bone quality appears to be an important factor for load transfer, causing dramatic changes due to different loading condition and implant geometry. These findings will help further improve anchorage design for stemless humeral heads in order to minimize bone remodeling and the long-term fixation of these implants

Injuries of the posterolateral corner (PLC) of the knee are uncommon, but can lead to chronic disability from persistent instability and resultant articular cartilage degeneration if not appropriately treated. Although numerous reconstructive techniques have been described in the literature, there is no consensus on a single surgical approach due to a lack of consistent, long-term clinical outcomes. Nonanatomic reconstructions, in particular, have produced variable results, while anatomic reconstructions offer the most promise by restoring normal knee stability and kinematics and are now favoured by most. We describe the novel use of the BICEPTOR™ Tenodesis screw (Smith & Nephew) as an effective and technically straight forward means of performing a PLC reconstruction. We describe the technique and present the first 10 consecutive cases from a single surgeon series. All of the patients had a positive dial test pre-operatively with increased external rotation of 10 degrees or more at 30 degrees of knee flexion indicating clinical PLC injury. They all had the PLC reconstructed at the same time as an arthroscopic ACL reconstruction. Mean time from injury to surgery was 4 months (range 2–12). Patients were seen in clinic at maximum follow-up (11.1 months mean, range 6–24 months) and assessed clinically using the dial test at 30 and 90 degrees of knee flexion. Lysholm Knee Questionnaire and Tegner Activity Scale were also performed at maximum follow-up. Mean Lysholm Score was 68 (range 32–96). Mean Tegner Score pre-operatively was 3.5 (range 3–6) and at maximum follow-up was 4.5 (range 3–7). Of particular note only one patient reported any symptoms at all of giving way at maximum follow-up. Dial test was negative on all patients. Further work is warranted but we describe this as an effective and straight forward means of performing a PLC reconstruction

We evaluated two reconstruction techniques for a simulated posterolateral corner injury on ten pairs of cadaver knees. Specimens were mounted at 30° and 90° of knee flexion to record external rotation and varus movement. Instability was created by transversely sectioning the lateral collateral ligament at its midpoint and the popliteus tendon was released at the lateral femoral condyle. The left knee was randomly assigned for reconstruction using either a combined or fibula-based treatment with the right knee receiving the other. After sectioning, laxity increased in all the specimens. Each technique restored external rotatory and varus stability at both flexion angles to levels similar to the intact condition. For the fibula-based reconstruction method, varus laxity at 30° of knee flexion did not differ from the intact state, but was significantly less than after the combined method.

Both the fibula-based and combined posterolateral reconstruction techniques are equally effective in restoring stability following the simulated injury.

This study compared the effect of a computer-assisted and a traditional surgical technique on the kinematics of the glenohumeral joint during passive abduction after hemiarthroplasty of the shoulder for the treatment of fractures. We used seven pairs of fresh-frozen cadaver shoulders to create simulated four-part fractures of the proximal humerus, which were then reconstructed with hemiarthroplasty and reattachment of the tuberosities. The specimens were randomised, so that one from each pair was repaired using the computer-assisted technique, whereas a traditional hemiarthroplasty without navigation was performed in the contralateral shoulder. Kinematic data were obtained using an electromagnetic tracking device.

The traditional technique resulted in posterior and inferior translation of the humeral head. No statistical differences were observed before or after computer-assisted surgery.

Although it requires further improvement, the computer-assisted approach appears to allow glenohumeral kinematics to more closely replicate those of the native joint, potentially improving the function of the shoulder and extending the longevity of the prosthesis.