Limited implant survival due to aseptic cup loosening is most commonly responsible for revision total hip arthroplasty (THA). Advances in implant designs and materials have been crucial in addressing those challenges. Vitamin E-infused highly cross-linked polyethylene (VEPE) promises strong wear resistance, high oxidative stability, and superior mechanical strength. Although VEPE monoblock cups have shown good mid-term performance and excellent wear patterns, long-term results remain unclear. This study evaluated migration and wear patterns and clinical and radiological outcomes at a minimum of ten years’ follow-up. This prospective observational study investigated 101 cases of primary THA over a mean duration of 129 months (120 to 149). At last follow-up, 57 cases with complete clinical and radiological outcomes were evaluated. In all cases, the acetabular component comprised an uncemented titanium particle-coated VEPE monoblock cup. Patients were assessed clinically and radiologically using the Harris Hip Score, visual analogue scale (pain and satisfaction), and an anteroposterior radiograph. Cup migration and polyethylene wear were measured using Einzel-Bild-Röntgen-Analyze software. All complications and associated treatments were documented until final follow-up.Aims
Methods
The aim of this study was to compare the primary fixation stability and initial fixation stiffness of two commonly used fixation techniques, the tension band wiring technique and interfragmentary screw fixation, with an innovative mini-screw fragment fixation system in a model of transverse fracture of the patella. It was hypothesized that the biomechanical performance of the fragment fixation system would not significantly differ from the loading characteristics of the two established methods currently investigated.
Side-to-side comparison of anatomical or functional parameters in the evaluation of unilateral pathologies of the knee joint is common practice. Generally, it is assumed that the contralateral joint provides “normal” anatomy and function and that within-subject side differences are less when compared with between-subject variability. This has advocated the use of side-to-side comparisons in a wide field of orthopaedic surgery. The aim of this study was to test the hypothesis that there are no significant differences in the morphometric knee joint dimensions between the right and the left knee of a human subject. Furthermore, it was hypothesized that side differences within subjects are smaller than inter-subject variability. In 30 pairs of human cadaver knees the morphometry of the articulating osseous structures of the femorotibial joint, the cruciate ligaments, and the mensici were measured using established measurement methods. Morphometric data were obtained either using digital callipers, radiographs, contour gauges, or cross-sectiontal scans. Data were analysed for overall side differences using the Student t-test and Pearson’s correlation coefficient and the ratio between within-subject side differences and intersubject variability was calculated. In three out of 71 morphometric dimensions there was a significant side difference, including the posterior tibial slope, the anatomical valgus alignment of the distal femur, and the position of the femoral insertion area of the ACL. In two additional parameters, including the cross-sectional area of the distal third of the ACL and PCL, within-subject side differences were larger than intersubject variability. In general, there was a positive correlation in morphometric dimensions between right and left knees in one subject. This study confirmed a good correlation in the morphometric dimensions of a human knee joint between the right and the left side. Our data support the concept of obtaining morphometric reference data from the contralateral uninjured side in the evaluation of unilateral pathologies of the knee joint. The uninjured contralateral side rather than knee joint dimensions obtained from an uninjured subject should be used as a valid control in orthopaedic practice.
In the treatment of acute elbow dislocation promising clinical results have been reported on articulated external fixation and surgical reconstruction of major joint stabilizers. However, it remains unclear whether or not surgical reconstruction of the major joint stabilizers sufficiently stabilizes the elbow joint or if augmentation by a hinged elbow fixator is beneficial to provide early stability and motion capacity. The aim of the present study was to compare the stabilizing potential of surgical reconstruction versus augmentation by a hinged external elbow in a model of sequentially induced intability of the elbow.
The present study was conducted to analyze the specific morphological features of press-fitted quadriceps tendon-patellar bone grafts that determine primary graft stability in ACL-reconstruction. Ten quadriceps tendon-patellar bone grafts were harvested from fresh frozen human cadaveric knees (age 52–82) and fixed to porcine femora in a press-fit technique. Four specimens were prepared for histological analysis of the bone-tendon junction, while a modified technique for tissue-plastination was applied to 6 specimens to investigate the microscopic and microradiographic features of the bone-to-bone interface. Analysis of the bone-tendon junction revealed a serious damage of the fibrocartilage at the attachment zone according to the impaction of the patellar bone plug with implantation. Microradiographs and microscopy of the plastinated specimens showed that there is a trabecular interaction between the bony interfaces of the graft and the femoral tunnel, representing an early osseous integration with local increase of radiopacity. In consequence, both elevated compressive forces as well as increased frictional resistance seem to contribute to the primary stability of press-fit fixated grafts. The stability of quadriceps tendon-patellar bone grafts in press-fit technique to a certain degree depends on bone quality, allowing compressive forces to arise at the bone-to-bone interface. Loss of graft stability, however, is caused by disturbance of the integrity of the bone-tendon junction while impacting the patellar bone plug into the femoral tunnel.
Press-fit fixation technique in anterior cruciate ligament (ACL) reconstruction has recently gained popularity. The objective of this study was to evaluate the initial fixation strength of human patellar tendon-bone (PTB) grafts with respect to bone-plug length and loading angle by using a femoral press-fit fixation technique. Fourty-eight human PTB-grafts were obtained from 24 fresh frozen cadavers (mean age 72 years). The specimens were randomly assigned to two experimental groups: One with a 15 mm (n=24) and a second with a 25 mm patellar bone plug (n=24). The grafts were implanted to porcine femora in a press-fit fixation technique. Ultimate failure loads were measured at 10 mm/s at varying loading angles of 0, 30 and 60. Biomechanical testing showed a significant difference of ultimate failure load comparing 15 mm (mean 236 N) to 25 mm (mean 333 N) bone plugs (p=0.015). In both groups, the fixation strength increased with rising loading angles. While axial graft loading exclusively caused plug dislocation, the predominant mode of failure was tendon rupture at 60 loading angle. It is concluded that bone plug length and loading angle significantly influence the primary stability of PTB press-fit fixation in ACL reconstruction. Based on these findings, we recommend the use of patellar bone plugs with a minimum of 25 mm in length. If graft harvesting occasionally generates a patellar bone plug measuring 15 mm, restrictive postoperative rehabilitation should be advised.