Animal experimental studies indicate that pulsed low-intensity ultrasound might enhance cartilage repair in early stages of osteoarthritis (OA) and to improve healing of osteochondral defects. The purpose of this in vitro study was to determine systematically whether and to what extent pulsed low-intensity ultrasound

influences the synthesis and release of PGs,

Full-thickness cartilage explants of the lateral compartment of the proximal tibia were taken from OA patients undergoing knee replacement surgery. Explants with mild or moderate OA alterations were cultured in a CO2-incubator at 37°C, 5% CO2 and 95% relative humidity. After 2 days, explants were subjected to ultrasound applied in a pulsed-wave form (1: 4) on the following 3 days. The ultrasound application apparatus was specifically designed and constructed to function within an explant culture system under sterile conditions. The effect of the ultrasound parameters intensity (2, 30, 120, 250 mW/cm2), duration (20, 3 × 30 minutes/day) and frequency (0.5, 1.2, 4.7 MHz) on PG synthesis and release were measured. PG synthesis was determined by the incorporation of 35SO4 during the final 22 h of the experiments whereas the content of PGs were quantitated with the DMMB-assay. The viability of chondrocytes was assessed microscopically using fluorescein diacetate and propidium iodide. Results were compared to untreated explants from the same joint. Each experimental condition was repeated five times using explants always obtained frrom 6 different patients (N=6).

Neither the degree of OA alterations of explants, nor the various ultrasound parameters tested displayed any significant effect on the synthesis and release of PGs as well as on the viability of explants.

This work was supported by the Deutsche Arthrose-Hilfe e.V.

Aim: Can comparable results be obtained regarding the postoperative improvement of range of motion using ßexionosteotomy alone in comparison to the three-dimensional corrective osteotomy. Material and Methods: 16 patients after SCFE were analyzed (7 female, 9 male). A computer program for simulation of movement and osteotomy developed by the authors, served for study execution. According to 3D-reconstruction of the computer tomography data the physiological range was determined by ßexion, abduction and internal rotation. The three-dimensional osteotomy was compared with the onedimensional ßexionosteotomy. Both inter-trochanteric osteotomy techniques were simulated and the improvements of the movement range were assessed and compared. Results: The average slipping and thus correction angles measured inferior 25.5¡ (range: 7.5¡–51.0¡) and posterior 52.0¡ (range: 29.0¡– 78.5¡). After the simulation of osteotomy by Southwick the angle of ßexion was 61.3¡ (improvement: 41.4¡), of abduction 60.3¡ (improvement: 42.9¡) and interior rotation of 70.1¡ (improvement: 52.6¡). The ßexionsosteotomy after Grifþth achieved a ßexion of 66.7¡ (improvement: 46.8¡), an abduction of 41.1¡ (improvement: 23.7¡) and an internal rotation of 57.4¡ (improvement: 40.0¡). Conclusion: The improvement of the free movement range after ßexion osteotomy is comparable, with three-dimensional osteotomy after Southwick with the exception of the abduction angle.