The Effectiveness of Growth Modulation Using Tension Band Plates in Children With Achondroplasia in Comparison to Children With Idiopathic Frontal Axial Deformities of the Knee.

BACKGROUND: Achondroplasia is the most common form of rhizomelic dwarfism. Aside from disproportionally short extremities, frontal knee malalignments are common. We assessed the effectiveness of guided growth via tension band plates in children with achondroplasia in comparison to patients with idiopathic knee deformities using radiography. METHODS: Twenty children with achondroplasia (8 valgus/31 varus knees) and 35 children with idiopathic knee malalignments (53 valgus/12 varus knees) which underwent temporary hemiepiphysiodesis at the distal femur and/or proximal tibia were retrospectively compared. Radiographic outcomes (mechanical lateral distal femoral angle, medial proximal tibial angle, and mechanical axis deviation) were compared before surgery and plate removal. Correction rates according to plate location were compared as change per implant duration and per growth in leg length. RESULTS: Achondroplasia patients were younger (9±2 vs.12±2 y), femoral and tibial growth rate was 43.3% and 48.5% lower and implant duration lasted longer: 36.9±8.9 months in valgus knees and 23.0±14.3 months in varus knees versus 13.4±7.9 months in idiopathic valgus and 11.7±4.6 months in idiopathic varus knees. Significant improvements in joint orientation angles and mechanical axis deviation were achieved but femoral and tibial plates achieved slower correction per months in achondroplasia (P≤0.031). When normalized to bone growth, the rate of correction in joint orientation angles was no longer significantly different for the femur (P=0.241), with a trend for slower correction in the tibia (P=0.066). The corrections in MAD per leg growth (mm/mm) remained smaller (P=0.001). In achondroplasia, older age correlated with slower MAD correction (r=-0.36, P=0.022), femoral plates corrected faster than tibial (P=0.024) and treatment of valgus was less successful than varus involving longer treatments (P=0.009). More complications occurred in achondroplastic knees (P=0.012). CONCLUSIONS: Skeletally immature patients with achondroplasia can benefit from growth modulations, but they need longer treatments and face more complications. Their slower growth does not solely determine the more tenacious success. LEVEL OF EVIDENCE: Therapeutic Level III-case-control study.

Femur reconstruction in 3D ultrasound for orthopedic surgery planning.

PURPOSE: Derotation varisation osteotomy of the proximal femur in pediatric patients usually relies on 2-dimensional X-ray imaging, as CT and MRI still are disadvantageous when applied in small children either due to a high radiation exposure or the need of anesthesia. This work presents a radiation-free non-invasive tool to 3D-reconstruct the femur surface and measure relevant angles for orthopedic diagnosis and surgery planning from 3D ultrasound scans instead. METHODS: Multiple tracked ultrasound recordings are segmented, registered and reconstructed to a 3D femur model allowing for manual measurements of caput-collum-diaphyseal (CCD) and femoral anteversion (FA) angles. Novel contributions include the design of a dedicated phantom model to mimic the application ex vivo, an iterative registration scheme to overcome movements of a relative tracker only attached to the skin, and a technique to obtain the angle measurements. RESULTS: We obtained sub-millimetric surface reconstruction accuracy from 3D ultrasound on a custom 3D-printed phantom model. On a pre-clinical pediatric patient cohort, angular measurement errors were [Formula: see text] and eventually [Formula: see text] for CCD and FA angles, respectively, both within the clinically acceptable range. To obtain these results, multiple refinements of the acquisition protocol were necessary, ultimately reaching success rates of up to 67% for achieving sufficient surface coverage and femur reconstructions that allow for geometric measurements. CONCLUSION: Given sufficient surface coverage of the femur, clinically acceptable characterization of femoral anatomy is feasible from non-invasive 3D ultrasound. The acquisition protocol requires leg repositioning, which can be overcome using the presented algorithm. In the future, improvements of the image processing pipeline and more extensive surface reconstruction error assessments could enable more personalized orthopedic surgery planning using cutting templates.