External fixators enable distraction osteogenesis and gradual foot deformity corrections. Hexapod fixators have become more popular than the Ilizarov apparatus. The Ortho-SUV Frame (OSF), which is a hexapod that was developed in 2006, allows flexible joint attachment so that multiple assemblies are available. We assessed the reduction capability of several assemblies. An artificial bone model with a 270-mm-long longitudinal foot was used. A 130-mm tibial full ring was attached 60 mm proximal to the ankle joint. A 140-mm, 2/3-ring forefoot was attached perpendicular to the metatarsal bone axis. A 130-mm, 2/3-ring hindfoot was attached parallel to the tibial ring. A V-osteotomy, which was combined with 2 oblique osteotomies at the navicular-cuboid bone and the calcaneus, was performed. The middle part of the foot, including the talus, was connected to the tibial ring. Five types of forefoot applications and 4 types of hindfoot were assessed. The range of correction included flexion/extension in the sagittal plane, adduction/abduction in the horizontal plane, and pronation/supination in the coronal plane. Additionally, we reported short-term results in 9 clinical cases. Forefoot applications, in which the axis of the hexapod was parallel to the axis of the metatarsal bones, had good results with 52/76 (flexion/extension), 48/53 (adduction/abduction), and 43/51 (pronation/supination) degrees. Hindfoot applications, in which the hexapod encircled the ankle joint, had good results with 47/58, 20/35, and 28/31 degrees, respectively. Clinically, all deformities were corrected as planned. Multiple assemblies and wide ranges of corrections are available with OSF.
Purposes This study compared the six-axis external fixator Ortho-SUV Frame (OSF) and the Ilizarov apparatus (IA) in femoral deformity correction. Our specific questions were: (1) which of the fixators (OSF or IA) provides shorter period of femoral deformity correction, and (2) which of the fixators (OSF or IA) provides better accuracy of correction. Methods We retrospectively analysed 123 cases of femoral deformities (127 femora): 45 (47) treated with OSF (20 male and 27 female) and 78 (80) with IA (53 male and 27 female). The average age in the OSF group was 34.6 (range, 18-66) and in the IA group 35.8 (range, 18-76). All the deformities were categorized according to the number of planes and deformity components as simple, middle and complex deformities. Results Elimination of simple deformities in the IA group took 58.3±21.4 days, EFI 58.8±39.8 days/cm, and lengthening was 4.6±1.98 cm. Middle deformities were 71.3±26.2, 61.9±30.3 and 4±2, respectively. In complex deformities we had 105.2± 21.8, 79.3±35.4 and 3.2±1.45, respectively. Normal alignment was achieved in 55.0 % of cases in IA. In 45.0 % of cases we had residual deformity. Elimination of simple deformations in the OSF group took 55.3±12.8 days, EFI 47.5±23 days/cm, and lengthening 4.5±1.1сm. Middle deformities were 43.6± 18.9, 59±14.6 and 3.6±2, respectively. In complex deformities we had 44.9±11.5, 57.5±9.4 and 3.6±1.7, respectively. In the OSF group normal alignment was achieved in 85.1 %. In 14.9 % there was residual deformity.Conclusion Using OSF simplifies deformity correction and reduces its period by 2.3 times in complex deformities and by 1.6 times in middle deformities. Accuracy of correction with OSF was significantly higher than correction with IA.
The Ortho-SUV frame (OSF) is a novel hexapod circular external fixator which draws upon the innovation of the Ilizarov method and the advantages of hexapod construction in the three-dimensional control of bone segments. Stability of fixation is critical to the success or failure of an external circular fixator for fracture or osteotomy healing. In vitro biomechanical modelling study was performed comparing the stability of the OSF under load in both original form and after dynamisation to the Ilizarov fixator in all zones of the femur utilising optimal frame configuration. A superior performance of the OSF in terms of resistance to deforming forces in both original and dynamised forms over that of the original Ilizarov fixator was found. The OSF shows higher rigidity than the Ilizarov in the control of forces acting upon the femur. This suggests better stabilisation of femoral fractures and osteotomies and thus improved healing with a reduced incidence of instability-related bone segment deformity, non-union and delayed union.
Circular fixation according to the Ilizarov method is a well-recognised modality of treatment for trauma and deformity. One shortcoming of the traditional fixator is its limited ability to correct more than one plane of deformity simultaneously, leading to lengthy frame-time indices. Hexapod circular fixation utilising computer guidance is commonplace for complex multidimensional deformity but difficulties often arise with correction of femoral deformity due to bulkiness of the frame construct, particularly in proximal deformity and in patients of increased size. The Ortho-SUV frame is an innovative hexapod which permits unique customisation to individual patient anatomy to maximise tolerance and optimal range of deformity correction. We hypothesised that the optimal configuration and maximal degree of correction achievable by the Ortho-SUV frame can be biomechanically modelled and applied clinically. A study was constructed using Ortho-SUV and femoral limb models to measure deformity correction via differing frame constructs and determine optimal frame configuration to achieve correction in proximal, middle, and distal third deformities with respect to the soft tissue envelope. The ideal frame configuration is determined for correction of deformity in all locations of the femur with the maximal parameters of correction calculated whilst avoiding and mitigating soft tissue irritation from bulky frame construction.
Aim. This study aimed to estimate the results of congenital long bone deformities using the consecutive application of guided growth and external fixation. Materials and methods. We performed a retrospective analysis of the treatment results of 38 children with congenital deformities of long bones. Group 1 consisted of 17 children who underwent consecutive application of two methods: guided growth and external fixation. Group 2 (control group) consisted of 21 children who underwent isolated lengthening and deformity correction by external fixation. Results. There were 14 complications in group 1 and 25 complications in group 2. Moreover, only seven cases in group 1 had complications requiring surgical treatment, whereas 17 cases in group 2 required operative treatment for complications. There was a relatively low level of refractures: zero cases in group 1 and three cases in group 2. The most common complication was a recurrence of deformity associated with the continuous growth of children: seven cases in group 1 and eight cases in group 2. However, no recurrence of the torsion component of deformity was observed in any group 1 cases, and repeated guided growth could be performed in the six cases of growing children. Conclusion. The consecutive use of external fixation and guided growth to treat congenital deformities of the lower limbs is a promising direction for pediatric orthopedics because it reduces the incidence of complications. The repeated use of guided growth, because of its minimal invasiveness, is the most effective solution for the recurrence of deformity in a growing child.
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