Salter-Harris II fractures of the distal tibia affect children frequently, and when they are displaced present a treatment dilemma. Treatment primarily aims to restore alignment and prevent
Out of a total of 112 children with displaced forearm shaft fracture treated with Percutaneous Kirschner (K) wire fixation in the past 9 years, 84 cases with fracture of both the radius and ulna were reviewed. 64 (76%) had fixation of both the radius and ulna, 10 (12%) the radius only and the other 10 (12%) the ulna only. In 60 (71%) patients were successful with one stage close reduction and pinning, while in the remaining 24 (29%) a semi- open reduction through a small incision was required. The K-wire was inserted through the radial styloid or the Lister tubercle for the radius, and through the tip of the olecranon for the ulna. All the patients reviewed were found to have good functional results with no non-union, deep infection or
Purpose of study: To evaluate the results of a consecutive series of displaced intracapsular paediatric femoral neck fractures treated by early closed reduction and Austin Moore Pin fixation. Method: Between 2001 and 2004, 14 paediatric patients with a mean age of 10 years suffering femoral neck fractures were identified. All traumatic epiphyseal, trans-cervical and basi-cervical femoral neck fractures were included. Pathological and intertrochanteric fractures were excluded. There were 11 male and 3 female patients. All patients were treated by reduction and internal fixation using Austin Moore pins. Patients were allowed to mobilize non-weight bearing with crutches for 3 months, followed by partial to full weight bearing. The mechanism of injury, associated injuries, time to reduction and time to union were reviewed. All patients were followed up till union. Mean follow up was 18 months. Patients were assessed clinically for pain, limp, use of walking aid, walking distance, stair climbing, cross leg sitting and squatting. Hip movements and limb length discrepancy were noted. Radiographs were analyzed to determine the adequacy of reduction, fracture healing and changes of avascular necrosis (AVN). Results: Mean injury-operation interval was 38.5 hours. Mean time to union was 16 weeks. All patients had excellent initial reduction which was maintained till healing. All patients’ fractures healed uneventfully. There were no complications in the form of non-union, AVN,
Introduction. Paediatric hip fracture accounts for less than one percent of paediatric fractures. Previous studies report complication rates between 20 and 92%. Method. We retrospectively identified patients with fixation for neck of femur fractures at Birmingham Children's Hospital. All patients were under age sixteen. Data were reviewed over a 10 year period (1997-2006). Fractures were classified by Delbet's classification and Ratliff's system to grade avascular necrosis (AVN). Function was assessed using Ratcliff's criteria, incorporating clinical examination and radiographic findings. Results. 15 femoral neck fractures were treated in 14 patients over a ten year period (R=1997-2006). One patient sustained bilateral fractures. Three patients had osteogenesis imperfecta and one osteopetrosis. Mean age at injury was 10.3 years (R=6-14 years). Mean follow-up was 31 months (R=6-110 months). Two fractures were Delbet type-I (13.3%), four type-II (26.7%), six type-III (40%) and three type-IV fractures (20%). Associated injuries included calcaneal fracture, head injury, pubic rami, acetabular and tibial fractures, hip dislocation, and depressed skull fracture with extradural haematoma. Eleven patients were operated on within 24 hours (R=4-19 hours) and four after 24 hours (R=2-11 days). One patient operated on within seven hours had a poor outcome.
Proximal Radius – Fractures of the proximal radius in children account for slightly more than 1% of all children’s fractures, represent 5 to 10% of all elbow fractures and accounts for 5% of all fractures involving the growth plate. The average age in the literature is 10 years (4 to 16 years) with no difference between boys and girls. The anatomical aspects should be emphasized for the comprehension of this fracture: 1) the radial head of the child only starts to ossify at age 5 so it is very rare to have a fracture before this age since all the head is cartilaginous and therefore more resistant to trauma. At the same time it makes more difficult the diagnosis because of the absence of ossification of the epiphysis. 2) There is a valgus angulation of 12.5° between the radial head and the shaft of the radius in the AP plan and an anterior angulation of 3° on the lateral plane that should not be misinterpreted as fractures. 3) The radial head is intrarticular in a similar way like the femoral head and trauma to this region may lead to AVN as a result of damage to the vascular supply of the epiphysis. 4) The proximal radioulnar joint has a very intimate continuity contributing to exact congruence of the articular surfaces. The axis of rotation lies directly in the center of the radial neck. Any deviation of the epiphysis over the neck has a major reflect over the axis of rotation causing a “cam” effect when the radial head rotates with loss of pronosupination. The mechanism of injury responsible for this injury result from a fall on the outstretched upper extremity in which the elbow is extended and a valgus force is applied to the elbow joint. In more rare cases it result from direct pressure to the radial head during dislocation of the elbow. There are different classifications mostly based on the anatomical lesion or degree of deformity. Wilkins divides this fracture in two major groups: Group I (valgus fracture) subdivided in three types: type A – the Salter-Harris type I and II, type B – Salter-Harris type IV and type C – fractures involving only the proximal radial metaphysis and Group II (fractures associated with elbow dislocation) subdivided in two types: type D – reduction injuries and type E – dislocation injuries. O’Brien divides the common valgus injury in three types according to the degree of angulation between the radial head and the axis of the radius: Type I (0 to 30° angulation) Type II (between 30° and 60°) and Type III (more than 60°). The clinical symptoms may vary according to the magnitude of the injury. The child will mostly complaint of pain and tenderness on the lateral side of the joint. In young children pain may first be referred to the wrist. The pain usually increases with pronosupination and extension of the elbow. The diagnosis relies mostly on the x-ray view (AP and lateral) and the fracture will be easily visualized in either film. In the cases where the fracture line is superimposed over the ulna an oblique view will be necessary. In the young child, whereas the epiphysis is still not ossified, an ultrasound may be helpful differentiating the position of the radial head. An arthrogram may also be of benefit especially during the process of reduction to check the accuracy of the treatment. The prognosis of this lesion depends on several factors. A poor result can be expected if the fracture is associated with other injuries such as elbow dislocation and ulna or medial epicondylar fractures. A residual tilt of the radial head, provided is not superior to 30°, is more tolerable than a translocation of the radial head superior to 4mm. Age is also an important factor since the older the child the less remodeling it will have. The treatment has also an important role in the prognosis of this injury since it is unanimous acceptable that an open reduction is associated with poor results. Therefore the treatment of a young child with an isolated minimal displaced fracture-separation of the proximal radius (less than 30°) should be a simple long arm cast. In a more displaced fracture (more than 30° of tilt) a closed reduction should be performed under general anesthesia as suggested by Patterson. If the maneuver is not successful other attempts should be made with lateral pin compression applied directly to the radial head as suggested by Pesudo or an indirect reduction by an intramedullary kirschner wire as suggested by Metaizeau. Open reduction should be only reserved for dislocated Grade IV Salter-Harris type fractures, incarcerated radial head or in the presence of failure of closed treatment. The incidence of complications especially if associated with a dislocation of the elbow or other fractures can be high. The most common are loss of motion, radial head overgrowth usually with no clinical significance, notching of the radial neck and
Purposes:. See if permanent damage of the growth plate after physeal distraction is the rule and. Identify factors with influence on the viability of the physis after physeal distraction. Introduction: Surgeons have always been concerned about the fate of the growth plate after physeal distraction and for that reason this technique has usually been considered only in patients nearing maturity. Previous experimental work has shown that the velocity of distraction has an influence on the viability of the growth plate at follow-up (recommended rate: 0.5 mm/day). Clinically, it has also been our observation that the condition of the physis prior to distraction is another important factor related to physeal function in the long term. Patients and methods: Since 1987 we have used low velocity physeal distraction in 43 bone segments of which 37 cases have been followed-up at least for 24 months and this has been the group included in this study. The indications were lengthening (14), angular deformity correction (19) and resection of benign bone tumours (4). Most patients (24) were older than 10 y.o. and 22 of them were followed-up until maturity. We have retrospectively reviewed these patients looking at the radiological morphology and function of the distracted growth plate at follow-up. Results: Out of the 24 children older than 10 y.o., twenty showed a
