Purpose: The treatment of extension type II pediatric supracondylar humerus fractures remains controversial. Some argue that closed reduction and cast immobilization is sufficient to treat these fractures, while others advocate closed reduction and pinning. The purpose of this radiographic outcomes study was to determine whether closed reduction and cast immobilization could successfully obtain and maintain appropriate position of extension type II supracondylar humerus fractures.

Method: The radiographs of 1017 pediatric patients treated for supracondylar fractures between 1987 and 2007 were retrospectively reviewed. Pre-reduction, immediate post-reduction, and final radiographs of 155 extension type II fractures were measured in order to assess the position and alignment of the fracture fragments. Measurements included the anterior humeral line, humeral-capitellar angle, Baumann’s angle, the Gordon index, and the Griffet index. The latter two indices calculate the rotational instability of the fracture, which can be predictive of reduction loss. Patients were excluded if insufficient radiographs failed to allow complete assessment of the measurement parameters, or if open reduction was required.

Results: The average age of the subjects was 5.3 years (range 1–13 years) and had a mean follow-up of 5.3 months. Analysis of the final radiographs demonstrated that in 80% of subjects, the anterior humeral line remained anterior to the mid third segment of the capitellum (radiographic extension deformity), the mean humeral-capitellar angle was 23.8° (range – 11°–50°), the mean Baumann’s angle was 79.4° (range 62°–97°), the mean Gordon index was 4.59%, and 44% of subjects had a Griffet index between 1–3 (potentially indicative of unstable reduction due to malrotation of the fragments, which can allow the development of a cubitus varus deformity).

Conclusion: From this radiographic review, a significant proportion of fractures treated with closed reduction and cast immobilization failed to achieve anatomic position and alignment on final x-rays. However, the clinical significance of these results and the potential for long-term re-modeling of these fractures remains unknown.

Purpose: To describe the Halifax anterior-posterior kyphectomy, and report on a series consecutive patients.

Method: Twenty-two patients received a Halifax kyphectomy over a 23 year period. Patient charts were examined, and radiographs measured pre- immediately post- and at final follow up. Cobb’s method was used to determine kyphosis angle. The procedure itself involves an apical kyphectomy, and cord transection if necessary, followed by the insertion of two rods distally and anteriorly in the vertebral bodies. This is followed by sublaminar wires superiorly and reduction of the kyphosis. Data was analysed to attempt to find a correlation between age, deformity, OR time, length of stay and maintainence of correction.

Results: Mean age was 7.59 years (2–17); mean pre-op kyphosis was 123.19 degrees (79–163); post-op 40.43 degrees (13–92); mean correction of 82.29 (39–153). Mean follow-up was 6.38 years (0–14); mean kyphosis at follow-up was 60.24 degrees (14–126), mean final correction of 63.43 degrees (−37–162); mean loss of correction 19.33 degrees (−9–76). The average OR time was 247.86 minutes (180–345); EBL 765cc (140–2100) and length of stay 13.68 days (1–57). Eight patients required hardware removal, and two of these required revision surgery. The other six patients maintained correction without hardware, and did not require re-operation. One patient had a rod fracture, but did not require revision or removal. Twelve patients had no complications. There was one intra-operative mortality.

Conclusion: The Halifax kyphectomy is a safe, effective treatment for kyphosis in myelomeningocele patients. Outcomes in this series are comparable to the available literature.