Children's hip fractures have historically had a bad prognosis. Accurate stable fixation has been one of the factors identified to improve the outcome.
Stable fractures have a better prognosis than displaced fractures.
The main problems have been avascular necrosis (AVN) due to disruption of the blood supply, nonunion and malunion due to unstable fixation.
The objective is timely fixation without disruption of the blood supply.
Angularly stable fixation is the solution to malunion. This is the rationale for using a pediatric hip locking plate.
The choice of implant size depends on the age and weight of the child.
Generally, a 130° angled plate is appropriate for fracture fixation as it corresponds most closely to the child's femoral neck-shaft angle. It offers the possibility of three parallel screws into the neck.
A plate with three shaft holes is sufficient for intracapsular fractures. If the fracture is extracapsular and involves the femoral shaft, pediatric hip locking plates are available with additional shaft holes.
Longer locking screws, not included in the standard pediatric hip locking plate set, may be required.
During preoperative planning, a decision should be made whether fixation needs to cross the physis. This decision will depend on the level of the fracture.
Note: It is more important to stabilize the fracture than to avoid crossing the physis.
2. Patient preparation and approaches
This procedure is normally performed with the patient in a supine position.
The guide wires for the pediatric hip locking plate are inserted.
This can be done using the dedicated angled guide, or by placing the wires through the plate with the screw-in guides attached to it.
An anteversion wire along the front of the femoral neck can be useful.
A 2.0 mm guide wire should be inserted high in the neck starting at least 5 mm below the trochanteric apophysis. This wire can be inserted using the angled guide, or freehand.
The position should be checked radiologically. On the lateral view, the wire should be in the middle of the femoral neck.
After the initial 2.0 mm wire, two 2.8 mm wires will be inserted using the dedicated angled guide.
The 2.8 mm wires will sit just above the mid-point of the femoral neck on the AP view.
Alternatively, these wires can be inserted through the plate with the locking guides attached.
With the three wires in place, the plate with locking guides can be slid over the wires onto the side of the femur.
The length of the screws is measured using a direct measuring device over the wire on the locking guide.
At this stage, a decision should be made whether a compression screw is required. If it is, it should be inserted through the third hole in the proximal part of the plate before any other screws are inserted. The compression screw can be a cortical lag screw. The hole for this screw should be drilled parallel to the 2.8 mm K-wires.
Note: A compression screw, if used, must be inserted before any locking screws.
After insertion of the compression screw, the locking screws should be inserted.
The guide wires are removed and replaced by locking screws one at a time. This ensures that fracture reduction is maintained by at least two wires, or screws, at all times.
If a compression screw has not been used, the third hole in the proximal part of the plate can be used to insert a further locking screw.
The plate should be secured to the shaft using two, or three locking screws. This prevents any disruption of the fracture fixation.
Definitive radiological images should be taken.
Consideration should be given to performing a capsulotomy for intracapsular fractures to prevent hemarthrosis under pressure.
The capsule should then be closed loosely to prevent a hemarthrosis forming under pressure, which can compromise the blood supply.
Routine closure is performed for the remainder of the wound, according to the surgeon’s preference.
Immobilization and weight bearing
If the fixation is stable, no external immobilization is required.
After a day or two of bed rest, the patient can be mobilized toe-touch weight bearing using crutches or a frame.
Increased weight bearing can be introduced as the fracture is judged to be healing depending on patient age. In an adolescent partial weight bearing at 6 weeks and full weight bearing at 12 weeks would be typical.
If screws cross the physis, and a lot of growth potential remains, they should be removed when the fracture is healed and consolidated.
In small children plate removal is advised to prevent bony overgrowth. Typically, this would be done at one year.
Plate removal is not compulsory in adolescents.
5. Protected weight bearing
After surgical stabilization, the construct should be sufficiently robust to allow protected weight bearing. Smaller children may not be able to comply with this and may need immobilization.
Forces through the hip are less with toe-touch weight bearing than with no weight bearing. Therefore, toe-touch is normally recommended for initial mobilization. This needs to be taught to children by a physiotherapist.
Range of movement
Range-of-movement exercises should start in the immediate postoperative period to prevent stiffness. Surgeons should indicate if any extremes of movement are forbidden.
Having started with toe-touch weight bearing, children progress to partial weight bearing and then to full weight bearing according to their age and the predicted rate of healing of their fracture. Even older adolescents should be fully weight bearing without aids at three months.
Swimming can be allowed as soon as partial weight bearing is permitted. Contact sports should be avoided for at least six months.
X-rays are generally taken immediately after the surgery and at 6 and 12 weeks.
Implants that cross the physis should be removed if there is significant growth remaining. The fracture should be healed and consolidated prior to removal (see Healing times).
Implants in young children should always be removed to prevent them from being covered by bony overgrowth.