Femoral mechanical-biological graft fixation in ACL reconstruction in young patients.

INTRODUCTION

ACL reconstructions in young, skeletally immature athletes are potentially harmful, both for the tibial and femoral growth plates.1,2

Over the last decade, the results of non-operative treatments have been poor, but several authors now recommend that skeletally immature patients undergo surgery,3–5 despite its potential risks.6

Observation alone may also be harmful to the health of the knee joint,7 because young athletes tend to be less cooperative and frequently resume the practice of rotational sports even against medical advice.8 Therefore, a consensual decision should be made by the parents, the athlete and the medical team before other structures of the joint (e.g., articular cartilage or any of the menisci) are irreversibly affected.7

BACKGROUND

Among the many surgical techniques for ACL reconstruction,8–12 the “over-the-top” technique is often chosen for young patients because it preserves the open femoral growth plate.13 This plate is usually fixed with spiked washers that do not promote long-term biological fixation. A different method could be used to insert the tendon graft into the lateral femoral condyle and achieve permanent tendon-bone integration. Such a method should combine intrinsic mechanical strength capable of holding the tendon graft immediately after its insertion with the capacity to biologically induce tendon-bone integration over time. This combination makes the system independent of the hardware used in the long term. Such a result can be achieved with the use of custom-made trephines, as described below.

SURGICAL TECHNIQUE

The semitendinosus and gracilis tendons are obtained as usual through a small incision in the anteromedial surface of the proximal tibia.

After removing all muscle tissue, the tendons are folded over themselves, and the free ends are stitched together. An 8-mm initial tibial tunnel, 1.5 cm in length, is drilled to a point just before entering the tibial growth plate. This tunnel is perforated with a trephine that removes a 1-cm bone plug.

The tunnel is drilled up to the tibial crest with a 6-mm drill. The tendons are passed through the joint and over the top of the lateral femoral condyle and exit on the lateral side.

At this point, an entrance hole parallel to the femoral growth plate is made through a lateral 2.5-cm skin incision with a 4-mm drill. Using a guide pressed against this hole, a 1.2-cm wide and 0.5-cm long bone washer is cut with another specially designed trephine (Figure 1, A and B).

Figure 1

(A) Cutting of the bone washer with a special trephine parallel to the growth plate. (B) Removal of the bone washer with the spongious screw.

The lower side of the hole is trimmed to avoid a possible sharp, harmful edge. After that, a spongious screw with a metal washer and the bone washer are passed through the two tendon loops (Figure 2, A and B). The bone washer presses the tendons against the bottom of the larger hole when connected to the screw (Figure 3, A and B).

Figure 2

Drawing (A) and picture (B) of the spongious screw with the metal washer and the bone washer being passed through the two tendon loops after countouring the lateral femoral condyle in an “over-the-top” fashion.

Figure 3

(A) Drawing of the bone washer pressing the tendons against the bottom of the larger hole when connected to the screw. (B) Picture of final fixation.

In contrast to their use in skeletally mature adult patients, the screws are not deeply inserted into the lateral femoral condyle across open growth plates in young athletes (Figures 4 and 5); they may be easily removed under local anesthesia when growth is complete.

Figure 4

The screw in its place of attachment.

Figure 5

Image of the screw in the bone one year after surgery.

The distal end of the tendon grafts is then fixed to the medial tibial metaphysis with a cortical screw and an AO plastic spiked washer. Finally, the cylindrical bone plug is pressed against the tendons at the entrance of the tibial hole, and both ends of the ACL graft are fixed with the screw. Full weight-bearing activity without crutches is allowed six days after surgery.

RESULTS

This surgical technique was used in 12 patients with fully satisfactory results. All athletes reached skeletal maturity without signs of angle deformity or an unexpected shortening of the operated limb.

Even the required second lateral incision was considered acceptable by the patients because of the advantage of not having to wait for reconstruction.

CONCLUSION

This technique provides not only strong, immediate mechanical fixation but also long-term biological fixation supported by bone growth around the tendon graft.