Introduction
Leg numbness due to nerve damage is one of the considerable complications after anterior cruciate ligament (ACL) reconstruction using both bone–patellar tendon–bone (BPTB) and medial hamstring tendons. Such patients especially complain of uncomfortable feelings when falling on their knees. Harvesting a BPTB graft includes risks of damaging nerves and causing sensory disturbance. Pagnani et al. pointed out the risk of saphenous nerve damage by harvesting medial hamstring tendons in the region of the pes anserinus.
Many authors have reported the nerve distribution patterns of the infrapatellar regions. It is well known that both the medial cutaneous nerve of the femoral nerve and the infrapatellar branch of the saphenous nerve are distributed throughout the infrapatellar region and the anterior lower leg region. The saphenous nerve descends laterally along the femoral artery and enters the adductor canal. It then leaves the artery at the distal end of the canal to proceed vertically along the medial side of the knee and runs between the sartorius and gracilis tendons. In contrast, the medial femoral cutaneous nerve originates from the anterior cutaneous branches of the femoral nerve. The medial femoral cutaneous nerve runs laterally to the femoral artery, and then it crosses anteriorly to the artery at the apex of the femoral triangle to be distributed to the anteromedial thigh and the infrapatellar region. Branches of the medial femoral cutaneous nerve and the infrapatellar branch of the saphenous nerve connect to each other and form the subsartorial plexus in the infrapatellar region.
Bone–Tendon–Bone Autograft
Anterior knee pain including leg numbness has been reported as a main complication of ACL reconstruction using BPTB grafts. In previous reports, the rate of postoperative anterior knee pain ranged from 4% to more than 40%. Mishra et al. at first described a technique using two horizontal incisions for patellar tendon harvest for the purpose of more cosmetic scarring and reducing pain and flexion limitation. Kartus et al. used a technique with two vertical incisions and reported an insensitive area compared with the insensitive area that resulted from a traditional vertical incision, which averaged 24 cm. Tsuda et al. changed the method of approaching the retinaculum layer, opening it horizontally rather than splitting it to protect nerves using two horizontal incisions. They reported a 17% rate of postoperative leg numbness. Portland et al. compared a horizontal incision and a vertical incision and reported an infrapatellar numbness of 43% resulting from a horizontal incision and 59% resulting from a horizontal incision.
Bone–Tendon–Bone Autograft
Anterior knee pain including leg numbness has been reported as a main complication of ACL reconstruction using BPTB grafts. In previous reports, the rate of postoperative anterior knee pain ranged from 4% to more than 40%. Mishra et al. at first described a technique using two horizontal incisions for patellar tendon harvest for the purpose of more cosmetic scarring and reducing pain and flexion limitation. Kartus et al. used a technique with two vertical incisions and reported an insensitive area compared with the insensitive area that resulted from a traditional vertical incision, which averaged 24 cm. Tsuda et al. changed the method of approaching the retinaculum layer, opening it horizontally rather than splitting it to protect nerves using two horizontal incisions. They reported a 17% rate of postoperative leg numbness. Portland et al. compared a horizontal incision and a vertical incision and reported an infrapatellar numbness of 43% resulting from a horizontal incision and 59% resulting from a horizontal incision.
Hamstring Autograft
The donor site morbidity associated with harvesting a hamstring tendon graft is well recognized to be less common than that associated with harvesting a BPTB autograft. However, sensory disturbance is frequently observed in regions on the anterior lower leg after ACL reconstruction using medial hamstring tendons. The incidence of sensory disturbance is reported to range from 50% to 88%. Figueroa et al. reported that a hypoesthesia area was found in 77%, with an average area of 36 cm 2 . Kjærgaard et al. reported that the incidence of sensory disturbance did not change, but the area was decreased 1-year postoperatively in 46%. Inderhaug et al. performed a long-term evaluation and reported that sensory disturbance after hamstring tendon harvesting is probably permanent.
Clinical Examination
We clinically examined 103 patients who had arthroscopically assisted ACL reconstructions using medial hamstring tendons to investigate the frequencies and areas of sensory disturbance. As an operative procedure, we made two horizontal incisions for the arthroscopy portal and one longitudinal incision (2.5–3 cm) at the pes anserinus for the tendon harvest and the tibial drill holes. We performed an inside-out technique and used Endobutton (Smith & Nephew Endoscopy, Andover, Massachusetts) for femoral fixation. The clinical examination was performed for an average of 13 months (range 6–18 months) after the operation. We detected sensory disturbance on the anterior surface of the lower leg in 60 of 103 (58%) patients. We randomly selected 13 patients with sensory disturbance, and we neurologically examined in detail the regions of sensory disturbance. The regions of sensory disturbance were of various sizes and shapes ( Fig. 132.1 ). These regions were generally quadrilateral and located lateral to the longitudinal incision for tendon harvest and distal to the horizontal incisions for the arthroscopy portal. In the detailed neurological examination, in 8 of 13 legs (62%) the region was very close to the longitudinal incision (see Fig. 132.1A–C ), and in the other five legs (38%) it was relatively far away from the longitudinal incision (see Fig. 132.1D ). The region was lower than the superior end of the longitudinal incisions in 12 of 13 legs (92%); however, in one leg (8%) the region was close to the horizontal incisions (see Fig. 132.1C ). The region was located in the upper half of the lower leg in 10 legs (77%); however, in three legs (23%) the region was wider than others (see Fig. 132.1B ).
Anatomical Investigations
In our anatomical study, 51 lower limbs of 26 adult cadavers were used. In the mediodistal region of the patella, the nerve branches pierced the fascia cruris in various patterns and ran on the outer surface of the fascia to supply the skin ( Fig. 132.2 ). On the outer surface of the fascia, the nerve branches often were connected to each other. In the regions near the horizontal and longitudinal skin incision lines, the nerve branches ran on the outer surface of the fascia cruris in all legs.
After complete removal of the fasciae lata and cruris, the origin of the nerve branches was examined. The anterior surface of the lower leg was innervated by branches of the medial femoral cutaneous nerve proximally and by branches of the saphenous nerve distally. In addition, the patellar region was innervated by branches of the intermediate femoral cutaneous nerve superiorly and by branches of the medial femoral cutaneous nerve medially and inferiorly. Compared with our clinical examinations, the sensory disturbance regions were considered to correspond with the regions supplied by the branches of the medial femoral cutaneous and saphenous nerves.
In 33 of 51 legs (65%; Fig. 132.3A and B ), the infrapatellar branch of the saphenous nerve ran along the inferoposterior border of the sartorius muscle. The infrapatellar branch of the saphenous nerve pierced the distal part of the sartorius muscle in 16 of 51 legs (31%; see Fig. 132.3C ). In two legs (4%; see Fig. 132.3D ), the branch of the saphenous nerve emerged from the anterosuperior border of the sartorius muscle and ran lateralward horizontally. The infrapatellar region and the anterior region of the lower leg were generally supplied by branches of both the medial femoral cutaneous nerve and the saphenous nerve in various patterns. Branches of the medial femoral cutaneous nerve were also distributed to the anterior surface of the leg in eight legs (16%; see Fig. 132.3A ), and branches of the saphenous nerve were also observed to supply the infrapatellar region in two legs (4%; see Fig. 132.3D ). Branches of these nerves and their connections were distributed to the region around the insertion of the sartorius muscle. At least, therefore, the branches of these two nerves showed a complementary distribution and a broad transitional zone. One or more branches of the nerve ran across the line of the longitudinal incision in 88% of the cases.