Abstracts

Introduction

Injuries or tears to the anterior cruciate ligament (ACL) in athletes or physically active individuals are seen very often in orthopedic practice. Epidemiological studies have showed that the incidence is approximately 80,000 injuries per year.¹1. Shimokochi Y, Shultz SJ. Mechanisms of noncontact anterior cruciate ligament injury. J Athl Train. 2008;43(4):396-408.

The first reports on ACL injuries appeared in the literature in the nineteenth century.²2. Stark J. Two cases of ruptured ligaments of the knee joint. Edinb Med Surg. 1850;74:267-71. Records of surgical reconstruction first appeared at the beginning of the twentieth century.³3. Hey-Groves EW. Operation for the repair of the crucial ligaments. Lancet. 1917;2:674-5. Over the last 30 years, many surgical techniques have been described for reconstructing this ligament, using several structures as a graft source. A long path was followed until the technique described by Campbell⁴4. Campbell WC. Reconstruction of the ligaments of the knee. Am J Surg. 1939;43:473-80. in 1939, which used the patellar ligament, was returned to. Also in that year, Macey⁵5. Macey BH. A new operative procedure for repair of ruptured cruciate ligaments of the knee joint. Surg Gynecol Obstet. 1939;69:108-9. described the first technique using the flexor tendons of the semitendinosus and gracilis (ST-G).

Although the great advances in surgical techniques have reduced the time taken for patients undergoing ACL reconstruction to return to their activities,⁶6. Bollen S. Advances in the management of anterior cruciate ligament injury. Curr Orthop. 2000;14:325-8. we did not find any studies in the literature correlating the angles of the tunnels with the postoperative results.

There is no consensus regarding the various techniques for ACL reconstruction that have been described, in relation to comparisons between the postoperative results. There is therefore a need for better examination of the possible variable that might correlate with a better final result.

Currently, tibial tunnels are constructed using prefabricated guides that are adjustable according to the angle that is desired.

The objective of this study was to ascertain the coronal angle of the femoral and tibial tunnels that would provide the best postoperative result from ACL reconstruction surgery, using the following assessment criteria: patient's complaints, satisfaction with the result, Lysholm-Tegner questionnaire (^{Annex 1} Annex 1. Lysholm questionnaire. ), IKDC questionnaire (^{Annex 2} Annex 2. IKDC subjective questionnaire. ), clinical examination and hopping on one foot.

Material

The knees of 16 patients were evaluated (Table 1). These patients were seen at the knee surgery outpatient clinic of the Sobradinho Regional Hospital, Federal District, Brazil, and had undergone ACL reconstruction performed by the same surgeon, who was a specialist in knee surgeon.

The demographic characteristics (gender, age body mass index (BMI) and dominant leg) are listed in Table 1.

The inclusion criteria were as follows: a postoperative period of between 24 and 48 months; ACL injury alone, as confirmed by means of magnetic resonance imaging before the operation; physiotherapy applied after the operation; and having been released from rehabilitation (with or without returning to the same activity level as before the injury).

The exclusion criteria comprised presence of any associated injuries to the ligaments, menisci or joint cartilage, revision surgery, inflammatory signs, neuromuscular disorders, infection, arthrofibrosis, lower-limb fractures, or advanced osteoarthrosis in the femoropatellar or tibiofemoral joints with evident displacement of the joint axis.

Table 2 details the factors correlated with the type of sport practiced, the ground and the conditions under which the injury and the rehabilitation took place.

All the patients underwent the same standard surgical technique, consisting of grafting a single band from the semitendinosus and gracilis tendons (ST-G) and use of a proximal crosspin fixation implant and an absorbable interference screw, with a distal cortical post (Fig. 1).

Method

The patients were given explanations regarding the aims of the study and, after agreeing to participate, they signed a free and informed consent statement.

The present study was submitted to the research ethics committee of the Foundation for Health Sciences Teaching and Research (FEPECS) and was approved by this body under report no. 0018/2010 and protocol no. 211/2010.

Non-sequential numbers were attributed to each knee that underwent surgery.

The clinical assessment was made firstly in a consultation office, where the patients' histories relating to the postoperative period were taken and the questions of the subjective International Knee Documentation Committee questionnaire (IKDC, 2000) and the Tegner-Lysholm Knee Scoring Scale were applied and scores were attributed. The latter scale has been validated for the Portuguese language.⁷7. Peccin MS, Ciconelli R, Cohen M. Questionário especifico para sintomas do joelho Lysholm Knee Scoring Scale': tradução e validação para a lingua portuguesa. Acta Ortop Bras. 2006;14(5):268-72. Clinical examinations were performed in order to find out whether there was any presence of joint effusion, crepitation, pain or laxity (Lachman, pivot-shift and anterior drawer tests), and knee goniometry was performed. All these data were recorded on a specific form (^{Annex 3} Annex 3. Research protocol followed by the interviewees and interviewers. ).

The patients performed a hop test, from which a lower-limb symmetry index was obtained. This comprised the ratio of measurements of the distance jumped by means of a one-leg hop on the side that underwent surgery in comparison with the non-operated side.

Lower-limb symmetry index = (distance with operated limb/distance with contralateral limb) × 100

The patients then underwent radiography (X-ray) of the operated knee in anteroposterior (AP) view, in an upright standing position with weight-bearing in parallel and with parallel rays. The joint line tangential to the condyles and the axes of the tunnels that had been constructed for the grafts to be inserted were traced out on these radiographs, and in the coronal plane, and the angles in degrees were measured (Fig. 2).

Mean values were calculated from these angles and the patients were then grouped into categories, according to the angles of the femoral and tibial tunnels on the AP knee radiographs (Table 3).

The postoperative results in terms of the following variables were evaluated for each group, in relation to the tunnel data:

Results

The mean angle of the tibial tunnels in the coronal plane (TTC) was 64.81° and that of the femoral tunnels (FTC) was 67.68°. The values measured at both sites were between 61 and 70° for most of the patients. The difference in alignment between the tibial and femoral tunnels (TTC-FTC) is shown in Table 4.

The factors relating to the postoperative period and the evaluations according to the tests applied are shown in Table 5.

Group I (femoral tunnels ≤ 65° and tibial tunnels in the coronal plane ≤ 65°)

There were five individuals in this group (four men and one woman). Their mean age was 29.6 years; the youngest was 22 years of age and the oldest was 46.

This group included the patients with tibial and femoral angles that were the most horizontal in the coronal plane. Both the femoral tunnels and the tibial tunnels had angles of between 55° and 64°, with a mean of 61.2° for the femoral tunnels and 61° for the tibial tunnels. The difference between the angles of the tibial and femoral axes ranged from varus of 9° to valgus of 9°.

All of these patients had suffered injuries while practicing sports, each on a different type of ground surfacing. One of them said that he had not returned to sports activity and declared that he was dissatisfied with the result from the surgery.

The mean IKDC score was 86.4 (range: 72-96) and the mean Lysholm score was 94.4 (range: 85-100).

During the physical examination, two patients presented positive Lachman tests.

In the hop test, the values ranged from 0.87 to 1 and the mean limb symmetry index was 0.95.

Group II (femoral tunnels ≤ 65° and tibial tunnels in the coronal plane > 65°)

The inclusion criteria for this group were fulfilled by only one individual: a 25-year-old male.

This patient presented a tibial angle that was more vertical and a femoral angle that was more horizontal, i.e. in principle similar to what is seen in the technique for constructing an arthroscopic transportal femoral tunnel.

The diaphysis-tunnel angle in the femur was 60° and in the tibia, 72°. The difference between the angles of the tibial and femoral axes was a valgus angle of 12°.

This patient presented maximum scores in the IKDC and Lysholm-Tegner questionnaires (100 and 97 points, respectively) and had negative Lachman, anterior drawer and pivot-shift tests in the physical examination. His limb symmetry index was 1 in the hop test. This patient did not present any spontaneous complaints when asked during the study period. He declared that he was satisfied with the result from the surgery and he returned to physical activity eight weeks after the operation.

Group III (femoral tunnels > 65° and tibial tunnels in the coronal plane ≤ 65°)

There were five individuals in this group (four men and one woman. The mean age of this group was 30.4 years: the youngest was 23 years of age and the oldest was 40.

This group included patients with tibial angles that were more horizontal and femoral angles that were more vertical in the coronal plane.

The angles formed by the axes of the diaphyses and tunnels were, for the femur, between 68° and 70° (mean: 69.2°) and, for the tibia, between 60° and 64° (mean: 61.8°). The difference between the angles of the femoral and tibial axes varied from -10° to -4°, i.e. always in varus.

All of the patients in this group had suffered injuries while practicing sports: three on synthetic grass and two on mats.

The scores from the IKDC questionnaire ranged from 85 to 97, with a mean value of 91.2, and the scores from the Lysholm questionnaire were from 88 to 100, with a mean of 93.4.

During the physical examination, one patient presented positive Lachman and pivot-shift tests. One individual stated that he had not returned to sports activity, but he considered himself satisfied with the results from the surgery.

In the hop test, the mean value of the limb symmetry index was 0.94, with a minimum of 0.85 and a maximum of 1.

All of these patients stated that they were satisfied with the postoperative results, although there were some spontaneous complaints such as pain while squatting, snaps and insecurity in performing jumps using the operated leg.

Group IV (femoral tunnels > 65° and tibial tunnels in the coronal plane > 65°)

There were five individuals in this group (four men and one woman). Their mean age was 30 years: the youngest was 20 years of age and the oldest was 45.

The angles formed between the axes of the diaphyses and tunnels among the patients in this group were the most vertical in the coronal plane. In the femur, the values ranged from 70° to 82° (mean: 74.2°), while in the tibia they ranged from 66° to 73° (mean: 70.2°). The difference between the angles of the femoral and tibial tunnels varied from -12° to + 3°, with a mean of -4° (varus).

All of the patients in this group had suffered injuries while practicing sports: three on natural grass, one on a parquet floor and one on synthetic grass.

The scores from the IKDC questionnaire ranged from 89 to 96, with a mean of 92.2, and the scores from the Lysholm questionnaire ranged from 95 to 100, with a mean of 97.8 (Fig. 3).

During the physical examination, two patients presented positive Lachman and pivot-shift signs. One individual said that he had not returned to sports activity, but he considered himself satisfied with the result from the surgery.

In the hop test, the mean value of the limb symmetry index was 0.99 with a minimum of 0.92 and maximum of 1.07 (Fig. 4).

There were spontaneous complaints with regard to increased flexibility and paresthesia on the lateral face of the leg operated.

The means obtained from evaluating the study variables are presented in Table 6.

Discussion

The present study was conducted with the aim of correlating the angles of the bone tunnels with the postoperative results from ACL reconstruction. Some remarks need to be made regarding the criteria that led to choosing this topic and in relation to the methodology used.

Studies on patients with ACL reconstructions that compared two types of graft, i.e. ST-G and the patellar tendon (PT), using the same fixation technique, have shown that there is no significant difference in anteriorization of the tibia. The choice between grafts therefore continues to be at the surgeon's discretion.⁸8. Abdalla RJ, Monteiro DA, Dias L, Correia DM, Cohen M, Forgas A. Comparação entre os resultados obtidos na reconstrução do ligamento cruzado anterior do joelho utilizando dois tipos de enxertos autólogos: tendão patelar versus semitendineo e grácil. Rev Bras Ortop. 2009;44(3):204-7. This study did not aim to compare graft sources. Thus, only patients who underwent the technique with ST-G grafts were selected in the present study.

With regard to graft fixation, comparison between different fixation methods was not our objective. The personal preference of the surgeon involved in this study, who has had great experience in such procedures, is to use a proximal crosspin with an absorbable interference screw and a distal post with a metal screw and washer.

The inclusion and exclusion criteria had the objective of limiting the individuals studied to those who solely presented a unilateral ACL injury, thereby eliminating the bias relating to associated injuries. However, among the 300 patients who underwent this surgery over the three-year study period, only 26 fulfilled all the criteria and, of these, only 16 returned to the clinic for assessments for the present study.

The measurements of the tunnel angles were all made by the same researcher, by means of simple radiographs. This is an inexpensive and widely available technique, but it gives rise to the possibility of variation of the angle measured according to the incidence of the rays. New studies using magnetic resonance imaging might reduce or even eliminate this bias.

The patients were divided into groups according to the mean values for the angles of the tunnels constructed. Thus, only one patient could be included in Group II. It was precisely this individual who presented the best values for the postoperative results, among the variables studied. In the future, more patients could be included in new studies, in order to obtain a larger sample and ascertain whether these findings would be maintained, and also whether significance would be reached with a more substantial number of individuals studied.

Biomechanical studies on cadavers have shown that constructing the femoral tunnel at an angle of 60° in the coronal plane minimizes the impact of the graft against the posterior cruciate ligament (PCL) and reduces the tension on the graft under flexion. These studies have also shown that the loss of flexion and anterior laxity are greater when the tibial tunnel is drilled at an angle ≥75° in the coronal plane, and that if the femoral tunnel is constructed more vertically via an transtibial route (between 70° and 80°), there will be an impact against the PCL. These tunnels increase the tension on the graft under flexion, which explains the limitation on flexion that is observed clinically. This impact against the PCL stretches the graft, which may explain the greater anterior laxity.⁹9. Simmons R, Howell SM, Hull ML. Effect of the angle of the femoral and tibial tunnels on tension of an anterior cruciate ligament graft. J Bone Joint Surg Am. 2003;85(6):1018-28.

It has been suggested from in vitro studies that, in order to reduce the tension under flexion, the tibial tunnel should be positioned at 60° in the coronal plane, because the angle of the femoral tunnel and the tension on the graft would be controlled by this angle and this would improve the flexion and diminish the anterior laxity.¹⁰10. Howell SM, Hull ML. Checkpoints for judging tunnel and anterior cruciate ligament graft placement. J Knee Surg. 2009;22(2):161-70.

Thus, the enthusiasm for conducting new studies with the aim of finding the ideal angle for the tibial and femoral tunnels is justified.

In the present study, it was observed that the groups analyzed presented differences in the outcome variables according to the tunnel angles. Group I, in which the tunnels were most horizontal (mean value for the tibial tunnel = 61° and for the femoral tunnel, 61.2°), had the lowest score for the IKDC questionnaire (mean: 86.4) and the second lowest score for the Lysholm questionnaire (mean = 94.4) and for the limb symmetry (mean: 0.956). Group II, in which the tibial tunnel was more vertical (72°) while the femoral tunnel remained more horizontal (60°), showed the best results and the values were the maximum possible for the IKDC, Lysholm and limb symmetry index variables. Group III, in which the femoral tunnel was more vertical (mean: 69.2°) while the tibial tunnel was more horizontal (61.8°), had the second worst IKDC (mean: 91.2) and the worst values for the Lysholm variables (93.4) and for the limb symmetry index (0.946). Group IV, in which the tibial tunnel (70.2°) and femoral tunnel (64.2°) were the most vertical, showed the second best results for the three variables: Lysholm (97.8), IKDC (92.2) and limb symmetry index (0.996).

Conclusion

From the data obtained in the present study, it can be concluded that the results from groups II and IV were superior to those from groups I and III. The two groups with the best indices were the ones with the tibial tunnel more vertical. The highest scores from the IKDC, Lysholm and limb symmetry index were obtained from a patient in whom the angles constructed were 60° for the femoral tunnel and 72° for the tibial tunnel, which gave rise to a varus alignment for the tunnels. The worst results for the variables studied were found in the group in which the tibial tunnel was most horizontal and the alignment of the tunnels was most displaced toward valgus. Nonetheless, further studies are needed in order to confirm these findings.

Annex 1. Lysholm questionnaire.

Annex 2. IKDC subjective questionnaire.

Annex 3. Research protocol followed by the interviewees and interviewers.

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