Abstract
Bone tunnel enlargement after ACL reconstruction has been described extensively in adults. However, little is known about this phenomenon in patients with open growth plates. Thus, the goals of the current study were to evaluate changes in bone tunnel size in patients with open growth plates after transphyseal ACL reconstruction with suspensory fixation and to correlate tunnel size with clinical outcome after medium-term follow-up. Fourteen patients with open growth plates were included that underwent primary transphyseal ACL reconstruction using hamstrings autografts and suspensory fixation. Mean follow-up time was 7 years. At the time of follow-up, MRIs of the operated knee were performed, and outcome was assessed using KOS-ADLS, Lysholm score, IKDC Subjective Knee Form score, Knee Examination Form score, and KT-1000 measurements. On MRI, the cross-sectional area of the bone tunnels was assessed using special axial cuts perpendicular to the axes of the tunnels. Two orthopaedic surgeons and two radiologists analysed the MRIs. Change in bone tunnel size from surgery to follow-up was calculated. No significant changes in bone tunnel size from surgery to follow-up were found. Regarding outcome measures, KOS-ADLS averaged 95%, Lysholm Score averaged 96 points, IKDC Subjective Knee Form averaged 95%, IKDC Knee Examination Form scores were 8A, 5B, 1C, and KT-1000 measurements averaged 1.8 ± 1.4 mm. No significant correlations were found between tunnel size at follow-up and outcome measures. Based on our study, bone tunnel enlargement does not occur in patients who have open growth plates and undergo ACL reconstruction using suspensory fixation.
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Introduction
In patients with open growth plates, a controversy still exists on the best treatment choice for torn anterior cruciate ligaments (ACL) [24]. Clinical studies have shown poor outcome in conservative treatment of ACL injuries in children and adolescents. Thus, early reconstruction may be recommended in these patients [27, 36]. Several surgical techniques were initiated, e.g. primary sutures, extra-articular tenodesis, transphyseal reconstructions, partial transphyseal reconstructions, and physeal sparing reconstructions [19, 22]. The fixation technique of the graft is crucial to prevent growth disturbances. Fixation hardware or bone plugs in the bone tunnel should not bridge the growth plate, and the bone tunnels should be filled with tendon across the growth plate [29, 39, 44]. Based on these findings, suspensory graft fixation may be recommended today [26, 43]. However, radiological studies in adults revealed a higher predisposition of bone tunnel enlargement in patients with suspensory graft fixation compared to aperture graft fixation [3, 32]. These studies in adults did not find a correlation between tunnel enlargement and clinical outcome, but bone tunnel enlargement after ACL reconstruction has been suggested to play an important role for revision ACL surgery, which is necessary in about 8% of patients after ACL reconstruction [47]. The purpose of the current study was to evaluate the change in bone tunnel size in patients that underwent transphyseal ACL reconstruction with open growth plates and suspensory graft fixation, and to correlate tunnel size with clinical outcome after medium-term follow-up. Towards this end we hypothesized that in patients with open growth plates and suspensory graft fixation, (1) bone tunnel enlargement occurs after a medium-term follow-up, and (2) bone tunnel size does not correlate with clinical outcome after a medium-term follow-up.
Methods
Patient selection
Fourteen patients with a mean age of 14.4 years (median 14.5 years, range 11–16 years) at the time of surgery were included that underwent primary transphyseal ACL reconstruction. Radiologically, all patients had open distal femoral and proximal tibial growth plates corresponding to Tanner stage 2 and 3 [12]. Patients with combined ligament injuries, fractures, and without any growth between time of surgery and follow-up were excluded. The mean time from injury to surgery was 7.6 months (median 5 months, range 6 days to 39 months). The fourteen patients included six girls and eight boys, with three right and eleven left knees affected. The average time of follow-up was after 7 years (median 8.3 years, range 23–133 months). The patients grew on average 0.08 m (median 0.04 m, interquartile range 0.02–0.07 m) from surgery to follow-up. Two patients underwent bilateral ACL reconstructions. One patient had open growth plates at the time of both surgeries and the other patient had open growth plates only during the first surgery. In this second patient, only the knee with open growth plates at the time of surgery was included. The Ethical Committee of the Otto-von-Guericke University Magdeburg approved this study (#78-2006). All patients signed informed consent.
Operative technique
Primary arthroscopic single-bundle ACL reconstruction was performed in all patients. Both tibial and femoral tunnels were drilled across the growth plate similar to the transtibial technique in adults. In one patient the graft was passed over-the-top at the femoral side; thus, no femoral bone tunnel measurements were performed. Hamstring autografts were used in all cases (Table 1), and suspensory tibial and femoral fixation was applied. Endobutton™ (Smith&Nephew, St. Petersburg, USA) fixation was used at the femoral site, and staples or sutures around a post were used at the tibial side. In addition to the ACL reconstruction, one lateral and two medial menisci were repaired, and one lateral meniscus was partially resected. Postoperatively, patients underwent full weight bearing, bracing with full extension, and a limited knee flexion to 90° continuously for 6 weeks. No complications were noted after surgery.
Bone tunnel measurements
In order to assess the size of the bone tunnels at follow-up, knee MRIs with special cuts were performed at the time of follow-up (1.5 Tesla scanner, Siemens, Erlangen, Germany). Slice thickness was 4 mm. T1-SE sequences were done with special axial cuts strictly perpendicular to the axes of the bone tunnels (Fig. 1). These perpendicular cuts were chosen to standardize the measurements, to measure the tunnel size independently from the drill angle, and to make the measured tunnel size comparable to the drill bit size that was used during surgery. At these special cuts, the size of the bone tunnels was measured at two different locations: (1) at the bone tunnel aperture and (2) 1 cm deep to the aperture (Fig. 2) [6]. Thus, the tunnel size at the aperture and at 1 cm tunnel depth was measured strictly perpendicular to the axes of the tunnels.
At the above-mentioned locations, the widest tunnel diameter (1. diameter) and the diameter strictly perpendicular to the widest diameter (2. diameter) were measured (Fig. 2). Thereafter, the cross-sectional area (CSA) was calculated by using an ellipse model \( \left( {A = {\frac{\pi }{4}} \times {\text{diameter}}1 \times {\text{diameter}}2} \right) \). The change in tunnel size from surgery to follow-up was calculated by subtracting the tunnel size calculated using the MRI measurements from the drill bit size that was reported in the surgical notes.
Clinical outcome
To assess clinical outcome, Knee Outcome Survey-Activities of Daily Living Scale (KOS-ADLS) [4, 15], Lysholm Score [45], and International Knee Documentation Committee (IKDC) Subjective Knee Form [14] were completed by the patients at follow-up. Clinical examination included the IKDC Knee Examination Form, and to further quantify the anterior knee laxity, KT-1000 arthrometer measurements were performed (134 N; MEDmetric Corp., San Diego, USA).
Statistical analysis
Wilcoxon signed ranks test was used to evaluate whether or not there was a statistical difference in tunnel CSA from surgery to follow-up. Spearman’s rank correlation coefficients were calculated to investigate the correlation between bone tunnel size and clinical outcome. The intraclass correlation coefficient (ICC) was performed to rate the reliability, using an absolute agreement and a two-way random effect model, in which subjects and raters are considered random effects. A post hoc sample size estimation was performed (power of 90%). Alpha level for statistical significance was set at P < 0.05. Data are given as mean (median, interquartile range) and, if reasonable, the range is also presented. SPSS 18 (Statistical Product and Service Solutions Inc., IL, USA) and Stata 11 (StataCorp, TX, USA) were used for statistical analyses.
Results
The averaged results of the four observers of the MRI measurements at follow-up are summarized in Table 2. The average CSA of the drill bit used during surgery was 43.2 mm2 (median 38.5 mm2, interquartile range = 38.5–50.3 mm2) [average diameter of 7.4 mm (median 7 mm, interquartile range = 7–8 mm)]. The changes in bone tunnel sizes from surgery to follow-up are summarized in Table 3. No significant tunnel size changes were observed from surgery to follow-up (Table 2). The average ICC was 0.73 ± 0.16. Of note, all ACL grafts were intact at the time of follow-up.
Regarding clinical outcome, the KOS-ADLS averaged 95% (median 96%, interquartile range 93–100%). In the subsection “Symptoms,” the average score was 95% (median 99%, interquartile range 90–100%), while in the subsection “Activity,” the average score was 95% (median 97%, interquartile range 92–100%). The Lysholm Score averaged 96 points (median 100 points, interquartile range 93–100 points). Of the 14 subjects, 11 patients were rated as excellent (>91 points) and three patients as good (84–90 points) according to the Lysholm score. The mean score of the IKDC Subjective Knee Form was 95 points (median 96 points, interquartile range 92–98 points). The IKDC Knee Examination Form was categorized eight times as A, five times as B, and once as C. The subject categorized as C was done so because of a ++ (clunk) pivot shift. Despite this result, this patient scored 97 points on the IKDC Subjective Knee Form, 100 points in the Lysholm score, and 91% in the KOS-ADLS.
An average side-to-side difference of 1.8 mm (median 1.5 mm, interquartile range 1–3 mm) was measured with the KT-1000 arthrometer. All patients demonstrated a normal range of motion with a mean knee flexion angle of 155.7° (median 160.0°, interquartile range 151.3–165.0°) and extension angle of 0.4° (median 0.0°, interquartile range 0.0–0.0°). Clinical evaluation showed no leg deformity.
No significant correlations were found between the clinical outcome data (KOS-ADLS, Lysholm score, IKDC Subjective Knee Form and Knee Examination Form, KT-1000 measurements) and the CSA of the tibial and femoral tunnels (Table 4).
Discussion
The most important finding of the current study was that no significant bone tunnel enlargement was found in patients with open growth plates and suspensory fixation after medium-term follow-up. This finding rejected our first hypothesis. These results contrast findings in adults, where bone tunnel enlargement after ACL reconstruction has been extensively described, especially with suspensory fixated grafts [13, 32, 38, 42].
Different reasons have been given to explain tunnel enlargement after ACL reconstruction, including mechanical causes such as bungee cord effect and windshield wiper effect [46], biological causes such as synovial fluid [7] and inflammatory cytokines in the bone tunnel [48], aggressive rehabilitation, heat exhaustion because of drilling, and immune response to the graft [18]. Almost all fixation techniques and grafts types have been noted to be accompanied by the phenomenon of bone tunnel enlargement in the tibia and femur [32, 38]. However, hamstring grafts placed in the cancellous bone area and fixed suspensorily were more likely to develop this phenomenon [9, 38]. The increased bone tunnel enlargement after ACL reconstruction using suspensory fixation might be because of increased graft motion in the bone tunnel. This increased graft motion would explain the findings of a cadaveric study that showed more anterior-posterior translation and internal rotation with suspensory fixation compared to aperture fixation [16].
However, bone tunnel enlargement increases in vivo through the first 6 months post surgery, and afterwards it decreases slightly without reaching initial tunnel size [6, 35]. In contrast to these findings in adults, in the current study bone tunnel enlargement was not found and one reason might be the high potential of bone growth in patients with open growth plates compared to adults [30, 41].
To evaluate the possible correlation between the tunnel size at follow-up and the clinical outcome, well-known outcome measures were used such as the Lysholm score, KOS-ADLS, IKDC Subjective Knee Form and Knee Examination Form, and KT-1000. The results of the questionnaires and the IKDC Knee Examination Form were similar to other studies evaluating the outcome of ACL reconstruction in patients with open growth plates [1, 10, 20, 22, 28, 31, 40] and slightly superior compared to most of the results in adults [2, 5]. The KT-1000 arthrometer measurements showed an increased anteroposterior knee laxity of 2 mm in the operated knee, which is similar to studies in immature patients regardless of physeal sparing or partial transphyseal techniques [1, 11]. As in previously published adult studies, no significant correlations were found between the above-mentioned outcome measures and the tunnel size at follow-up in our patients with open growth plates. These results confirmed our second hypothesis. This may have occurred because tunnel size does not affect outcome, or the study may not have contained a sufficient number of subjects to detect a correlation. Additionally, the assessment forms have not been validated for children and adolescent yet; thus, it remains questionable whether the results of subjective assessments of children, adolescents, and adults are comparable [37].
In addition to the above-mentioned standard outcome measures, growth disturbances and leg malalignment are important aspects for the outcome of patients with open growth plates after ACL reconstruction. In the current study, none of these complications were observed despite drilling across the growth plates. This might be due to suspensory fixation without bridging the growth plate with hard fixation devices, appropriate drill bit sizes, and appropriate graft tensioning. Previous studies have described growth disturbances caused by hard fixation devices (e.g. bone plugs or screws) that crossed the growth plate [21, 23, 25]. Additionally, animal studies found unfilled bone tunnels [39], graft tensioning with high loads [8, 34], and bone tunnels through the growth plate that exceeded a certain size as causes for growth disturbances [33]. The critical size of the bone tunnel relative to the growth plate to avoid growth disturbances was reported as 13% of the transverse diameter (medial-to-lateral width) and 3% of the CSA. Studies in animals and humans that respected the above-mentioned findings did not find growth disturbances after transphyseal ACL reconstruction [17, 39, 40]. Thus, based on our experience and the experiences of others [22], it seems to be sufficient to use a transphyseal technique and a suspensory fixation for ACL reconstruction in patients with open growth plates and Tanner stage 2–3.
This study has some limitations. Regarding the measurement of the bone tunnel size, CT scans would be superior, but high exposure to roentgen radiation causes ethical difficulties. However, MRI was found useful in other studies evaluating bone tunnel diameter [7]. Furthermore, bone tunnel size at surgery was recorded from the surgical notes, which has been also the standard method in several previously published studies. Additionally, a recent CT study showed that the drill bit size used during surgery is almost similar to the size of the bone tunnel measured immediately after surgery [13]. Moreover, no control group with another treatment option was established. However, a control group may not be necessary because tunnel size at follow-up was compared to tunnel size at the time of surgery. Our sample size is limited; however, patients with open growth plates at the time of ACL reconstruction are rare and our post hoc sample size analysis revealed that up to 10,370 patients would be necessary to find a significant difference in bone size from surgery to follow-up. Nevertheless, to our knowledge this was the first study evaluating bone tunnel size change in combination with a clinical assessment using transphyseal tunnel drilling after a mean follow-up time of 7 years.
Conclusions
Bone tunnel enlargement was not observed in patients with open growth plates that underwent ACL reconstruction using suspensory fixation and thus, there might be a decreased concern in revision surgeries about tunnel enlargement in these patients. Additionally, there did not seem to be a correlation between clinical outcome and tunnel size in these patients.
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Acknowledgments
We wish to thank M. Röpke, M.D. and W. Nebelung, M.D. for their support.
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Kopf, S., Schenkengel, JP., Wieners, G. et al. No bone tunnel enlargement in patients with open growth plates after transphyseal ACL reconstruction. Knee Surg Sports Traumatol Arthrosc 18, 1445–1451 (2010). https://doi.org/10.1007/s00167-009-1041-4
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DOI: https://doi.org/10.1007/s00167-009-1041-4