Keywords
anterior cruciate ligament - ligaments - knee injuries - tibia
Introduction
The anterior cruciate ligament (ACL) is the main restrictor of the anterior translation
of the tibia over the femur, being responsible for 85% of the anterior knee stabilization.[1]
[2] It also acts by limiting internal rotation and secondarily restricting valgus and
varus stresses.[2]
[3]
[4]
Anterior cruciate ligament injury is one of the most common ligament injuries of the
knee, with increasing incidence due to the rising number of individuals involved with
the practice of sports activities.[2]
[4] It occurs predominantly secondary to indirect trauma, with an association between
knee valgus stress and internal tibial rotation.[2]
[4]
[5] Failure to properly treat previous instability can lead to injuries to other structures
or long-term degenerative changes. Its surgical treatment has good results, although
the patient is not always able to return to sports activities with the same performance
as before the injury.[5]
[6]
[7]
The identification of risk factors for ACL injuries during physical and sports activities
has become a focus of musculoskeletal research. Understanding the mechanisms that
produce this instability allows the identification of people at increased risk so
that preventive interventions can be applied.[6]
[7]
The posterior tibial slope has been increasingly studied as a potential risk factor
for ACL injury, showing quite varied results between its increase and ligament injury.[6]
[8]
[9]
Some biomechanical studies of the knee joint verify that, during an axial compression
load, the posterior tibial slope acts producing a force component that leads to the
anteriorization of the tibia in relation to the femur.[8]
[9]
[10]
[11]
[12] It is known that the ACL is the primary retention system against this type of knee
movement, that is, an increase in the posterior tibial slope will generate a stress
increase in this ligament.[1]
[11]
[12] Although some studies suggest the relationship between the posterior slope of the
tibial plateau and the ACL injury, the level of risk presented by this intrinsic factor
remains unclear.[6]
[8]
[9]
Reducing the occurrence of ACL injuries in young active individuals remains an important
goal in sports medicine. The objective of the present study is to evaluate, in the
Brazilian population, the relationship between patients with ACL injury due to indirect
trauma and the increase in posterior tibial slope.
Material and Methods
This is a retrospective study, conducted through the analysis of medical records and
digital radiographs of patients present in the database of a tertiary hospital for
orthopedics and traumatology in Brazil, from January 2014 to January 2016.
The sample consisted of two groups, with Group I formed by patients diagnosed with
ACL injuries due to indirect trauma. During the study period, 643 patients with ACL
injury were identified. To form group I, patients who did not have medical records
clearly showing the trauma mechanism as indirect were excluded. Other exclusion criteria
were radiographs of the knee that prevented reliable measurement of posterior tibial
slope (poor quality, radiological changes due to previous surgery or osteoarthritis).
A control group (Group II) was formed from a database of knee radiographs, paired
by age with Group I. Any patient with evolution of the medical record showing knee
ligament injury was excluded. Research subjects with images that prevented reliable
measurement of the tibial slope were also excluded, as described for group I. After
analyzing the exclusion criteria, each group was composed of 275 patients. The sample
age ranged from 16 to 55 years old. [Table 1] provides data on age and gender distribution.
Table 1
Variable
|
ACL injury due to indirect trauma (n = 275)
|
Control group (n = 275)
|
Total (n = 550)
|
Age (years)
|
Mean (SD)
|
33.0 (8.8)
|
38.4 (9.7)
|
35.7 (9.7)
|
Sex (N)
|
Male
|
241 (87.6%)
|
212 (77.1%)
|
453 (82.4%)
|
Female
|
34 (12.4%)
|
63 (22.9%)
|
97 (17.6%)
|
All of the patients underwent a radiographic study according to the routine recommended
by the institution. The 500 mA Shimadzu (RADspeed MF, Shimadzu, Kyoto, Japão) X-ray
machine was used with a 50 KV and 25 mA technique. A 30 × 40 cm film was placed at
one meter from the ampoule of the digital radiographic apparatus. Then, images in
lateral view (profile) with a 30° semiflexion were obtained.
The patients had their knee profile radiographs analyzed, and their posterior tibial
slope measured by three orthopedics specialists who were unaware of which group each
patient belonged to. This measurement was performed by drawing a line on the posterior
tibial cortical and another on the proximal articular surface of the tibia. The angle
formed between the perpendicular to the posterior cortical line and the line of the
articular surface corresponded to the measurement of the posterior tibial slope, as
described in [Figure 1] and determined by the technique of Hohmann et al.[13]
Fig. 1 Demonstration of measurement of posterior tibial inclination.
The statistical analysis was composed by the Student t test for independent samples
in the comparison of continuous data between the group with ACL injury by indirect
mechanism and the control group, and by the chi-squared test (χ2) when comparing categorical
data. In the association between continuous variables, the Pearson correlation coefficient
was used.
A Receiver Operating Characteristic (ROC) curve was built to identify the best cutoff
point for posterior tibial slope for indirect trauma. The strength of the association
between elevated posterior tibial slope and indirect trauma was measured by odds ratio
(OR) and its respective 95% confidence interval (CI).
The normality of data distribution was assessed using the Kolmogorov-Smirnov test
and graphical analysis of the histogram. The significance determination criterion
adopted was the level of 5%. The statistical analysis was processed using IBM SPSS
Statistics for Windows, Version 20.0 (IBM Corp., Armonk, NY, USA). The study was previously
approved by the research ethics committee of the hospital where the study was carried
out under the number CAAE 79853617.0.0000.5273.
Results
The values of the posterior tibial slope ranged from 2.6° to 18.1° in the first group,
with an average of 9.1°, and from 0 to 17.6° in the second, with an average value
of 7.3°. Evaluating the variables posterior tibial slope and gender as a whole, according
to the Student's t test, we verified that there was no significant association (p = 0.66), that is, men did not present a medium tibial slope (8.2 ± 2.9 degrees) significantly
different from women (8.1 ± 2.8 degrees).
When we performed the association between tibial slope and the two groups under study,
we observed that the group of patients with ACL injury due to indirect trauma presented
a tibial slope (in degrees) significantly greater than the control group in the total
sample and in the subsamples stratified by gender. [Table 2] provides the descriptive of the tibial slope (mean, standard deviation [SD], minimum
and maximum, in degrees) according to the groups and the corresponding descriptive
level (p-value) of the Student t test for independent samples, in the total sample and stratified by gender (men and
women).
Table 2
Sample
|
ACL injury due to indirect trauma
|
Control group
|
p-value
|
All (n = 275 × 275)
|
Mean (SD)
|
9.1 (2.9)
|
7.3 (2.6)
|
< 0.0001
|
Minimum–maximum
|
2.6–18.1
|
0–17.6
|
Men (n = 241 × 212)
|
Mean (SD)
|
9.0 (2.9)
|
7.3 (2.6)
|
< 0.0001
|
Minimum–maximum
|
2.6–18.1
|
0.10–17.6
|
Women (n = 34 × 63)
|
Mean (SD)
|
9.3 (3.0)
|
7.4 (2.5)
|
0.001
|
Minimum–maximum
|
3.1–14.6
|
0–12.5
|
[Figure 2] illustrates the ROC curve of posterior tibial slope for the group with ACL injury
due to indirect trauma in the total sample. The overall accuracy of a test can be
described as the area under the ROC curve, and the larger the area, that is, the closer
to 1, the better the test.
Fig. 2 ROC curve of the tibial slope (in degrees) for patients with ACL injury from indirect
trauma.
An area of 0.67 was observed with a 95%CI of 0.62 to 0.71, expressing a “moderate/regular”
discriminatory power with a significant value (p < 0.0001). In addition, considering the control group as a reference category, the
best cutoff point for the first group can be identified, which was, according to the
ROC curve in the present study sample, a posterior tibial slope ≥ 8°, reaching a sensitivity
of 63.3% and a specificity of 62.5%.
[Table 3] provides the frequency (n) and percentage (%) of the tibial slope ≥ 8° according
to the groups under analysis, the corresponding descriptive level (p-value) and the odds ratio (OR) for ACL injury due to indirect trauma with the respective
95%CI in the total sample. It was observed, in the total sample, that the group with
ACL injury due to indirect trauma presented a proportion of tibial slope ≥ 8° (63.3%)
significantly higher than the control group (37.5%), with an OR of 2.8 (95%CI: 2.04–4.07)
([Figure 3]).
Table 3
Tibial slope
|
ACL injury due to indirect trauma
|
Control group
|
p value
|
OR
|
CI 95%
|
≥ 8°
|
174 (63.3%)
|
103 (37.5%)
|
< 0.0001
|
2.87
|
2.04–4.07
|
< 8°
|
101 (36.7%)
|
172 (62.5%)
|
Fig. 3 Tibial slope ≥ 8° according to the groups under study.
However, in [Table 4], it was observed that group I presented a proportion of posterior tibial slope ≥ 8°
significantly higher than the control group by stratifying into subsamples according
to gender, with an OR of ∼ 3 for ACL injury from indirect trauma.
Table 4
Tibial slope
|
ACL injury due to indirect trauma
|
Control group
|
p-value
|
OR
|
CI 95%
|
All (n = 275 × 275)
|
≥ 8 degrees
|
174 (63.3%)
|
103 (37.5%)
|
< 0.0001
|
2.87
|
2.04–4.07
|
< 8 degrees
|
101 (36.7%)
|
172 (62.5%)
|
Men (n = 241 × 212)
|
≥ 8 degrees
|
149 (61.8%)
|
74 (34.9%)
|
0.011
|
3.02
|
2.05–4.43
|
< 8 degrees
|
92 (38.2%)
|
138 (65.1%)
|
Women (n = 34 × 63)
|
≥ 8 degrees
|
25 (73.5%)
|
29 (46.0%)
|
< 0.0001
|
3.25
|
1.31–8.08
|
< 8 degrees
|
9 (26.5%)
|
34 (54.0%)
|
Discussion
The association between ACL injury and posterior tibial slope is well-documented in
the literature, even though there is still not a consolidated consensus on the level
of risk that such an association may have. The present study specifically sought to
assess the importance of the degree of posterior tibial slope in patients with ACL
injuries originating from indirect trauma. In view of the results found, there is
no association between the gender of the patient and the intensity of the posterior
tibial slope, differently from what was found by Hohmann et al.,[13] who found greater angulations among females. In the face of equal exposure conditions,
it is known that females have a greater risk of ACL injury than males;[7]
[14] however, the posterior tibial slope could not be considered, according to the results
found, one of the reasons for this increased risk.
The relationship between posterior tibial slope and patients with ACL injury due to
indirect trauma showed that an increase in angulation would represent an increased
risk to the ACL structure when compared to a control group, proving an important interference
of the anatomy and biomechanics of the knee in the stability of the joint.
This relationship has been previously described by some authors[9]
[15]
[16]
[17]
[18] who demonstrated that posterior tibial slope has an adverse effect on knee kinematics.
On a cadaveric model, Dejour et al.[15] showed a 6 mm increase in anterior tibial translocation for each 10° increase in
posterior tibial slope. Similarly, Giffin et al.[16] demonstrated a significant increase in anterior tibial translocation if the posterior
slope was increased by 4.4° after a high tibial osteotomy in the opening wedge. Fening
et al.[9] performed high tibial osteotomies in the opening wedge and reported an increase
in anterior tibial translocation with an increase in tibial slope.
McLean et al.[19] suggested that axial compression of a knee with a greater slope of the lateral tibial
plateau, compared to that of the medial tibial plateau, may cause greater anterior
movement of the lateral tibial compartment, compared to the other, generating stress
in internal rotation of the tibia in relation to the femur, further increasing the
load on the ACL.
The statistical analysis of the present study found that patients with an angle ≥
8° are 3 times more likely to damage the ACL through indirect trauma than patients
with an angle < 8°, regardless of gender.
Some authors advocate the performance of deflection osteotomy as a surgical treatment
for patients with excessive posterior tibial slope associated with ACL rupture.[20]
[21] Dejour et al.[20] evaluated retrospectively a series of patients with tibial slope > 12° who underwent
a second ACL reconstruction review associated with deflection osteotomy. After a minimum
follow-up of 2 years, the 9 patients in the study, who met the adopted criteria, were
free of complications and with satisfactory functional scores, justifying the procedure
for selected cases.
The present study had limitations because it was retrospective. This led to the exclusion
of research subjects, due to incomplete information in the medical records, in addition
to making it difficult to match the groups on other important criteria, such as the
level of sports activity performed or on other associated risk factors for ACL injuries,
such as angular deformities.
Conclusion
It is concluded that the increase in posterior tibial slope is associated with a greater
risk of ACL injury due to indirect trauma, regardless of gender. Thus, corrective
measures should be considered, particularly for those who present excessive tibial
slope associated with anterior knee instability.