Medial meniscal extrusion: a validation study comparing different methods of assessment

The role of the meniscus in the pathogenesis of painful knee osteoarthritis (OA) is a common target for investigation [1, 7, 22]. As the meniscus “fails”, it extrudes from the joint line and it has been suggested that this is an important step in the development of OA [9]. Large, longitudinal cohort studies of patients, such as the Osteoarthritis Initiative (OAI) [13] and the Multicentre Osteoarthritis Study (MOST) [6], provide opportunities to investigate meniscal extrusion over time by performing MRI scans at sequential time points in the same patient. In these cohorts, MRI scans of the knee are obtained in supine non-weight-bearing position, the same position that scans are obtained in clinical practice. This makes the assessment of these cohorts relevant to the clinical situation. The meniscus is known to behave differently in weight-bearing situations [14, 21]. An absolute extrusion distance of 3 mm or greater than 30% of the total meniscal width is commonly used as the definition of an “extruded” meniscus [8, 11, 15]. An accurate, validated measurement of extrusion is essential to categorise patients appropriately. Segmenting the tibia and meniscus to allow three-dimensional analysis of meniscus has been identified as the most accurate method of determining meniscal extrusion [2, 23, 24] and is considered the reference standard although it is not a suitable technique in large cohorts due to the laborious nature of manual segmentation. Contemporary measurements of meniscal extrusion therefore tend to utilise one of two methods. The first (“Bony Landmarks”) method uses a fixed bony point in the knee on coronal MRI slices, usually the apex of the medial tibial spine [5, 6, 16, 17]. This Bony Landmarks is chosen as it allows the same coronal slice to be reproducibly selected when comparing scans taken on the same patient at different time points. Once the apex of the medial tibial spine has been identified, the horizontal distance between the most medial aspect of the tibia and the most medial aspect of the meniscus on this image is measured. The second (“Coronal Slices”) method inspects all coronal MRI slices and then measures the horizontal distance between the most medial aspect of the tibia and the most medial aspect of the meniscus [7, 8, 11] on the slice that demonstrates the greatest extrusion. Whilst both these methods may be practical, to date neither has been validated as an accurate method of measuring extrusion.

Problems exist with both methods of assessment because both assess the meniscus on one anatomical slice. The “Bony Landmarks” method may lead to false-negative results as menisci that are not extruded at that point but are extruded further anteriorly or posteriorly might be incorrectly labelled as “not extruded”. Similarly, with the “Coronal Slices” method, measuring horizontal extrusion on Coronal Slices anterior and posterior to the midline may falsely increase the perceived “extrusion” as the approximately circular edges of the tibia and meniscus may not be parallel (Fig. 1, line A, distance X).

A more appropriate absolute measurement of extrusion distance would be to assess the perpendicular distance between the edge of the tibia and the edge of the meniscus (Fig. 1, line B, distance Y), although this measurement is only possible following segmentation of the meniscus and tibia—not on Coronal Slices.

In order to determine the most accurate method of measuring medial meniscal extrusion for use in both longitudinal cohorts and clinical assessments, this study aimed to compare the “Bony Landmarks” and “coronal slice” methods to a reference standard—the maximal perpendicular extrusion of the meniscus from the tibial edge calculated from 3D volumetric reconstructions of segmented tibia and meniscus. It was hypothesised that there is no difference in the location of maximal meniscal extrusion or the extent of maximal extrusion when assessed using different measurement techniques compared to the reference standard.

Ethical approval was obtained from National Research and Ethics Committee South Central Oxford A (OxRECA 12/SC/006).

High-resolution, supine, 3T MRI scans (Achieva 3.0T X series, Philips Medical Systems International, B.V, Eindhoven, Netherlands) were obtained on 20 asymptomatic patients (20 knees, all males, mean age 28.3 years [SD 6.2]) as part of a larger study into the aetiology of knee OA. The knee was positioned as per a standardised, routine clinical protocol with the patient supine and the ankles supported on foam pads allowing the knee to fall into full extension. With this protocol, the apex of the patella is placed in the centre of the coil, and the knee is held in position with foam pads. A three-plane localiser scan is performed to ensure the correct position of the knee. In the coronal plane, the slices are aligned with the back of the femoral condyles with the joint in the middle of the field of view. The scan then proceeds posterior to anterior from the back of the femoral condyles to the centre of the patella anteriorly. All scans were then reviewed by a single trained observer (LJ) to confirm the absence of osteophytes, degenerative meniscal tears, chondral cartilage lesions and ligamentous insufficiency. In three scans, degenerative cartilage lesions were observed in the medial compartment and these scans were therefore discarded. In total, 17 asymptomatic knees with no degenerative cartilage change in the knee were included in the study. This number of scans is comparable to other studies that have explored segmentation of the meniscus [2]. An a priori power analysis was performed using a power of 0.8, a p value of 0.05 and an effect size of 0.5. This indicated a sample size of 11 to be compared across the three methods.

The geometry of each patient’s tibial plateau and meniscus was segmented using Mimics (v. 14.1, Materialise, Belgium) and exported as stereolithography (STL) files. Meniscal segmentation was performed via a method previously validated by Bowers et al. [4], using meniscal volumes calculated by surface integration. Coronal Slices provided near perpendicular views for precise meniscal edge definition at the meniscosynovial rim. Accurate outlining was further aided by the high contrast between the low intrameniscal and high extrameniscal signal intensity on T2-weighted images. 3D meniscal reconstructions were then obtained.

These files were imported into MATLAB (R2010b, The MathWorks Inc., Natick, MA, USA), and medial meniscal extrusion was calculated using the following technique. Firstly, the tibia and meniscus geometry was rotated to give a view down the longitudinal axis of the tibia. The breadth of the tibial plateau and the highest point (the apex of the medial tibial spine) were then determined.

A “Circular Edge of Tibia to Circular Edge of Meniscus” (CETCEM) algorithm was then used to establish the reference standard method. A coronal plane through the medial tibial spine was used to divide the tibia and meniscus into anterior and posterior portions creating four distinct anatomical regions. Multiple points on the medial edge of the anterior and posterior tibia and anterior and posterior meniscus were selected, and circles were fitted to these points. The edges of both the meniscus and tibia were linearly interpolated to fill gaps caused by the scan slice thickness. Vectors were projected from the centre of the anterior and posterior tibial circles to corresponding points on the circumference of the circles fitted to the anterior and posterior portions of the meniscus (Fig. 2). Extrusion was calculated by subtracting the radius of the tibial circles from the length of the vectors. As this represented the true perpendicular extrusion of the meniscus from the tibial edge, this was used as the reference standard with which to compare the other methods of assessment.

For the comparator groups (“Coronal Slices” and “Bony Landmarks”), measurements were carried out on slices at 1-millimetre intervals from the front to the back of the tibial plateau in the AP plane (simulating Coronal Slices on an MRI scan). Extrusion was calculated as the horizontal difference between the most medial edge of the meniscus and the tibia (Fig. 3) at each 1-mm interval. Measurements of meniscal extrusion were made on the simulated slice containing the apex of the medial tibial spine (representing the “Bony Landmarks” method), as well as the simulated slice with the maximal horizontal extrusion measured when comparing each 1-mm AP interval (representing the “Coronal Slices” method).

To allow comparison of extrusion between patients (and therefore between tibias of different sizes), the position of the measurements was expressed as a percentage of the AP depth of the tibial plateau, i.e. 0% corresponded to the front (most anterior point of joint line) of the tibia, as well as in absolute distance in millimetres from the front of the tibia.

Using the commonly accepted definition of extrusion as 3 mm, and then defining the meniscus as either extruded or not, intraobserver reliability studies for the binary extrusion of the meniscus using all three methods demonstrated a kappa value of 1.0 (SE 0.00, p = 0.00) indicating perfect agreement. Interobserver reliability studies for the binary extrusion of the meniscus using all three methods demonstrated a kappa value of 0.82 (SE 0.16 p = 0.00) indicating substantial agreement.

The mean AP tibial breadth was 52.9 mm (range 47.2–61.6 mm, SD 3.6), and the highest point of the medial tibial spine was found at mean 29.8 mm (range 28–33 mm, SD 1.7) from the most anterior point of the tibial plateau. This corresponded to 56% of the AP tibial breadth and was the anatomical location of the slice used in the “Bony Landmarks” method.

The median maximum meniscal extrusion was 4.8 mm (SD 1.7, mean 4.7) when measured by the “Coronal Slices” method, compared to 3.1 mm (SD 1.2, mean 3.0) when measured by the CETCEM method. The median maximum meniscal extrusion measured using the “Bony Landmarks” method was 2.2 mm (SD 1.5, mean 2.4).

A Friedman’s ANOVA for nonparametric data indicated that the maximum meniscal extrusion was significantly higher when measured using the “Coronal Slices” method compared to both the CETCEM method (4.8 vs 3.1 mm) and the “Bony Landmarks” method (4.8 vs 2.2 mm) (p < 0.001). In addition, there was a statistically significant difference between the estimated maximum extrusion using the CETCEM method as compared with the “Bony Landmarks” method (3.1 vs 2.2 mm) (p < 0.001).

Bivariate correlation analysis of the maximum extrusion between measurement techniques indicates Spearman’s rho correlation coefficients between the CETCEM method and “Coronal Slices” method of r = 0.64 (p = 0.04), and between the “Bony Landmarks” and CETCEM method of r = 0.72 (p < 0.001). The “Bony Landmarks” and the “Coronal Slices” method corresponded poorly, r = 0.53 (p = 0.03).

The most important finding of this validation study comparing different methods of measuring meniscal extrusion is that maximum medial meniscal extrusion does not occur reliably in one location along the medial edge of the tibia (in the AP plane), irrespective of the measurement method used. The “Coronal Slices” method, as expected, found the location of maximal extrusion to be very anterior on the tibia compared to the reference CETCEM method and the “Bony Landmarks” method. In addition, the “Coronal Slices” method overestimated maximal extrusion compared to the reference CETCEM method. The “Bony Landmarks” method tended to underestimate maximal extrusion. However, the maximal extrusion measured using the “Bony Landmarks” method correlated more closely with the reference CETCEM method than the maximal extrusion measured using the “Coronal Slices” method.

The role of the pathological and normal meniscus in the pathogenesis of osteoarthritis of the knee has been debated for some time. The link between joint space narrowing and meniscal extrusion in symptomatic knee OA was first explored by Gale et al. [7] who demonstrated that meniscal subluxation is strongly associated with symptomatic knee OA, suggesting that joint space narrowing was secondary to extrusion and not hyaline cartilage loss. They postulated that, upon extrusion, the meniscus fails to perform its primary function of distributing loads across the hyaline cartilage leading to increased contact pressures and subsequent cartilage degeneration. Thus, meniscal extrusion has become a focus for clinical and epidemiological investigators. The importance of a validated method of assessment, particularly in longitudinal studies that inspect the same knee at different time points, is clear. The use of meniscal extrusion measurements in the assessment of the efficacy of both meniscal transplant and meniscal repair techniques is also common place [3, 10, 12, 18‐20, 25].

This is the first time to our knowledge that different methods of measurement of extrusion have been directly compared in the same knee. This study indicates that if investigators choose to assess meniscal extrusion using “Coronal Slices” method, they will consistently overestimate the maximum extrusion distance. This occurs because the edge of the tibia and the meniscus is not parallel anterior and posterior to the midline, and therefore, measurements are not made perpendicular to the tibial edge (Fig. 1). It also suggests that, as the CETCEM reference method demonstrates, maximal extrusion occurs at a point 26.0 mm (48%) from the front of the knee. Measuring meniscal extrusion at the level of the highest point of the medial tibial spine is therefore a reasonable proxy for the more labour-intensive CETCEM method.

There are limitations to this study. The MRI scans utilised in this study were taken in a supine position, and it is well established that the meniscus behaves differently under weight-bearing conditions [21]. However, the aim of this study was to determine the most suitable method for assessing meniscal extrusion for use in both longitudinal cohorts and in assessing outcome of interventions such as meniscal transplantation. In clinical practice, MRI scans are obtained in the supine non-weight-bearing position. Similarly, MRI scans are obtained supine in large longitudinal cohorts such as the Osteoarthritis Initiative. Hence, this study is applicable for both these uses. Further studies on the location of meniscal extrusion on the weight-bearing scan should be performed when this method of imaging is used more commonly in the clinical setting. The results of this study should not be extrapolated weight-bearing scenario. This study has only considered those with no degenerative change in the knee. It may be that the meniscus in a degenerative knee does not behave in the same way [12]. For example, the presence of medial tibial osteophyte may act as a physical barrier to limit extrusion.

The CETCEM method requires the tibia and the meniscus to be segmented. This makes it unsuitable for longitudinal datasets as manual segmentation is time-consuming and requires specialist software. In this study, the CETCEM method was used as a theoretical “reference standard” against which other methods can be compared. This study indicates that the “Coronal Slices” method tends to overestimate extrusion and should not be used as an assessment method. Clinicians assessing longitudinal change in meniscal extrusion, whether as an indicator of impending OA or to determine the long-term success of meniscal transplantation, should be aware of the limitations of the “Coronal Slices” method and assess extrusion at the level of the medial tibial spine.

In cross-sectional MRI imaging of the medial meniscus of the knee, assessing extrusion at the level of the apex of the medial tibial spine represents a pragmatic and validated alternative to the reference standard method of segmentation.