Optimizing MR Imaging Detection of Type 2 Focal Cortical Dysplasia: Best Criteria for Clinical Practice

Discussion

The main findings of this systematic qualitative MR imaging analysis in a series of 71 consecutive patients with histologically confirmed type 2 FCD are as follows: 1) Only 59% had positive MR imaging findings despite optimal MR imaging techniques according to recommended guidelines;²³ 2) all patients with positive MR imaging findings presented with least 3 of the 6 recognized MR imaging criteria for type 2 FCD, with combined cortical thickening, blurring of the GWM interface, and the transmantle sign in 64% of patients; and 3) MR imaging features suggestive of type 2 FCD were overlooked on initial imaging in 40% of the cases, leading to late referral for surgical consideration.

Cortical thickening and blurring of the GWM demarcation are considered to be major signs, corresponding to the presence of dysmorphic neurons and balloon cells in the cortex and GWM junction, ectopic neurons, or axonal loss in white matter.^7,8,14,15 We additionally found subtle pseudothickening (ie, a subtle subcortical signal increase similar to that of the cortex) in a few patients, contrasting with the extensive thickening reported in previous studies.^3,7,11,15 The subtlety of this sign is in line with histologic data showing that cortical thickening is more focal and less obvious than previously described.^24,25 Cortical thickening has been the focus of an expert consensus, stipulating that it must be seen in 2 adjacent sections and with 2 different pulse weightings, to avoid being confounded with pseudothickening.²⁵ We did not observe any sign of lobar, gyral, or focal cortical atrophy, in contrast to others who reported atrophy in 15%–44% of cases (Table 1). This subtle and subjective sign, more common in type 1 focal cortical dysplasia,⁶ may have been underestimated in our analysis. It is also possible that what we considered a deep dysplastic sulcus was interpreted by others as pseudofocal atrophy.²⁶ We never observed any major cortical thinning as encountered in ischemic or traumatic sequelae.

The third major sign consisted of subcortical white matter abnormalities, which were found in all patients with positive MR imaging findings. This is likely due to the clear-cut signal changes on T2WI or FLAIR. Contrary to the authors of a previous report,¹⁶ we found no correlation between the presence of balloon cells and subcortical signal abnormalities (Table 2).

The signal increase of the cortex is a well-known sign of type 2 FCD, though rarely emphasized.^3,14 It was found in 48% of patients with positive MR imaging findings, within the 15%–62% range of previous reports (Table 1).^3,6,13,15 It was often moderate and was more clearly seen on FLAIR sequences. This abnormality could be related to a high attenuation of balloon cells in the cortex.¹⁴ With the increased use of 3D FLAIR and high-field MR imaging, this sign may, in the future, be easier to detect and become more reliable.

The transmantle sign is reported to be a specific feature for malformations of cortical development.²² This typical pattern overlaps the path of migrating neuroblasts, consistent with a disruption of early corticogenesis. It has been related to the presence of balloon cells and hypomyelination in the white matter underlying the dysplastic lesion.^7,22 This sign may also occur in other developmental abnormalities, such as venous or arteriovenous malformations²⁷ and, when isolated, is not specific for type 2 FCD. However, its association with cortical thickening and GWM blurring provides the most reliable pattern for the diagnosis of type 2 FCD. We observed the transmantle sign in >80% of patients with positive MR imaging findings, which is a higher proportion than that reported in even the most recent studies. In 2 recent studies, the frequency of the transmantle sign reached 60%,^7,28 whereas its frequency did not exceed 30% in other studies, suggesting that it may have been underestimated in earlier reports.^6,7,13,15,26

Abnormalities of sulcal morphology were present in nearly one-half of the cases with positive MR imaging findings. Such features are difficult to assess and are likely underestimated. Isolated minor sulcal abnormalities may also be retrospectively found in cortical areas containing a small type 2 FCD, as observed in nearly half of the cases with negative MR imaging findings (Fig 4). Sulcal abnormalities have already been described²⁹ but have received little attention, and their prevalence has never been evaluated. Only 1 study²⁶ confirmed by quantitative analysis that small type 2 FCDs were preferentially located at the bottom of an abnormally deep sulcus. Their physiologic mechanisms have not been elucidated to date. Nevertheless, most malformations of cortical development are associated with abnormal gyral/sulcal morphology, suggesting that the organization of sulci is intimately linked to the early stages of cortical development.³⁰

Another striking finding in this study is that abnormalities were arranged symmetrically relative to an axis perpendicular to the cortex. Of note, the axis of symmetry overlapped the trajectory of the transmantle sign. In addition, in half of the cases, a gradient of decreasing abnormal signal intensity from the bottom of the dysplastic sulcus to the surrounding gyri was found (Fig 1). This finding confirms that irrespective of the size of the lesion, maximum cellular abnormalities are located deep in the sulcus.

The proportion of patients with type 2 FCD with negative MR imaging findings (41%) was higher than that in most reported series ^{3,6⇓–8,13⇓–15,26} but similar to the rate reported using stereo-EEG as a diagnostic tool.³¹ This is likely explained by the fact that in our patients with negative MR imaging findings, surgery was based on a combination of FDG-PET and stereo-EEG. Balloon cells were found in the cortical specimens of 79% of our patients with negative MR imaging findings (Table 2), in contrast to previous reports suggesting that balloon cell FCDs (type 2b) are generally characterized by signal changes in the white matter.¹⁶

Finally, the localization of type 2 FCD was overwhelmingly frontal and rarely temporal in our series, as in others,^8,14,15 whereas other epileptogenic lesions are predominantly located in the temporal lobe. This suggests that frontal drug-resistant partial epilepsy with normal MR imaging findings should raise the suspicion of type 2 FCD, and this is supported by surgical series of cryptogenic partial epilepsy, in which up to 40% of the resected cortical specimens (especially in the frontal lobe) corresponded to type 2 FCD at histology.^9,31,32 Moreover, a recent report of the International League against Epilepsy noted that none of the children with epilepsy diagnosed with tumor or ischemia had normal MR imaging findings.¹¹

Our study has some limitations. It was retrospective and was based solely on patients who underwent surgery and thus does not represent the entire spectrum of type 2 FCD. Nevertheless, the study of unoperated patients would be limited by the lack of histologic confirmation. Furthermore, due to the lack of a control group, we cannot assess the specificity of the MR imaging abnormalities, especially the transmantle sign. In addition, positive MR imaging findings (59% of our patients) were based on conventional visual analysis. Voxel-based postprocessing methods proved a significant benefit in comparison with visual analysis alone^33,34 and would possibly decrease our rate of negative MR imaging findings. However, these techniques apply algorithms not applicable in routine practice. Furthermore, the feature maps direct the attention to suspicious regions, but the interpretation still requires an experienced reader to confirm, with conventional MR imaging, the presence of a type 2 FCD. Finally, the use of a 3T magnetic field could have increased the number of positive findings on MRI as reported in a recent study.³⁵