Abstract
Purpose
To evaluate a MRI postprocessing tool for the enhanced and rapid detection of focal cortical dysplasia (FCD).
Methods
MP2RAGE sequences of 40 consecutive, so far MRI-negative patients and of 32 healthy controls were morphometrically analyzed to highlight typical FCD features. The resulting morphometric maps served as input for an artificial neural network generating a FCD probability map. The FCD probability map was inversely normalized, co-registered to the MPRAGE2 sequence, and re-transferred into the PACS system. Co-registered images were scrolled through “within a minute” to determine whether a FCD was present or not.
Results
Fifteen FCD, three subcortical band heterotopias (SBH), and one periventricular nodular heterotopia were identified. Of those, four FCD and one SBH were only detected by MRI postprocessing while one FCD and one focal polymicrogryia were missed, respectively. False-positive results occurred in 21 patients and 22 healthy controls. However, true positive cluster volumes were significantly larger than volumes of false-positive clusters (p < 0.001). The area under the curve of the receiver operating curve was 0.851 with a cut-off volume of 0.05 ml best indicating a FCD.
Conclusion
Automated MRI postprocessing and presentation of co-registered output maps in the PACS allowed for rapid (i.e., “within a minute”) identification of FCDs in our clinical setting. The presence of false-positive findings currently requires a careful comparison of postprocessing results with conventional MR images but may be reduced in the future using a neural network better adapted to MP2RAGE images.
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Introduction
Malformations of cortical development comprise heterogeneous disorders of disrupted cerebral cortex formation caused by various genetic, infectious, vascular, or metabolic etiologies [1]. Among those, focal malformations represent an important subgroup as they may be amenable to epilepsy surgery. Focal malformations include focal cortical dysplasia (FCD) but also gray matter heterotopia and focal polymicrogyria.
Gray matter heterotopia are clusters of normal neurons in abnormal locations and commonly categorized into periventricular nodular heterotopia (previously designated as subependymal heterotopia), subcortical heterotopia, and subcortical band heterotopia (SBH) (previously called double cortex) [1]. Polymicrogyria means an excessive number of abnormally small cerebral gyri, most commonly in a bilateral location in the posterior parts of the Sylvian fissures. However, any part of the cerebral cortex including the frontal, occipital, and temporal lobes can be affected [1].
FCD are characterized by disordered cortical lamination with or without abnormal cell types. FCD are the most commonly resected epileptogenic lesions in children and the third most common lesions in adults [2]. Structural MRI abnormalities comprise an increased cortical thickness, blurring of the gray/white matter junction, a transmantle sign, and/or an abnormal gyral/sulcal pattern [3]. These abnormalities can be subtle but highlighted by voxel-based morphometric MRI analysis and comparison of results to a group of healthy controls. Using this approach, the morphometric analysis program (version of 2018; MAP18) utilizes MPRAGE data sets and generates morphometric maps in terms of junction, extension, and thickness images enhancing the visualization of abnormal blurring of the gray/white matter junction, abnormal extension of gray matter into deep white matter as well as an increased cortical thickness [4,5,6]. The sensitivity of FCD detection is higher by using MP2RAGE instead of MPRAGE sequences as potential FCD lesions are displayed with larger volumes and higher mean z-scores [7]. The MP2RAGE sequence is a MPRAGE sequence with two inversion pulses at 700 ms and 2500 ms, respectively. From the two images, a so-called unified image is calculated using the formula \(\mathrm{MP}2\mathrm{RAGE}=\frac{\mathrm{contrast TI}1 \times \mathrm{ contrast TI}2}{{\mathrm{contrast T}1}^{2} + {\mathrm{contrast TI}2}^{2}}\). The MP2RAGE sequence produces images with a higher B1 homogeneity than the MPRAGE sequence and is therefore particularly suited for postprocessing [8, 9]. Another recent modification is the integration of an artificial neural network (ANN) in the postprocessing tool MAP18. This ANN was trained with morphometric and brain segmentation maps from MPRAGE sequences and generates FCD probability maps which reflect the voxel-wise probability for dysplastic tissue [10]. Here, although the ANN was trained with MPRAGE images, FCD probability maps were calculated from MP2RAGE images and presented as an overlay on the original MP2RAGE input image (cf. examples in Figs. 1, 2, 3, and 4).
We hypothesized that by presentation of original MR images together with co-registered maps resulting from morphometric MRI analysis, FCD can be detected very fast, i.e., “within one minute.” The aim of this prospective study was therefore to evaluate the feasibility and accuracy of such an approach.
Methods
Within a 6-month period (1.9.2019–29.2.2020), consecutive patients with focal epilepsy syndromes suggested by semiology and/or EEG were included. Inclusion criteria were that patients had been considered MRI-negative so far and were studied with an epilepsy-dedicated protocol including a MP2RAGE sequence on a 3-T Prisma scanner (Siemens Healthineers, Erlangen, Germany) [7]. The study was in accordance with the 1964 Helsinki Declaration and its later amendments and approved by the local ethical committee.
Postprocessing
The unified images of the MP2RAGE sequence were processed with SPM 12 (http://www.fil.ion.ucl.ac.uk/spm/) running in MATLAB R2014b (MathWorks, Natick, MA, USA). DICOM images were converted to NIfTI format; segmented into gray matter (GM), white matter (WM), and cerebrospinal fluid (CSF) maps; and normalized to the Montreal Neurological Institute (MNI) space. Using the MAP18 software, junction, extension, and thickness images were calculated as described before [4,5,6]. In addition, these morphometric maps were used as input for an artificial neural network (ANN) trained with MRI data of FCD patients and healthy controls as described elsewhere [10]. However, it should be noted that this ANN has been trained with MPRAGE data as FCD cases with MP2RAGE sequences required for such training are currently not available in sufficient quantity. The output of the ANN after classification of all voxels in the unified MP2RAGE image comprises a FCD probability map with values closer to 1 indicating voxels more likely to be dysplastic tissue and values closer to 0 representing non-dysplastic brain tissue or compartments outside of the brain. Finally, all results of MRI postprocessing (i.e., morphometric maps and FCD probability map) were inversely normalized (i.e., transferred to native space), co-registered, reconverted to DICOM format, and exported to the PACS system. The FCD probability map was displayed as an overlay in the original MP2RAGE image and could be screened very fast by scrolling through the co-registered data sets (Fig. 1).
Evaluation
Epilepsy-dedicated MRI scans of 40 consecutive patients were evaluated by a senior neuroradiologist (> 20 years of experience) by visual inspection of the conventional MR images first, and then—for the “one minute” approach—together with the co-registered MRI postprocessing results. A FCD was diagnosed when the typical radiologic criteria [3] were clearly identifiable in the conventional MR images. A lesion was regarded as detected by the “one minute” approach (i.e., true positive, TP), if the results in the FCD probability map overlapped with the dysplastic lesion, thus allowing for a rapid detection. Furthermore, we differentiated between lesions that were already recognizable in the first screening of the conventional MRI images and those only detected in the “one minute” approach by means of co-registered postprocessing results. In order to calculate false positives (FP), we generated morphometric results including FCD probability maps of 36 healthy controls who had been studied to build up a normative database. Number and volumes of TP and FP clusters in the FCD probability map were measured using the imaging platform NORA (www.nora-imaging.org).
Statistics
Descriptive statistics include age, gender, clinical findings/semiology, and location of lesions. The normal distribution of TP and FP FCD cluster volumes was checked by Shapiro–Wilk test. The Mann–Whitney U test was used to compare TP and FP FCD volumes. A receiver operating curve (ROC) was calculated to determine the optimal cut-off volume between TP and FP. All statistical analyses were performed using R statistics (R Core Team, https://www.R-project.org).
Results
Out of 40 consecutive patients, 15 patients had FCD, three subcortical band heterotopia (SBH), one periventricular nodular heterotopia, and one focal polymicrogyria respectively. Twenty patients were MRI-negative (Table 1).
Four FCD (## 7, 8, 22, 40; i.e., 27% of FCD) and one SBH (#25; i.e., 33% of SBH) were only detected by postprocessing using “within a minute” approach (Figs. 2, 3). One FCD with a subtle transmantle sign was missed with the “within a minute” approach and only visible in the junction image of the MAP (#15). The focal polymicrogyria (#2) was not visualized with the “within a minute” approach.
In another two patients, the extent of the FCD displayed by postprocessing was visually larger than in the conventional MR images (##32, 33).
FPs were found in 29 patients: 11 patients had no FP, 16 patients had one or two FP clusters with a volume of 0.01–0.63 ml, and 13 patients more than two, often scattered FP clusters (volumes of 0.01–8.29 ml), respectively.
Median lesion volume of true positive (TP) clusters was 0.53 ml (0.04–13.1 ml; IQR 1.17) compared to 0.04 ml (0.01–8.29 ml; IQR 0.10) of the FP clusters (p < 0.001).
The AUC of the receiver operating curve was 0.851 with a cut-off volume of 0.05 ml best indicating a true dysplastic lesion (n = 15).
With respect to FPs in healthy controls, 14 of 36 had no FP, 11 subjects had singular FP clusters, three patients had two, and eight patients more than two FP clusters, respectively. The median volume of FP was 0.09 ml (0.01–4.29 ml, IQR 0.28).
Discussion
FCD can be detected “within a minute” when MP2RAGE data sets are postprocessed by morphometric analysis and then presented together with morphometric results in the PACS, thus allowing for a very fast screening by scrolling through the co-registered images. In the present study, this approach helped to detect four FCD and one subcortical band heterotopia which otherwise would have been overlooked. In another two patients, the lesions were larger in the postprocessed compared to the conventional images which encourages the reader to consider it a lesion and not a FP. Yet, there were also FP clusters in the FCD probability maps, both in patients and in healthy controls. However, volumes of true dysplastic lesions were significantly larger than FP clusters, at least in our study population.
According to the ROC analysis of 15 FCD, a threshold size of 0.05 ml differentiated best between FCD and FP findings in our study. The number of underlying FCD cases is too small to make a definite recommendation for a threshold value here. It is probably also not possible to determine a fixed lower limit for the size of FCDs, as they may become arbitrarily small. In any case, if a lesion is suspicious according to postprocessing, it is essential to check whether the typical criteria of FCD can also be identified in the conventional MR images.
One limitation of our study also offers hope for the future: for the generation of the FCD probability maps, we used the artificial neural network (ANN) currently available in MAP18, which was trained on MPRAGE data sets. A new training using MP2RAGE data for this study was not possible so far due to the low numbers of FCD with MP2RAGE sequence. In this respect, the false-positive findings could also be partly a consequence of this still insufficient adaptation. Future training with MP2RAGE data might reduce the number of FP and increase both sensitivity and specificity for FCD detection. For FCD detection during a presurgical work-up, sensitivity is more important than specificity or the number of FPs. An undetected FCD may prevent the patient from further work-up, but a putative FCD would not be operated without proving its epileptogenicity using clinical and electrophysiological data. Therefore, a high sensitivity is more crucial in this clinical situation than a high specificity.
The morphometric analysis program (MAP) is integrated in standard presurgical workflows of over 60 epilepsy centers in 22 different countries [10]. It has independently been validated for its clinical benefits against expert neuroradiological assessments [11,12,13] with potential impact on further, also invasive and presurgical patient management [14]. The resulting morphometric maps as well as the FCD probability map resulting from the recently integrated ANN [6] can be easily inversely normalized back to the native space within the program and directly used for stereotactic and/or neuronavigation procedures. The program typically processes MPRAGE sequences with isotropic 1mm3 large voxels; the MPRAGE sequence itself is a fundamental part of epilepsy imaging protocols [15,16,17]. However, House and co-workers found higher mean z-scores of FCD when processing 3D T2-weighted instead of MPRAGE data sets [18]. We recently showed that not only the mean z-scores but also the volumes of FCD are larger when processing MP2RAGE instead of MPRAGE data sets. Especially, the higher volume of FCD facilitated the separation from FP when scrolling through the MP2RAGE data sets [7]. By displaying larger and brighter lesions, the MP2RAGE sequence increases the diagnostic confidence which may have an impact on the decision to proceed with invasive EEG recordings or epilepsy surgery. The higher diagnostic yield of the MP2RAGE sequence likely results from the intrinsic correction of B1 inhomogeneities which is achieved by combining two MPRAGE data sets acquired interleaved at different inversion times [7,8,9]. The drawback is a longer acquisition time (≈ 8 versus 4 min) and the higher risk for movement artifacts.
The major limitation of this study is that only six of 15 patients with FCD have been operated so far (## 12, 22, 25, 29, 33, 40). Four of those underwent stereo-electroencephalographic (SEEG) recordings which clearly showed ictal EEG activity within and around the lesions. Here, the “one minute” approach led to extended electrode implantations proving the accuracy of the findings with SEEG recordings (#22, Fig. 3).
In conclusion, by postprocessing and displaying a MP2RAGE sequence and the co-registration output map in the PACS, subtle or even unvisible FCD can be detected “within a minute.” Fully automated MRI analyses have the potential to easily identify FCD and to contribute to overcome the underutilization of epilepsy surgery and prolonged latencies for referral to epilepsy centers.
Data and materials availability
On reasonable request to corresponding author, the underlying data can be accessed.
Code availability
MAP18 and re-integration into a PACS are based on the freely available Statistical Parametric Mapping toolbox (SPM12, Wellcome Trust Centre for Human Neuroimaging, London, UK). MAP18 is administered by Huppertz HJ, Zurich, Switzerland.
Change history
22 February 2022
OA funding note shall be added to the article to fulfill the contractual requirement of the Compact agreement.
Abbreviations
- FCD:
-
Focal cortical dysplasia
- SBH:
-
Subcortical band heterotopias
- MAP:
-
Morphometric analysis program
- ANN:
-
Artificial neural network
- TP:
-
True positives
- FP:
-
False positives
- PACS:
-
Picture archiving communication system
References
Severino M, Geraldo AF, Utz N Tortora D, Pogledic I, Klonowski W, Triulzi F, Arrigoni F, Mankad K, Leventer RJ, Mancini GMS, Barkovich JA, Lequin MH, Rossi A (2020) Definitions and classification of malformations of cortical development: practical guidelines. Brain 143:2874–2894
Blumcke I, Spreafico R, Haaker G, Coras R, Kobow K, Bien CG, Pfäfflin M, Elger C, Widman G, Schramm J, Becker A, Braun KP, Leijten F, Baayen JC, Aronica E, Chassoux F, Hamer H, Stefan H, Rössler K, Thom M, Walker MC, Sisodiya SM, Duncan JS, McEvoy AW, Pieper T, Holthausen H, Kudernatsch M, Meencke HJ, Kahane P, Schulze-Bonhage A, Zentner J, Heiland DH, Urbach H, Steinhoff BJ, Bast T, Tassi T, Lo Russo G, Özkara C, Oz B, Krsek P, Vogelgesang S, Runge U, Lerche H, Weber Y, Honavar M, Pimentel J, Arzimanoglou A, Campos, AU, Noachtar S, Hartl E, Schijns O, Guerrini R, Barba C, Jacques TS, Cross HJ, Feucht M, Mühlebner A, Grunwald T, Trinka E, Winkler PA, Gil-Nagel A, Toledano Delgado R, Mayer T, Lutz M, Zountsas B, Garganis K, Rosenow F, Hermsen A, von Oertzen TJ, Diepgen TL, Avanzini G, on behalf of the European Epilepsy Brain Bank (EEBB) Consortium (2017) Histopathological findings in brain tissue obtained during epilepsy surgery. N Engl J Med 377:1648–1656
Krsek P, Maton B, Korman B, Pacheco-Jacome E, Jayakar P, Dunoyer C, Rey G, Morrison G, Ragheb J, Vinters HV, Resnick T, Duchowny M (2008) Different features of histopathological subtypes of pediatric focal cortical dysplasia. Ann Neurol 63:758–769
Huppertz HJ, Grimm C, Fauser S, Kassubek J, Mader I, Hochmuth A, Spreer J, Schulze-Bonhage A (2005) Enhanced visualization of blurred gray white matter junctions in focal cortical dysplasia by voxel-based 3D MRI analysis. Epilepsy Res 67:35–50
Huppertz HJ. Morphometric MRI analysis (2013) In: Urbach H (ed) MRI in Epilepsy. Springer Berlin Heidelberg, pp 73–84
Huppertz HJ, Wellmer J, Staack AM, Altenmüller DM, Urbach H, Kröll J (2008) Voxel-based 3D MRI analysis helps to detect subtle forms of subcortical band heterotopia. Epilepsia 49:772–785
Demerath T, Rubensdörfer L, Schwarzwald R, Schulze-Bonhage A, Altenmüller DM, Kaller C, Kober T, Huppertz HJ, Urbach H (2020) Morphometric MRI analysis: improved detection of focal cortical dysplasia using the MP2RAGE sequence. AJNR Am J Neuroradiol 41:1009–1014
Marques JP, Kober T, Krueger G, van der Zwaag W, Van de Moortele PF, Gruetter R (2010) MP2RAGE, a self bias-field corrected sequence for improved segmentation and T1-mapping at high field. Neuroimage 49:1271–1281
Tanner M, Gambarota G, Kober T, Krueger G, Erritzoe D, Marques JP, Newbould R (2012) Fluid and white matter suppression with the MP2RAGE sequence. J Magn Reson Imaging 35:1063–1070
David B, Kröll-Seger J, Schuch F, Wagner J, Wellmer J, Woermann F, Oehl B, Van Paesschen W, Breyer T, Becker A, Vatter H, Hattingen E, Urbach H, Weber B, Surges R, Elger CE, Huppertz HJ, Rüber T (2021) External validation of automated focal cortical dysplasia detection using morphometric analysis. Epilepsia 62:1005–1021
Wagner J, Weber B, Urbach H, Elger CE, Huppertz HJ (2011) Morphometric MRI analysis improves detection of focal cortical dysplasia type II. Brain 134:2844–2854
Wang ZI, Alexopoulos AV, Jones SE, Najm IM, Ristic A, Wong C, Prayson R, Schneider F, Kakisaka Y, Wang S, Bingaman W, Gonzalez-Martinez JA, Burgess RC (2014) Linking MRI postprocessing with magnetic source imaging in MRI-negative epilepsy. Ann Neurol 75:759–770
Wang ZI, Jones SE, Jaisani Z, Najm IM, Prayson RA, Burgess RC, Krishnan B, Ristic A, Wong CH, Bingaman W, Gonzalez-Martinez JA, Alexopoulos AV (2015) Voxel-based morphometric magnetic resonance imaging (MRI) postprocessing in MRI-negative epilepsies. Ann Neurol 77:1060–1075
El Tahry R, Santos SF, Vrielynck P, de Tourtchaninoff M, Duprez T, Vaz GR, Raftopoulos C, Choi JY, Wang ZI (2020) Additional clinical value of voxel-based morphometric MRI post-processing for MRI-negative epilepsies: a prospective study. Epileptic Disord 22:156–164
Wellmer J, Quesada C, Rothe L, Elger CE, Bien CG, Urbach H (2013) Proposal for a magnetic resonance imaging protocol for the detection of epileptogenic lesions at early outpatient stages. Epilepsia 54:1977–1987
Urbach H, Mast H, Egger K, Mader I (2015) Presurgical MR imaging in epilepsy. Clin Neuroradiol 25:151–155
Rüber T, David B, Elger CE (2018) MRI in epilepsy: clinical standard and evolution. Curr Opin Neurol 31:223–231
House PM, Lanz M, Holst B, Martens T, Stodieck S, Huppertz HJ (2013) Comparison of morphometric analysis based on T1- and T2-weighted MRI data for visualization of focal cortical dysplasia. Epilepsy Res 106:403–409
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Urbach, H., Heers, M., Altenmueller, DM. et al. “Within a minute” detection of focal cortical dysplasia. Neuroradiology 64, 715–726 (2022). https://doi.org/10.1007/s00234-021-02823-7
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DOI: https://doi.org/10.1007/s00234-021-02823-7