Fully automated detection of focal cortical dysplasia: Comparison of MPRAGE and MP2RAGE sequences

Demerath, Theo; Kaller, Christoph P.; Heers, Marcel; Staack, Anke M.; Schwarzwald, Ralf; Kober, Tobias; Reisert, Marco; Schulze‐Bonhage, Andreas; Huppertz, Hans‐Jürgen; Urbach, Horst

doi:10.1111/epi.17127

Cited by 8 publications

(6 citation statements)

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“…Most approaches formulate the problem of FCD detection as a classification task. 13,16,24,34,35,40,46,69,70,[71][72][73][74] Input data range from raw MRI data to morphometric maps or surface features. They can be one-dimensional, that is, single voxels (or vertices if the input data are surface-based), or two-or three-dimensional images.…”

Section: Classificationmentioning

confidence: 99%

“…Many works do not uniquely belong to one of these three categories and involve a mix of other processing steps. For example, several approaches use morphometric maps and other differences compared to a “normal” cohort as inputs to a classification model 13,24,71,73 . Colliot et al 83 explore segmentation with coarse localization information as additional input, which could be helpful for hypothesis refinement.…”

Section: What Is Automatic Fcd “Detection”?mentioning

confidence: 99%

“…In the two-and three-dimensional cases, an algorithm often only operates on smaller image parts, socalled "patches." The output is thus generated on the voxel level, 24,46,[71][72][73] vertex level, 13,18,35,40,70 or patch level. 16,34,69,74 Figure 2 shows examples of the outputs from Multi-centre Epilepsy Lesion Detection (MELD), 18 Morphometric Analysis Program v2018 (MAP18), 24 and deepFCD 16 models.…”

Section: Classificationmentioning

confidence: 99%

“…Its output is a value between 0 and 1, akin to the probability for the input data belonging to a particular class, as shown in Figure 3A,B. For FCD detection, the possible classes are usually either “lesional” or “nonlesional.” Most approaches formulate the problem of FCD detection as a classification task 13,16,24,34,35,40,46,69,70,71–74 . Input data range from raw MRI data to morphometric maps or surface features.…”

Section: What Is Automatic Fcd “Detection”?mentioning

confidence: 99%

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Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

et al. 2023

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Focal cortical dysplasias (FCDs) are malformations of cortical development and one of the most common pathologies causing pharmacoresistant focal epilepsy. Resective neurosurgery yields high success rates, especially if the full extent of the lesion is correctly identified and completely removed. The visual assessment of magnetic resonance imaging does not pinpoint the FCD in 30%–50% of cases, and half of all patients with FCD are not amenable to epilepsy surgery, partly because the FCD could not be sufficiently localized. Computational approaches to FCD detection are an active area of research, benefitting from advancements in computer vision. Automatic FCD detection is a significant challenge and one of the first clinical grounds where the application of artificial intelligence may translate into an advance for patients' health. The emergence of new methods from the combination of health and computer sciences creates novel challenges. Imaging data need to be organized into structured, well‐annotated datasets and combined with other clinical information, such as histopathological subtypes or neuroimaging characteristics. Algorithmic output, that is, model prediction, requires a technically correct evaluation with adequate metrics that are understandable and usable for clinicians. Publication of code and data is necessary to make research accessible and reproducible. This critical review introduces the field of automatic FCD detection, explaining underlying medical and technical concepts, highlighting its challenges and current limitations, and providing a perspective for a novel research environment.

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Section: Classificationmentioning

confidence: 99%

Section: What Is Automatic Fcd “Detection”?mentioning

confidence: 99%

Section: Classificationmentioning

confidence: 99%

Section: What Is Automatic Fcd “Detection”?mentioning

confidence: 99%

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Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

et al. 2023

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“…These parameters were initially optimized by Marques et al to obtain the highest and most uniform T 1 ‐weighted brain tissue contrast when combining the two acquired images in a complex ratio. This so‐called “UNI” contrast, free from

{\mathrm{B}}_1^{-}

reception bias, showed high potential for segmentation purposes 1,3 and major interest in pathological contexts such as epilepsy or multiple sclerosis (MS) imaging at 7 T 4–8 and 3 T, 9,10 progressively turning into a surrogate to the MPRAGE sequence for T 1 ‐weighted brain imaging 2 . Moreover, from the UNI image, a quantitative T 1 map 11 can be derived that can be useful in clinical research 12–14 …”

Section: Introductionmentioning

confidence: 99%

Pushing MP2RAGE boundaries: Ultimate time‐efficient parameterization combined with exhaustive T₁ synthetic contrasts

Bapst,

Massire,

Mauconduit

et al. 2023

Magnetic Resonance in Med

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PurposeMP2RAGE parameter optimization is redefined to allow more time‐efficient MR acquisitions, whereas the T1‐based synthetic imaging framework is used to obtain on‐demand T1‐weighted contrasts. Our aim was to validate this concept on healthy volunteers and patients with multiple sclerosis, using plug‐and‐play parallel‐transmission brain imaging at 7 T.MethodsA “time‐efficient” MP2RAGE sequence was designed with optimized parameters including TI and TR set as small as possible. Extended phase graph formalism was used to set flip‐angle values to maximize the gray–to–white‐matter contrast‐to‐noise ratio (CNR). Several synthetic contrasts (UNI, EDGE, FGATIR, FLAWSMIN, FLAWSHCO) were generated online based on the acquired T1 maps. Experimental validation was performed on 4 healthy volunteers at various spatial resolutions. Clinical applicability was evaluated on 6 patients with multiple sclerosis, scanned with both time‐efficient and conventional MP2RAGE parameterizations.ResultsThe proposed time‐efficient MP2RAGE protocols reduced acquisition time by 40%, 30%, and 19% for brain imaging at (1 mm)3, (0.80 mm)3 and (0.65 mm)3, respectively, when compared with conventional parameterizations. They also provided all synthetic contrasts and comparable contrast‐to‐noise ratio on UNI images. The flexibility in parameter selection allowed us to obtain a whole‐brain (0.45 mm)3 acquisition in 19 min 56 s. On patients with multiple sclerosis, a (0.67 mm)3 time‐efficient acquisition enhanced cortical lesion visualization compared with a conventional (0.80 mm)3 protocol, while decreasing the scan time by 15%.ConclusionThe proposed optimization, associated with T1‐based synthetic contrasts, enabled substantial decrease of the acquisition time or higher spatial resolution scans for a given time budget, while generating all typical brain contrasts derived from MP2RAGE.

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Diagnostic Accuracy of Epilepsy-dedicated MRI with Post-processing

et al. 2023

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Purpose To evaluate the diagnostic accuracy of epilepsy-dedicated 3 Tesla MRI including post-processing by correlating MRI, histopathology, and postsurgical seizure outcomes. Methods 3 Tesla-MRI including a magnetization-prepared two rapid acquisition gradient echo (MP2RAGE) sequence for post-processing using the morphometric analysis program MAP was acquired in 116 consecutive patients with drug-resistant focal epilepsy undergoing resection surgery. The MRI, histopathology reports and postsurgical seizure outcomes were recorded from the patient’s charts. Results The MRI and histopathology were concordant in 101 and discordant in 15 patients, 3 no hippocampal sclerosis/gliosis only lesions were missed on MRI and 1 of 28 focal cortical dysplasia (FCD) type II associated with a glial scar was considered a glial scar only on MRI. In another five patients, MRI was suggestive of FCD, the histopathology was uneventful but patients were seizure-free following surgery. The MRI and histopathology were concordant in 20 of 21 glioneuronal tumors, 6 cavernomas, and 7 glial scars. Histopathology was negative in 10 patients with temporal lobe epilepsy, 4 of them had anteroinferior meningoencephaloceles. Engel class IA outcome was reached in 71% of patients. Conclusion The proposed MRI protocol is highly accurate. No hippocampal sclerosis/gliosis only lesions are typically MRI negative. Small MRI positive FCD can be histopathologically missed, most likely due to sampling errors resulting from insufficient harvesting of tissue.

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Fully automated detection of focal cortical dysplasia: Comparison of MPRAGE and MP2RAGE sequences

Cited by 8 publications

References 30 publications

Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

Pushing MP2RAGE boundaries: Ultimate time‐efficient parameterization combined with exhaustive T₁ synthetic contrasts

Diagnostic Accuracy of Epilepsy-dedicated MRI with Post-processing

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Fully automated detection of focal cortical dysplasia: Comparison of MPRAGE and MP2RAGE sequences

Cited by 8 publications

References 30 publications

Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

Artificial intelligence for the detection of focal cortical dysplasia: Challenges in translating algorithms into clinical practice

Pushing MP2RAGE boundaries: Ultimate time‐efficient parameterization combined with exhaustive T1 synthetic contrasts

Diagnostic Accuracy of Epilepsy-dedicated MRI with Post-processing

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Pushing MP2RAGE boundaries: Ultimate time‐efficient parameterization combined with exhaustive T₁ synthetic contrasts