Computer-Aided Diagnosis and Localization of Lateralized Temporal Lobe Epilepsy Using Interictal FDG-PET

Kerr, Wesley T.; Nguyen, Stefan; Cho, Andrew Y.; Lau, Edward; Silverman, Daniel; Douglas, Pamela K.; Reddy, Navya M.; Anderson, Ariana; Bramen, Jennifer; Salamon, Noriko; Stern, John M.; Cohen, Mark S.

doi:10.3389/fneur.2013.00031

Cited by 41 publications

(49 citation statements)

References 104 publications

(142 reference statements)

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“…The ample evidences of advanced research using multimodal combinational non-invasive neuroimaging techniques like MRI, MRS, f-MRI, FDG-PET, SPECT, and MEG have revealed that most of the cases of TLE patients are accompanied by pathological changes in brain structure and function network, including cortical and subcortical (hippocampus and parahippocampus) structures [12][13][14]. Such multimodal combinational imaging (structural and functional) approaches are being suggested to detect the laterization of TLE with ictal and interictal onset in pre-surgical diagnostic purpose [15][16][17][18][19][20]. Regardless, epilepsy occasionally is a clinical problem as regards medical management and the problem becomes acute in developing countries as there is often delay in clinical diagnosis due to the limited resources, large patient load, and health care manpower constraints [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

et al. 2015

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Section: Introductionmentioning

confidence: 99%

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

et al. 2015

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“…Furthermore, as we only utilized T1 MRI data and did not incorporate signal variation from T2/FLAIR scans (Coan et al, 2014, Cantor-Rivera et al, 2015 or alterations found in PET (Kerr et al, 2013) or DTI data (Cantor-Rivera et al, 2015), it is clear that there is still much room for improving classifier performance. Thus, in the future, an even more comprehensive model that identifies subgroups, incorporates other imaging modalities in addition to clinical and neuropsychological data, would likely be superior in regards to both diagnosis and predicting treatment outcomes, thus achieving clinical utility.…”

Section: Discussionmentioning

confidence: 99%

Machine learning classification of mesial temporal sclerosis in epilepsy patients

Rudie¹,

Colby²,

Salamon

2015

Epilepsy Research

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a b s t r a c tBackground and purpose: Novel approaches applying machine-learning methods to neuroimaging data seek to develop individualized measures that will aid in the diagnosis and treatment of brain-based disorders such as temporal lobe epilepsy (TLE). Using a large cohort of epilepsy patients with and without mesial temporal sclerosis (MTS), we sought to automatically classify MTS using measures of cortical morphology, and to further relate classification probabilities to measures of disease burden. Materials and methods: Our sample consisted of high-resolution T1 structural scans of 169 adults with epilepsy collected across five different 1.5 T and four different 3 T scanners at UCLA. We applied a multiple support vector machine recursive feature elimination algorithm to morphological measures generated from FreeSurfer's automated segmentation and parcellation in order to classify Epilepsy patients with MTS (n = 85) from those without MTS (N = 84). Results: In addition to hippocampal volume, we found that alterations in cortical thickness, surface area, volume and curvature in inferior frontal and anterior and inferior temporal regions contributed to a classification accuracy of up to 81% (p = 1.3 × 10 −17 ) in identifying MTS. We also found that MTS classification probabilities were associated with a longer duration of disease for epilepsy patients both with and without MTS. Conclusions: In addition to implicating extra-hippocampal involvement of MTS, these findings shed further light on the pathogenesis of TLE and may ultimately assist in the development of automated tools that incorporate multiple neuroimaging measures to assist clinicians in detecting more subtle cases of TLE and MTS.

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“…These include tumor imaging (1), neurologic diseases such as epilepsy (2) and Alzheimer disease (3)(4)(5), and psychiatric disorders such as major depression (6). Hence, PET using the radiolabeled glucose analog 18 F-FDG offers an excellent opportunity for imaging and quantification of glucose metabolism.…”

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confidence: 99%

Quantification of Task-Specific Glucose Metabolism with Constant Infusion of¹⁸F-FDG

et al. 2016

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The investigation of cerebral metabolic rate of glucose (CMRGlu) at baseline and during specific tasks previously required separate scans with the drawback of high intrasubject variability. We aimed to validate a novel approach to assessing baseline glucose metabolism and task-specific changes in a single measurement with a constant infusion of 18 F-FDG. Methods: Fifteen healthy subjects underwent two PET measurements with arterial blood sampling. As a reference, baseline CMRGlu was quantified from a 60-min scan after 18 F-FDG bolus application using the Patlak plot (eyes closed). For the other scan, a constant radioligand infusion was applied for 95 min, during which the subjects opened their eyes at 10-20 min and 60-70 min and tapped their right thumb to their fingers at 35-45 min and 85-95 min. The constant-infusion scan was quantified in two steps. First, the general linear model was used to fit regional time-activity curves with regressors for baseline metabolism, task-specific changes for the eyes-open and finger-tapping conditions, and movement parameters. Second, the Patlak plot was used for quantification of CMRGlu. Multiplication of the baseline regressor by β-values from the general linear model yielded regionally specific time-activity curves for baseline metabolism. Further, taskspecific changes in metabolism are directly proportional to changes in the slope of the time-activity curve and hence to changes in CMRGlu. Results: Baseline CMRGlu from the constant-infusion scan matched that from the bolus application (test-retest variability, 1.1% ± 24.7%), which was not the case for a previously suggested approach (variability, −39.9% ± 25.2%, P , 0.001). Task-specific CMRGlu increased in the primary visual and motor cortices for eyes open and finger tapping, respectively (P , 0.05, familywise errorcorrected), with absolute changes of up to 2.1 μmol/100 g/min and 6.3% relative to baseline. For eyes open, a decreased CMRGlu was observed in default-mode regions (P , 0.05, familywise errorcorrected). CMRGlu quantified with venous blood samples (n 5 6) showed excellent agreement with results obtained from arterial samples (r . 0.99). Conclusion: Baseline glucose metabolism and taskspecific changes can be quantified in a single measurement with constant infusion of 18 F-FDG and venous blood sampling. The high sensitivity and regional specificity of the approach offer novel possibilities for functional and multimodal brain imaging.

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Computer-Aided Diagnosis and Localization of Lateralized Temporal Lobe Epilepsy Using Interictal FDG-PET

Cited by 41 publications

References 104 publications

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

Machine learning classification of mesial temporal sclerosis in epilepsy patients

Quantification of Task-Specific Glucose Metabolism with Constant Infusion of¹⁸F-FDG

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Computer-Aided Diagnosis and Localization of Lateralized Temporal Lobe Epilepsy Using Interictal FDG-PET

Cited by 41 publications

References 104 publications

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

MRI characterization of temporal lobe epilepsy using rapidly measurable spatial indices with hemisphere asymmetries and gender features

Machine learning classification of mesial temporal sclerosis in epilepsy patients

Quantification of Task-Specific Glucose Metabolism with Constant Infusion of18F-FDG

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Quantification of Task-Specific Glucose Metabolism with Constant Infusion of¹⁸F-FDG