Development and Validation of Forecasting Next Reported Seizure Using e‐Diaries

Goldenholz, Daniel M.; Goldenholz, Shira R.; Romero, Juan; Moss, Robert; Sun, Haoqi; Westover, M. Brandon

doi:10.1002/ana.25812

Cited by 42 publications

(62 citation statements)

References 31 publications

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“…In contrast, forecasts based on “black‐box” machine learning models cannot be projected beyond the range of the available data, and therefore are less flexible for making long‐range estimates of seizure likelihood. The increasing availability of electronic diary data has recently advanced machine learning techniques for diary‐based seizure forecasting 30,44,45 . However, it is important to bear in mind that self‐reported diaries provide a noisy, undersampled representation of the underlying true seizure likelihood.…”

Section: Discussionmentioning

confidence: 99%

“…We have shown that multiday seizure cycles can be measured noninvasively using self‐reported seizure times; and, for most people, seizure cycles measured from self‐reported events correlated with their cycles of electrographic seizures 29 . There is now growing evidence that seizure diaries can be used to generate accurate, personalized forecasts of future seizure likelihood 29–31 . Diary‐based forecasts are compelling due to their widespread availability, ease of use, and low‐cost implementation (typically available via free digital platforms or mobile apps) 32 .…”

Section: Introductionmentioning

confidence: 99%

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Cycles of self‐reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Karoly

Eden²,

Nurse

et al. 2021

Epilepsia

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Objective Video‐electroencephalography (vEEG) is an important component of epilepsy diagnosis and management. Nevertheless, inpatient vEEG monitoring fails to capture seizures in up to one third of patients. We hypothesized that personalized seizure forecasts could be used to optimize the timing of vEEG. Methods We used a database of ambulatory vEEG studies to select a cohort with linked electronic seizure diaries of more than 20 reported seizures over at least 8 weeks. The total cohort included 48 participants. Diary seizure times were used to detect individuals' multiday seizure cycles and estimate times of high seizure risk. We compared whether estimated seizure risk was significantly different between conclusive and inconclusive vEEGs, and between vEEG with and without recorded epileptic activity. vEEGs were conducted prior to self‐reported seizures; hence, the study aimed to provide a retrospective proof of concept that cycles of seizure risk were correlated with vEEG outcomes. Results Estimated seizure risk was significantly higher for conclusive vEEGs and vEEGs with epileptic activity. Across all cycle strengths, the average time in high risk during vEEG was 29.1% compared with 14% for the conclusive/inconclusive groups and 32% compared to 18% for the epileptic activity/no epileptic activity groups. On average, 62.5% of the cohort showed increased time in high risk during their previous vEEG when epileptic activity was recorded (compared to 28% of the cohort where epileptic activity was not recorded). For conclusive vEEGs, 50% of the cohort had increased time in high risk, compared to 21.5% for inconclusive vEEGs. Significance Although retrospective, this study provides a proof of principle that scheduling monitoring times based on personalized seizure risk forecasts can improve the yield of vEEG. Forecasts can be developed at low cost from mobile seizure diaries. A simple scheduling tool to improve diagnostic outcomes may reduce cost and risks associated with delayed or missed diagnosis in epilepsy.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cycles of self‐reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Karoly

Eden²,

Nurse

et al. 2021

Epilepsia

View full text Add to dashboard Cite

show abstract

“…In contrast, forecasts based on “black-box” machine learning models cannot be projected beyond the range of the available data, so are less flexible for making long-range estimates of seizure likelihood. The increasing availability of electronic diary data has recently advanced machine learning techniques for diary-based seizure forecasting 30,44,45 .…”

Section: Discussionmentioning

confidence: 99%

Cycles of self-reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Karoly

Eden²,

Nurse

et al. 2020

Preprint

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Objective: Video-electroencephalography (vEEG) is an important component of epilepsy diagnosis and management. Nevertheless, inpatient vEEG monitoring fails to capture seizures in up to one third of patients during diagnostic and pre-surgical monitoring. We hypothesized that personalized seizure forecasts could be used to optimize the timing of vEEG and improve diagnostic yield. Methods: We used a database of ambulatory vEEG studies to select a cohort with linked electronic seizure diaries of more than 20 reported seizures over at least 8 weeks. The total cohort included 48 participants. Diary seizure times were used to detect individuals' multi-day cycles and estimate times of high seizure risk. We then compared whether estimated seizure risk was significantly different between diagnostic and non-diagnostic vEEGs, and between vEEG with and without recorded epileptic activity. Results: Estimated seizure risk was significantly higher for diagnostic vEEGs and vEEGs with epileptic activity. Across all cycle strengths, the average time in high risk during vEEG was 29.1% compared with 14% for the diagnostic/non-diagnostic groups and 32% compared to 18% for the epileptic activity/no epileptic activity groups. On average, 62.5% of the cohort showed increased time in high risk during vEEG when epileptic activity was recorded (compared to 28% of the cohort where epileptic activity was not recorded). For diagnostic vEEGs, 50% of the cohort had increased time in high risk, compared to 21.5% for non-diagnostic vEEGs. Significance: This study provides a proof of principle that scheduling monitoring times based on personalized seizure risk forecasts can improve the yield of vEEG. Importantly, forecasts can be developed at low cost from mobile seizure diaries. A simple scheduling tool to improve diagnostic outcomes has the potential to reduce the significant cost and risks associated with delayed or missed diagnosis in epilepsy.

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“…Jin et al developed a neural network classifier with magnetic resonance imaging data to identify solitary focal cortical dysplasias (FCDs) in a dataset of 61 patients with type II FCDs as well as 120 controls from three different epilepsy centers and achieved a sensitivity of 73.7%, specificity of 90.0%, and area under the curve (AUC) for the receiver operating characteristic analysis of .75 52 . Goldenholz et al proposed an approach with recurrent networks and multilayer perceptron to forecast the probability of future seizures; the evaluation results achieved an AUC of .86 on the testing set of 1613 patients 53 . Abbasi and Goldenholz provided a detailed review of machine learning applications with different domains in epilepsy, such as automated seizure detection, analysis of imaging and clinical data, epilepsy localization, and prediction of medical and surgical outcomes 40 …”

Section: Big Data Building Blocks For Cdsssmentioning

confidence: 99%

“…52 Goldenholz et al proposed an approach with recurrent networks and multilayer perceptron to forecast the probability of future seizures; the evaluation results achieved an AUC of .86 on the testing set of 1613 patients. 53 Abbasi and Goldenholz provided a detailed review of machine learning applications with different domains in…”

Section: Machine Learningmentioning

confidence: 99%

Can Big Data guide prognosis and clinical decisions in epilepsy?

Cui

Zhang

et al. 2021

Epilepsia

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Big Data is no longer a novel concept in health care. Its promise of positive impact is not only undiminished, but daily enhanced by seemingly endless possibilities. Epilepsy is a disorder with wide heterogeneity in both clinical and research domains, and thus lends itself to Big Data concepts and techniques. It is therefore inevitable that Big Data will enable multimodal research, integrating various aspects of “‐omics” domains, such as phenome, genome, microbiome, metabolome, and proteome. This scope and granularity have the potential to change our understanding of prognosis and mortality in epilepsy. The scale of new discovery is unprecedented due to the possibilities promised by advances in machine learning, in particular deep learning. The subsequent possibilities of personalized patient care through clinical decision support systems that are evidence‐based, adaptive, and iterative seem to be within reach. A major objective is not only to inform decision‐making, but also to reduce uncertainty in outcomes. Although the adoption of electronic health record (EHR) systems is near universal in the United States, for example, advanced clinical decision support in or ancillary to EHRs remains sporadic. In this review, we discuss the role of Big Data in the development of clinical decision support systems for epilepsy care, prognostication, and discovery.

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Development and Validation of Forecasting Next Reported Seizure Using e‐Diaries

Cited by 42 publications

References 31 publications

Cycles of self‐reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Cycles of self‐reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Cycles of self-reported seizure likelihood correspond to yield of diagnostic epilepsy monitoring

Can Big Data guide prognosis and clinical decisions in epilepsy?

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