Alexander M Chan1, Felice T Sun, Erem H Boto, Brett M Wingeier. 1. Harvard-MIT Division of Health Sciences and Technology, Medical Engineering and Medical Physics Program, 77 Massachusetts Avenue, E25-519, Cambridge, MA 02139, USA.
Abstract
OBJECTIVE: A novel algorithm for automated seizure onset detection is presented. The method allows for precise identification of electrographic seizure onset times within large databases of electrographic data. METHODS: The patient-specific algorithm extracts salient spectral and temporal features in five frequency bands within a sliding window of an electrographic recording. Feature windows are classified as containing or not containing a seizure onset via support vector machines. A clustering and regression analysis is utilized to accurately localize seizure onsets in time. User-adjustable parameters allow for tuning of detection sensitivity, false positive rate, and latency. The method was tested on intracranial electrographic data recorded from six patients with a total of 1792 recorded seizure onsets from 8246 total electrographic recordings. RESULTS: Testing of algorithm performance via cross-validation resulted in sensitivities between 80% and 98%, false positive rates from 0.002 to 0.046 per minute (0.12-2.8 per hour), and median detection time within 100ms of the electrographic onset for all patients. In five of the six patients, more than 90% of all detected onsets were less than 3s from the electrographic onset. CONCLUSIONS: The detection system was able to detect seizure onset times in a temporally unbiased fashion with low latency while maintaining reasonable sensitivities and false positive rates. The regression algorithm for temporal localization of onsets confers a considerable benefit in terms of detection latency. SIGNIFICANCE: With the use of our algorithm, large databases of electrographic data can be rapidly processed and seizure onset times accurately marked, facilitating research and analyses of peri-onset events that require precise seizure onset alignment.
OBJECTIVE: A novel algorithm for automated seizure onset detection is presented. The method allows for precise identification of electrographic seizure onset times within large databases of electrographic data. METHODS: The patient-specific algorithm extracts salient spectral and temporal features in five frequency bands within a sliding window of an electrographic recording. Feature windows are classified as containing or not containing a seizure onset via support vector machines. A clustering and regression analysis is utilized to accurately localize seizure onsets in time. User-adjustable parameters allow for tuning of detection sensitivity, false positive rate, and latency. The method was tested on intracranial electrographic data recorded from six patients with a total of 1792 recorded seizure onsets from 8246 total electrographic recordings. RESULTS: Testing of algorithm performance via cross-validation resulted in sensitivities between 80% and 98%, false positive rates from 0.002 to 0.046 per minute (0.12-2.8 per hour), and median detection time within 100ms of the electrographic onset for all patients. In five of the six patients, more than 90% of all detected onsets were less than 3s from the electrographic onset. CONCLUSIONS: The detection system was able to detect seizure onset times in a temporally unbiased fashion with low latency while maintaining reasonable sensitivities and false positive rates. The regression algorithm for temporal localization of onsets confers a considerable benefit in terms of detection latency. SIGNIFICANCE: With the use of our algorithm, large databases of electrographic data can be rapidly processed and seizure onset times accurately marked, facilitating research and analyses of peri-onset events that require precise seizure onset alignment.
Authors: Evan M Dastin-van Rijn; Nicole R Provenza; Jonathan S Calvert; Ro'ee Gilron; Anusha B Allawala; Radu Darie; Sohail Syed; Evan Matteson; Gregory S Vogt; Michelle Avendano-Ortega; Ana C Vasquez; Nithya Ramakrishnan; Denise N Oswalt; Kelly R Bijanki; Robert Wilt; Philip A Starr; Sameer A Sheth; Wayne K Goodman; Matthew T Harrison; David A Borton Journal: Cell Rep Methods Date: 2021-06-01
Authors: Sabato Santaniello; Samuel P Burns; Alexandra J Golby; Jedediah M Singer; William S Anderson; Sridevi V Sarma Journal: Epilepsy Behav Date: 2011-12 Impact factor: 2.937