Deep active learning for Interictal Ictal Injury Continuum EEG patterns

Wendong Ge; Jin Jing; Sungtae An; Aline Herlopian; Marcus Ng; Aaron F. Struck; Brian Appavu; Emily L. Johnson; Gamaleldin Osman; Hiba A. Haider; Ioannis Karakis; Jennifer A. Kim; Jonathan J. Halford; Monica B. Dhakar; Rani A. Sarkis; Christa B. Swisher; Sarah Schmitt; Jong Woo Lee; Mohammad Tabaeizadeh; Andres Rodriguez; Nicolas Gaspard; Emily Gilmore; Susan T. Herman; Peter W. Kaplan; Jay Pathmanathan; Shenda Hong; Eric S. Rosenthal; Sahar Zafar; Jimeng Sun; M. Brandon Westover

doi:10.1016/j.jneumeth.2020.108966

Deep active learning for Interictal Ictal Injury Continuum EEG patterns

Wendong Ge, Jin Jing, Sungtae An, Aline Herlopian, Marcus Ng, Aaron F. Struck, Brian Appavu, Emily L. Johnson, Gamaleldin Osman, Hiba A. Haider, Ioannis Karakis, Jennifer A. Kim, Jonathan J. Halford, Monica B. Dhakar, Rani A. Sarkis, Christa B. Swisher, Sarah Schmitt, Jong Woo Lee, Mohammad Tabaeizadeh, Andres RodriguezNicolas Gaspard, Emily Gilmore, Susan T. Herman, Peter W. Kaplan, Jay Pathmanathan, Shenda Hong, Eric S. Rosenthal, Sahar Zafar, Jimeng Sun, M. Brandon Westover

School of Medicine

Research output: Contribution to journal › Article › peer-review

Abstract

Objectives: Seizures and seizure-like electroencephalography (EEG) patterns, collectively referred to as “ictal interictal injury continuum” (IIIC) patterns, are commonly encountered in critically ill patients. Automated detection is important for patient care and to enable research. However, training accurate detectors requires a large labeled dataset. Active Learning (AL) may help select informative examples to label, but the optimal AL approach remains unclear. Methods: We assembled >200,000 h of EEG from 1,454 hospitalized patients. From these, we collected 9,808 labeled and 120,000 unlabeled 10-second EEG segments. Labels included 6 IIIC patterns. In each AL iteration, a Dense-Net Convolutional Neural Network (CNN) learned vector representations for EEG segments using available labels, which were used to create a 2D embedding map. Nearest-neighbor label spreading within the embedding map was used to create additional pseudo-labeled data. A second Dense-Net was trained using real- and pseudo-labels. We evaluated several strategies for selecting candidate points for experts to label next. Finally, we compared two methods for class balancing within queries: standard balanced-based querying (SBBQ), and high confidence spread-based balanced querying (HCSBBQ). Results: Our results show: 1) Label spreading increased convergence speed for AL. 2) All query criteria produced similar results to random sampling. 3) HCSBBQ query balancing performed best. Using label spreading and HCSBBQ query balancing, we were able to train models approaching expert-level performance across all pattern categories after obtaining ∼7000 expert labels. Conclusion: Our results provide guidance regarding the use of AL to efficiently label large EEG datasets in critically ill patients.

Original language	English (US)
Article number	108966
Journal	Journal of Neuroscience Methods
Volume	351
DOIs	https://doi.org/10.1016/j.jneumeth.2020.108966
State	Published - Mar 1 2021

Keywords

Active learning
Convolutional neural network
Electroencephalography(EEG)
Embedding map
Ictal Interictal Injury Continuum
Machine learning
Seizure

ASJC Scopus subject areas

General Neuroscience

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10.1016/j.jneumeth.2020.108966

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Ge, W., Jing, J., An, S., Herlopian, A., Ng, M., Struck, A. F., Appavu, B., Johnson, E. L., Osman, G., Haider, H. A., Karakis, I., Kim, J. A., Halford, J. J., Dhakar, M. B., Sarkis, R. A., Swisher, C. B., Schmitt, S., Lee, J. W., Tabaeizadeh, M., ... Westover, M. B. (2021). Deep active learning for Interictal Ictal Injury Continuum EEG patterns. Journal of Neuroscience Methods, 351, Article 108966. https://doi.org/10.1016/j.jneumeth.2020.108966

Ge, W, Jing, J, An, S, Herlopian, A, Ng, M, Struck, AF, Appavu, B, Johnson, EL, Osman, G, Haider, HA, Karakis, I, Kim, JA, Halford, JJ, Dhakar, MB, Sarkis, RA, Swisher, CB, Schmitt, S, Lee, JW, Tabaeizadeh, M, Rodriguez, A, Gaspard, N, Gilmore, E, Herman, ST, Kaplan, PW, Pathmanathan, J, Hong, S, Rosenthal, ES, Zafar, S, Sun, J & Westover, MB 2021, 'Deep active learning for Interictal Ictal Injury Continuum EEG patterns', Journal of Neuroscience Methods, vol. 351, 108966. https://doi.org/10.1016/j.jneumeth.2020.108966

@article{3e2e4474aca246069ac9e848dcf5d90e,

title = "Deep active learning for Interictal Ictal Injury Continuum EEG patterns",

abstract = "Objectives: Seizures and seizure-like electroencephalography (EEG) patterns, collectively referred to as “ictal interictal injury continuum” (IIIC) patterns, are commonly encountered in critically ill patients. Automated detection is important for patient care and to enable research. However, training accurate detectors requires a large labeled dataset. Active Learning (AL) may help select informative examples to label, but the optimal AL approach remains unclear. Methods: We assembled >200,000 h of EEG from 1,454 hospitalized patients. From these, we collected 9,808 labeled and 120,000 unlabeled 10-second EEG segments. Labels included 6 IIIC patterns. In each AL iteration, a Dense-Net Convolutional Neural Network (CNN) learned vector representations for EEG segments using available labels, which were used to create a 2D embedding map. Nearest-neighbor label spreading within the embedding map was used to create additional pseudo-labeled data. A second Dense-Net was trained using real- and pseudo-labels. We evaluated several strategies for selecting candidate points for experts to label next. Finally, we compared two methods for class balancing within queries: standard balanced-based querying (SBBQ), and high confidence spread-based balanced querying (HCSBBQ). Results: Our results show: 1) Label spreading increased convergence speed for AL. 2) All query criteria produced similar results to random sampling. 3) HCSBBQ query balancing performed best. Using label spreading and HCSBBQ query balancing, we were able to train models approaching expert-level performance across all pattern categories after obtaining ∼7000 expert labels. Conclusion: Our results provide guidance regarding the use of AL to efficiently label large EEG datasets in critically ill patients.",

keywords = "Active learning, Convolutional neural network, Electroencephalography(EEG), Embedding map, Ictal Interictal Injury Continuum, Machine learning, Seizure",

author = "Wendong Ge and Jin Jing and Sungtae An and Aline Herlopian and Marcus Ng and Struck, {Aaron F.} and Brian Appavu and Johnson, {Emily L.} and Gamaleldin Osman and Haider, {Hiba A.} and Ioannis Karakis and Kim, {Jennifer A.} and Halford, {Jonathan J.} and Dhakar, {Monica B.} and Sarkis, {Rani A.} and Swisher, {Christa B.} and Sarah Schmitt and Lee, {Jong Woo} and Mohammad Tabaeizadeh and Andres Rodriguez and Nicolas Gaspard and Emily Gilmore and Herman, {Susan T.} and Kaplan, {Peter W.} and Jay Pathmanathan and Shenda Hong and Rosenthal, {Eric S.} and Sahar Zafar and Jimeng Sun and Westover, {M. Brandon}",

note = "Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

year = "2021",

month = mar,

day = "1",

doi = "10.1016/j.jneumeth.2020.108966",

language = "English (US)",

volume = "351",

journal = "Journal of Neuroscience Methods",

issn = "0165-0270",

publisher = "Elsevier",

}

TY - JOUR

T1 - Deep active learning for Interictal Ictal Injury Continuum EEG patterns

AU - Ge, Wendong

AU - Jing, Jin

AU - An, Sungtae

AU - Herlopian, Aline

AU - Ng, Marcus

AU - Struck, Aaron F.

AU - Appavu, Brian

AU - Johnson, Emily L.

AU - Osman, Gamaleldin

AU - Haider, Hiba A.

AU - Karakis, Ioannis

AU - Kim, Jennifer A.

AU - Halford, Jonathan J.

AU - Dhakar, Monica B.

AU - Sarkis, Rani A.

AU - Swisher, Christa B.

AU - Schmitt, Sarah

AU - Lee, Jong Woo

AU - Tabaeizadeh, Mohammad

AU - Rodriguez, Andres

AU - Gaspard, Nicolas

AU - Gilmore, Emily

AU - Herman, Susan T.

AU - Kaplan, Peter W.

AU - Pathmanathan, Jay

AU - Hong, Shenda

AU - Rosenthal, Eric S.

AU - Zafar, Sahar

AU - Sun, Jimeng

AU - Westover, M. Brandon

PY - 2021/3/1

Y1 - 2021/3/1

N2 - Objectives: Seizures and seizure-like electroencephalography (EEG) patterns, collectively referred to as “ictal interictal injury continuum” (IIIC) patterns, are commonly encountered in critically ill patients. Automated detection is important for patient care and to enable research. However, training accurate detectors requires a large labeled dataset. Active Learning (AL) may help select informative examples to label, but the optimal AL approach remains unclear. Methods: We assembled >200,000 h of EEG from 1,454 hospitalized patients. From these, we collected 9,808 labeled and 120,000 unlabeled 10-second EEG segments. Labels included 6 IIIC patterns. In each AL iteration, a Dense-Net Convolutional Neural Network (CNN) learned vector representations for EEG segments using available labels, which were used to create a 2D embedding map. Nearest-neighbor label spreading within the embedding map was used to create additional pseudo-labeled data. A second Dense-Net was trained using real- and pseudo-labels. We evaluated several strategies for selecting candidate points for experts to label next. Finally, we compared two methods for class balancing within queries: standard balanced-based querying (SBBQ), and high confidence spread-based balanced querying (HCSBBQ). Results: Our results show: 1) Label spreading increased convergence speed for AL. 2) All query criteria produced similar results to random sampling. 3) HCSBBQ query balancing performed best. Using label spreading and HCSBBQ query balancing, we were able to train models approaching expert-level performance across all pattern categories after obtaining ∼7000 expert labels. Conclusion: Our results provide guidance regarding the use of AL to efficiently label large EEG datasets in critically ill patients.

AB - Objectives: Seizures and seizure-like electroencephalography (EEG) patterns, collectively referred to as “ictal interictal injury continuum” (IIIC) patterns, are commonly encountered in critically ill patients. Automated detection is important for patient care and to enable research. However, training accurate detectors requires a large labeled dataset. Active Learning (AL) may help select informative examples to label, but the optimal AL approach remains unclear. Methods: We assembled >200,000 h of EEG from 1,454 hospitalized patients. From these, we collected 9,808 labeled and 120,000 unlabeled 10-second EEG segments. Labels included 6 IIIC patterns. In each AL iteration, a Dense-Net Convolutional Neural Network (CNN) learned vector representations for EEG segments using available labels, which were used to create a 2D embedding map. Nearest-neighbor label spreading within the embedding map was used to create additional pseudo-labeled data. A second Dense-Net was trained using real- and pseudo-labels. We evaluated several strategies for selecting candidate points for experts to label next. Finally, we compared two methods for class balancing within queries: standard balanced-based querying (SBBQ), and high confidence spread-based balanced querying (HCSBBQ). Results: Our results show: 1) Label spreading increased convergence speed for AL. 2) All query criteria produced similar results to random sampling. 3) HCSBBQ query balancing performed best. Using label spreading and HCSBBQ query balancing, we were able to train models approaching expert-level performance across all pattern categories after obtaining ∼7000 expert labels. Conclusion: Our results provide guidance regarding the use of AL to efficiently label large EEG datasets in critically ill patients.

KW - Active learning

KW - Convolutional neural network

KW - Electroencephalography(EEG)

KW - Embedding map

KW - Ictal Interictal Injury Continuum

KW - Machine learning

KW - Seizure

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DO - 10.1016/j.jneumeth.2020.108966

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JO - Journal of Neuroscience Methods

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M1 - 108966

ER -

Deep active learning for Interictal Ictal Injury Continuum EEG patterns

Abstract

Keywords

ASJC Scopus subject areas

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