AEYE: A Deep Learning System for Video Nystagmus Detection

Overview

Journal Front Neurol

Specialty Neurology

Date 2022 Aug 29

PMID 36034311

Authors

Narayani Wagle

John Morkos

Jingyan Liu

Henry Reith

Joseph Greenstein

Kirby Gong

Indranuj Gangan

Daniil Pakhomov

Sanchit Hira

Oleg V Komogortsev

David E Newman-Toker

Raimond Winslow

David S Zee

Jorge Otero-Millan

Kemar E Green

Affiliations

Soon will be listed here.

Abstract

Background: Nystagmus identification and interpretation is challenging for non-experts who lack specific training in neuro-ophthalmology or neuro-otology. This challenge is magnified when the task is performed telemedicine. Deep learning models have not been heavily studied in video-based eye movement detection.

Methods: We developed, trained, and validated a deep-learning system (aEYE) to classify video recordings as normal or bearing at least two consecutive beats of nystagmus. The videos were retrospectively collected from a subset of the monocular (right eye) video-oculography (VOG) recording used in the Acute Video-oculography for Vertigo in Emergency Rooms for Rapid Triage (AVERT) clinical trial (#NCT02483429). Our model was derived from a preliminary dataset representing about 10% of the total AVERT videos ( = 435). The videos were trimmed into 10-sec clips sampled at 60 Hz with a resolution of 240 × 320 pixels. We then created 8 variations of the videos by altering the sampling rates (i.e., 30 Hz and 15 Hz) and image resolution (i.e., 60 × 80 pixels and 15 × 20 pixels). The dataset was labeled as "nystagmus" or "no nystagmus" by one expert provider. We then used a filtered image-based motion classification approach to develop aEYE. The model's performance at detecting nystagmus was calculated by using the area under the receiver-operating characteristic curve (AUROC), sensitivity, specificity, and accuracy.

Results: An ensemble between the ResNet-soft voting and the VGG-hard voting models had the best performing metrics. The AUROC, sensitivity, specificity, and accuracy were 0.86, 88.4, 74.2, and 82.7%, respectively. Our validated folds had an average AUROC, sensitivity, specificity, and accuracy of 0.86, 80.3, 80.9, and 80.4%, respectively. Models created from the compressed videos decreased in accuracy as image sampling rate decreased from 60 Hz to 15 Hz. There was only minimal change in the accuracy of nystagmus detection when decreasing image resolution and keeping sampling rate constant.

Conclusion: Deep learning is useful in detecting nystagmus in 60 Hz video recordings as well as videos with lower image resolutions and sampling rates, making it a potentially useful tool to aid future automated eye-movement enabled neurologic diagnosis.

Citing Articles

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Sakazaki H, Noda M, Dobashi Y, Kuroda T, Tsunoda R, Fushiki H JMIR Form Res. 2025; 9:e70015.

PMID: 40014039 PMC: 11884307. DOI: 10.2196/70015.

Feasibility of video-based real-time nystagmus tracking: a lightweight deep learning model approach using ocular object segmentation.

Cho C, Park S, Ma S, Lee H, Lim E, Hong S Front Neurol. 2024; 15:1342108.

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Smartphone-Assisted Medical Care for Vestibular Dysfunction as a Telehealth Strategy for Digital Therapy Beyond COVID-19: Scoping Review.

Noda M, Kuroda T, Nomura A, Ito M, Yoshizaki T, Fushiki H JMIR Mhealth Uhealth. 2023; 11:e48638.

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Capturing nystagmus during vertigo attacks using a smartphone: adherence, characteristics, pearls and pitfalls.

Melliti A, van de Berg M, van de Berg R J Neurol. 2023; 270(12):6044-6056.

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Neurological update: neuro-otology 2023.

Halmagyi G, Akdal G, Welgampola M, Wang C J Neurol. 2023; 270(12):6170-6192.

PMID: 37592138 PMC: 10632253. DOI: 10.1007/s00415-023-11922-9.

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