TY - JOUR
T1 - Application of a Deep Learning System to Detect Papilledema on Nonmydriatic Ocular Fundus Photographs in an Emergency Department
AU - Biousse, Valérie
AU - Najjar, Raymond P.
AU - Tang, Zhiqun
AU - Lin, Mung Yan
AU - Wright, David W.
AU - Keadey, Matthew T.
AU - Wong, Tien Y.
AU - Bruce, Beau B.
AU - BONSAI Study Group
AU - Milea, Dan
AU - Newman, Nancy J.
AU - Fraser, Clare L.
AU - Micieli, Jonathan A.
AU - Costello, Fiona
AU - Bénard-Séguin, Étienne
AU - Yang, Hui
AU - Chan, Carmen Kar Mun
AU - Cheung, Carol Y.
AU - Chan, Noel C. Y.
AU - Hamann, Steffen
AU - Gohier, Philippe
AU - Vautier, Anaïs
AU - Rougier, Marie-B. nédicte
AU - Chiquet, Christophe
AU - Vignal-Clermont, Catherine
AU - Hage, Rabih
AU - Khanna, Raoul Kanav
AU - Tran, Thi Ha Chau
AU - Lagrèze, Wolf Alexander
AU - Jonas, Jost B.
AU - Ambika, Selvakumar
AU - Fard, Masoud Aghsaei
AU - la Morgia, Chiara
AU - Carbonelli, Michele
AU - Barboni, Piero
AU - Carelli, Valerio
AU - Romagnoli, Martina
AU - Amore, Giulia
AU - Nakamura, Makoto
AU - Fumio, Takano
AU - Petzold, Axel
AU - Wenniger lj, Maillette de Buy
AU - Kho, Richard
AU - Fonseca, Pedro L.
AU - Bikbov, Mukharram M.
AU - Najjar, Raymond P.
AU - Ting, Daniel
AU - Loo, Jing Liang
AU - Tow, Sharon
AU - Singhal, Shweta
AU - Vasseneix, Caroline
AU - Maillette de Buij Wenniger, L.J.
N1 - Publisher Copyright: © 2023 Elsevier Inc.
PY - 2024/5/1
Y1 - 2024/5/1
N2 - Purpose: The Fundus photography vs Ophthalmoscopy Trial Outcomes in the Emergency Department (FOTO-ED) studies showed that ED providers poorly recognized funduscopic findings in patients in the ED. We tested a modified version of the Brain and Optic Nerve Study Artificial Intelligence (BONSAI) deep learning system on nonmydriatic fundus photographs from the FOTO-ED studies to determine if the deep learning system could have improved the detection of papilledema had it been available to ED providers as a real-time diagnostic aid. Design: Retrospective secondary analysis of a cohort of patients included in the FOTO-ED studies. Methods: The testing data set included 1608 photographs obtained from 828 patients in the FOTO-ED studies. Photographs were reclassified according to the optic disc classification system used by the deep learning system (“normal optic discs,” “papilledema,” and “other optic disc abnormalities”). The system's performance was evaluated by calculating the area under the receiver operating characteristic curve (AUC), sensitivity, and specificity using a 1-vs-rest strategy, with reference to expert neuro-ophthalmologists. Results: The BONSAI deep learning system successfully distinguished normal from abnormal optic discs (AUC 0.92 [95% confidence interval {CI} 0.90-0.93]; sensitivity 75.6% [73.7%-77.5%] and specificity 89.6% [86.3%-92.8%]), and papilledema from normal and others (AUC 0.97 [0.95-0.99]; sensitivity 84.0% [75.0%-92.6%] and specificity 98.9% [98.5%-99.4%]). Six patients with missed papilledema in 1 eye were correctly identified by the deep learning system as having papilledema in the other eye. Conclusions: The BONSAI deep learning system was able to reliably identify papilledema and normal optic discs on nonmydriatic photographs obtained in the FOTO-ED studies. Our deep learning system has excellent potential as a diagnostic aid in EDs and non-ophthalmology clinics equipped with nonmydriatic fundus cameras.
AB - Purpose: The Fundus photography vs Ophthalmoscopy Trial Outcomes in the Emergency Department (FOTO-ED) studies showed that ED providers poorly recognized funduscopic findings in patients in the ED. We tested a modified version of the Brain and Optic Nerve Study Artificial Intelligence (BONSAI) deep learning system on nonmydriatic fundus photographs from the FOTO-ED studies to determine if the deep learning system could have improved the detection of papilledema had it been available to ED providers as a real-time diagnostic aid. Design: Retrospective secondary analysis of a cohort of patients included in the FOTO-ED studies. Methods: The testing data set included 1608 photographs obtained from 828 patients in the FOTO-ED studies. Photographs were reclassified according to the optic disc classification system used by the deep learning system (“normal optic discs,” “papilledema,” and “other optic disc abnormalities”). The system's performance was evaluated by calculating the area under the receiver operating characteristic curve (AUC), sensitivity, and specificity using a 1-vs-rest strategy, with reference to expert neuro-ophthalmologists. Results: The BONSAI deep learning system successfully distinguished normal from abnormal optic discs (AUC 0.92 [95% confidence interval {CI} 0.90-0.93]; sensitivity 75.6% [73.7%-77.5%] and specificity 89.6% [86.3%-92.8%]), and papilledema from normal and others (AUC 0.97 [0.95-0.99]; sensitivity 84.0% [75.0%-92.6%] and specificity 98.9% [98.5%-99.4%]). Six patients with missed papilledema in 1 eye were correctly identified by the deep learning system as having papilledema in the other eye. Conclusions: The BONSAI deep learning system was able to reliably identify papilledema and normal optic discs on nonmydriatic photographs obtained in the FOTO-ED studies. Our deep learning system has excellent potential as a diagnostic aid in EDs and non-ophthalmology clinics equipped with nonmydriatic fundus cameras.
UR - http://www.scopus.com/inward/record.url?scp=85188184066&partnerID=8YFLogxK
U2 - 10.1016/j.ajo.2023.10.025
DO - 10.1016/j.ajo.2023.10.025
M3 - Article
C2 - 37926337
SN - 0002-9394
VL - 261
SP - 199
EP - 207
JO - American Journal of Ophthalmology
JF - American Journal of Ophthalmology
ER -