Purpose: To develop a data-driven interpretable predictive model of incoming drusen regression as a sign of disease activity and identify optical coherence tomography (OCT) biomarkers associated with its risk in intermediate age-related macular degeneration (AMD). Methods: Patients with AMD were observed every 3 months, using Spectralis OCT imaging, for a minimum duration of 12 months and up to a period of 60 months. Segmentation of drusen and the overlying layers was obtained using a graph-theoretic method, and the hyperreflective foci were segmented using a voxel classification method. Automated image analysis steps were then applied to identify and characterize individual drusen at baseline, and their development was monitored at every follow-up visit. Finally, a machine learning method based on a sparse Cox proportional hazard regression was developed to estimate a risk score and predict the incoming regression of individual drusen. Results: The predictive model was trained and evaluated on a longitudinal dataset of 61 eyes from 38 patients using cross-validation. The mean follow-up time was 37.8 ± 13.8 months. A total of 944 drusen were identified at baseline, out of which 249 (26%) regressed during follow-up. The prediction performance was evaluated as area under the curve (AUC) for different time periods. Prediction within the first 2 years achieved an AUC of 0.75. Conclusions: The predictive model proposed in this study represents a promising step toward image-guided prediction of AMD progression. Machine learning is expected to accelerate and contribute to the development of new therapeutics that delay the progression of AMD.
Purpose: To develop a data-driven interpretable predictive model of incoming drusen regression as a sign of disease activity and identify optical coherence tomography (OCT) biomarkers associated with its risk in intermediate age-related macular degeneration (AMD). Methods:Patients with AMD were observed every 3 months, using Spectralis OCT imaging, for a minimum duration of 12 months and up to a period of 60 months. Segmentation of drusen and the overlying layers was obtained using a graph-theoretic method, and the hyperreflective foci were segmented using a voxel classification method. Automated image analysis steps were then applied to identify and characterize individual drusen at baseline, and their development was monitored at every follow-up visit. Finally, a machine learning method based on a sparse Cox proportional hazard regression was developed to estimate a risk score and predict the incoming regression of individual drusen. Results: The predictive model was trained and evaluated on a longitudinal dataset of 61 eyes from 38 patients using cross-validation. The mean follow-up time was 37.8 ± 13.8 months. A total of 944 drusen were identified at baseline, out of which 249 (26%) regressed during follow-up. The prediction performance was evaluated as area under the curve (AUC) for different time periods. Prediction within the first 2 years achieved an AUC of 0.75. Conclusions: The predictive model proposed in this study represents a promising step toward image-guided prediction of AMD progression. Machine learning is expected to accelerate and contribute to the development of new therapeutics that delay the progression of AMD.
Authors: Janice Sutton; Martin J Menten; Sophie Riedl; Hrvoje Bogunović; Oliver Leingang; Philipp Anders; Ahmed M Hagag; Sebastian Waldstein; Amber Wilson; Angela J Cree; Ghislaine Traber; Lars G Fritsche; Hendrik Scholl; Daniel Rueckert; Ursula Schmidt-Erfurth; Sobha Sivaprasad; Toby Prevost; Andrew Lotery Journal: Eye (Lond) Date: 2022-05-25 Impact factor: 4.456
Authors: Jason Yim; Reena Chopra; Terry Spitz; Jim Winkens; Annette Obika; Christopher Kelly; Harry Askham; Marko Lukic; Josef Huemer; Katrin Fasler; Gabriella Moraes; Clemens Meyer; Marc Wilson; Jonathan Dixon; Cian Hughes; Geraint Rees; Peng T Khaw; Alan Karthikesalingam; Dominic King; Demis Hassabis; Mustafa Suleyman; Trevor Back; Joseph R Ledsam; Pearse A Keane; Jeffrey De Fauw Journal: Nat Med Date: 2020-05-18 Impact factor: 53.440
Authors: Rene Y Choi; Aaron S Coyner; Jayashree Kalpathy-Cramer; Michael F Chiang; J Peter Campbell Journal: Transl Vis Sci Technol Date: 2020-02-27 Impact factor: 3.283
Authors: Omer Trivizki; Michael R Karp; Anuj Chawla; Justin Yamanuha; Giovanni Gregori; Philip J Rosenfeld Journal: Am J Ophthalmol Date: 2020-07-02 Impact factor: 5.258