Longitudinal Analysis
Longitudinal analysis focuses on studying changes in data over time, aiming to understand dynamic processes and make accurate predictions. Current research emphasizes the use of deep learning models, including transformers, neural ordinary differential equations, and generative adversarial networks, to analyze longitudinal data from diverse sources like social media, medical images, and sensor data. This approach enables improved prediction of disease progression, personalized treatment strategies, and a deeper understanding of complex temporal phenomena across various scientific disciplines, ultimately leading to more effective interventions and resource allocation. The development of robust methods to handle missing data and account for temporal dependencies remains a key challenge and area of active research.
Papers
L-MAE: Longitudinal masked auto-encoder with time and severity-aware encoding for diabetic retinopathy progression prediction
Rachid Zeghlache, Pierre-Henri Conze, Mostafa El Habib Daho, Yihao Li, Alireza Rezaei, Hugo Le Boité, Ramin Tadayoni, Pascal Massin, Béatrice Cochener, Ikram Brahim, Gwenolé Quellec, Mathieu Lamard
Markov chain models for inspecting response dynamics in psychological testing
Andrea Bosco