Background: The study of learning in populations of subjects can provide insights into the changes that occur in the brain with aging, drug intervention, and psychiatric disease.
New method: We introduce a separable two-dimensional (2D) random field (RF) model for analyzing binary response data acquired during the learning of object-reward associations across multiple days. The method can quantify the variability of performance within a day and across days, and can capture abrupt changes in learning.
Results: We apply the method to data from young and aged macaque monkeys performing a reversal-learning task. The method provides an estimate of performance within a day for each age group, and a learning rate across days for each monkey. We find that, as a group, the older monkeys require more trials to learn the object discriminations than do the young monkeys, and that the cognitive flexibility of the younger group is higher. We also use the model estimates of performance as features for clustering the monkeys into two groups. The clustering results in two groups that, for the most part, coincide with those formed by the age groups. Simulation studies suggest that clustering captures inter-individual differences in performance levels.
Comparison with existing method(s): In comparison with generalized linear models, this method is better able to capture the inherent two-dimensional nature of the data and find between group differences.
Conclusions: Applied to binary response data from groups of individuals performing multi-day behavioral experiments, the model discriminates between-group differences and identifies subgroups.
Keywords: Aging; Bayesian inference; Behavior; Change-point test; EM algorithm; Gibbs sampling; Laplace prior; Learning; MAP estimation; Markov Chain Monte Carlo; Reversal learning task; Separable random field model.
Copyright © 2018 The Authors. Published by Elsevier B.V. All rights reserved.