We present a neural network approach for closed-loop deep brain stimulation
(DBS). We cast the problem of finding an optimal neurostimulation strategy as a
control problem. In this setting, control policies aim to optimize therapeutic
outcomes by tailoring the parameters of a DBS system, typically via electrical
stimulation, in real time based on the patient's ongoing neuronal activity. We
approximate the value function offline using a neural network to enable
generating controls (stimuli) in real time via the feedback form. The neuronal
activity is characterized by a nonlinear, stiff system of differential
equations as dictated by the Hodgkin-Huxley model. Our training process
leverages the relationship between Pontryagin's maximum principle and
Hamilton-Jacobi-Bellman equations to update the value function estimates
simultaneously. Our numerical experiments illustrate the accuracy of our
approach for out-of-distribution samples and the robustness to moderate shocks
and disturbances in the system.Comment: Extended Abstract presented at Machine Learning for Health (ML4H)
symposium 2023, December 10th, 2023, New Orleans, United States, 12 page