Nonlinear Model Predictive Control of a Conductance-Based Neuron Model via Data-Driven Forecasting

Precise control of neural systems is essential to experimental investigations of how the brain controls behavior and holds the potential for therapeutic manipulations to correct aberrant network states like epilepsy. Although purely reactive controllers work well with single neurons and other simple neural systems, more sophisticated techniques are likely to be needed to control complex circuits and systems with nonlinear recurrent dynamics, high levels of exogenous noise, and limited information about the connectivity and state of the network. One potential approach is model predictive control (MPC), which uses a dynamical model to find optimal control inputs by forecasting how the system will respond. However, the challenge still remains of selecting the right model, constraining its parameters, and synchronizing to the neural system. As a proof of principle, we used recent advances in data-driven forecasting to construct a nonlinear machine-learning model of a Hodgkin-Huxley type neuron when only the membrane voltage is observable and there are an unknown number of intrinsic currents. We show that this approach is able to learn the dynamics of different neuron types and can be used with MPC to force the neuron to engage in arbitrary, researcher-defined spiking behaviors.