Tracking receptive field modulation during natural stimulation

Nicholas A. Lesica and Garrett B. Stanley
Division of Engineering and Applied Sciences
Harvard University

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Traditional approaches to characterizing the stimulus/response mapping in sensory systems make a number of simplifying assumptions: 1) the stimulus is stationary and uncorrelated, 2) the mapping does not change over time, and 3) the response of the neuron depends only on the stimulus and is independent from one interval to the next. However, characterizing the stimulus/response mapping in a natural setting demands a more realistic model of sensory encoding in which stimuli of arbitrary complexity are adaptively filtered into a history dependent neural response. To identify the stimulus/response mapping in this context, a new analytic approach must be developed. This poster introduces a point process extended recursive least-squares (ERLS) approach to receptive field estimation with the ability to: 1) estimate RFs from responses to complex natural stimuli, 2) track adaptation of receptive field properties during a single trial, and 3) capture the behavior of a neuron more accurately by including history dependence in a point process response model. This powerful approach allows us to track RF modulation in retinal ganglion cells in response to changes in contrast and investigate the nonlinearity of LGN responses to natural scenes. The ERLS technique lends tremendous flexibility to experimental design, which is essential for the investigation of sensory function in the natural environment.