A Model of a Temporal Filter in Chemoreception to Extract Directional Information From a Turbulent Odor Plume

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A Model of a Temporal Filter in Chemoreception to Extract Directional Information From a Turbulent Odor Plume

PAUL MOORE ¹ and JELLE ATEMA ¹

¹ Boston University Marine Program, Marine Biological Laboratory, Woods Hole, Massachusetts 02543

We ask whether animals can derive spatial information fromtemporal patterns contained in turbulant odor plumes under realisticbiological constraints of receptor properties (size and physiologicalresponses) and behavioral requirements (time averaging). Wemodeled an appropriately scaled aquatic odor plume with a salttracer to serve as the input to two different lobster chemoreceptororgans.

We then constructed a computer model based on some ofthe currently known temporal filtering characteristics of lobsterchemoreceptor cells in situ. The output of this model representsthe supra-threshold stimulus intensity fluctuations "seen" byrealistically adapting cells. The input and output of the modelwere evaluated for directional information. We focused on fourparameters that characterize concentration peaks within theplume: height, length, maximum rising slope, and off time (timebetween peaks). These characteristics were analyzed under twobiologically important sampling strategies: one correspondingto a continuous-sampling receptor organ (e.g., lobster leg,catfish nose) and the other to a discrete-sampling receptororgan (e.g., lobster nose, tuna nose). We let the discrete-samplingmodel analyze at a frequency of four sniffs per second, eachaveraging over 100 ms. The continuous-sampling model used anhistoric exponential average of 25, 100, or 1000 ms based ondisadaptation rates of receptor cells in situ. In this preliminarystudy, filtered odor spectra contained less biologically usefulinformation than the unfiltered input spectra. Discrete andcontinuous models were not different. In all cases, the probabilitydistribution of maximum rising slopes of stimulus concentrationcontained the most reliable directional information.

Submitted on January 7, 1988
Accepted on March 25, 1988

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