In mammals, the so-called “seat of the cognitive map” is located in place cells within the hippocampus. Recent work suggests that the shape of place cell fields might be defined by the animals’ natural movement; in rats the fields appear to be laterally compressed (meaning that the spatial map of the animal is more highly resolved in the horizontal dimensions than in the vertical), whereas the place cell fields of bats are statistically spherical (which should result in a spatial map that is equally resolved in all three dimensions). It follows that navigational error should be equal in the horizontal and vertical dimensions in animals that travel freely through volumes, whereas in surface-bound animals would demonstrate greater vertical error. Here, we describe behavioral experiments on pelagic fish in which we investigated the way that fish encode three-dimensional space and we make inferences about the underlying processing. Our work suggests that fish, like mammals, have a higher order representation of space that assembles incoming sensory information into a neural unit that can be used to determine position and heading in three-dimensions. Further, our results are consistent with this representation being encoded isotropically, as would be expected for animals that move freely through volumes. Definitive evidence for spherical place fields in fish will not only reveal the neural correlates of space to be a deep seated vertebrate trait, but will also help address the questions of the degree to which environment spatial ecology has shaped cognitive processes and their underlying neural mechanisms.
Hydrostatic pressure is a global cue that varies linearly with depth which could provide crucial spatial information for fish navigating vertically; however, whether fish can determine their depth using hydrostatic pressure has remained unknown. Here we show that Mexican tetras (Astyanax mexicanus) can learn the depth of a food site and consistently return to it with high fidelity using only hydrostatic pressure as a cue. Further, fish shifted their search location vertically as predicted if using pressure alone to signal depth. This study uncovers new sensory information available to fish which allows them to resolve their absolute depth on a fine scale.
Introduction: Atopic dermatitis (AD) is an inflammatory disease causing severe skin itching. Data on patient-physician disconnect on treatment satisfaction in patients with AD in Japan are limited. We investigated patient-physician disconnect on treatment satisfaction in AD and if it influences treatment patterns, clinical characteristics, and patientreported outcomes (PROs). Methods: Data were drawn from the Adelphi AD Disease Specific Programme (DSP), a realworld, point-in-time survey of physicians and patients with AD conducted in Japan from April to July 2019. Patients and physicians were grouped according to level of treatment satisfaction (''extremely satisfied'' to ''extremely dissatisfied''); with any level of dissatisfaction recorded as ''less than satisfied.'' Data were collected on treatment patterns, clinical characteristics, and PROs including the Dermatology Life Quality Index (DLQI), Patient-Oriented
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