4.0 Article

A Time Duration Discrimination Task for the Study of Elapsed Time Processing in Rats

Journal

BIO-PROTOCOL
Volume 11, Issue 6, Pages -

Publisher

BIO-PROTOCOL
DOI: 10.21769/BioProtoc.3965

Keywords

Rat; Behavior; Temporal processing; Time cells; Episodic memory; Time duration discrimination

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Funding

  1. University of San Diego, College of Arts and Sciences and Mount Holyoke College

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Research indicates that both spatial and temporal information are crucial for episodic memory. While spatial tasks have been extensively used to study the behavioral relevance of place cells, the study of time cells has often overlooked the duration of time as a key variable in behavioral paradigms. Through the novel TDD task, researchers aim to directly investigate the neurological mechanisms underlying temporal processing.
Space and time are both essential features of episodic memory. However, while spatial tasks have been used effectively to study the behavioral relevance of place cells, the behavioral paradigms utilized for the study of time cells have not used time duration as a variable that animals need to be aware of to solve the task. In order to evaluate how time flow is coded into memory, time duration needs to be a variable that animals use to solve the behavioral task. This protocol describes a novel behavioral paradigm, the time duration discrimination (TDD) task, which is designed to directly investigate the neurological mechanisms that underlie temporal processing. During the TDD task, rats navigate around a Figure-8 Maze, which contains a rectangular track with a central arm and a delay box at the end of the central arm. While confined to the delay box, rats experience a 10- or 20-second time delay, during which a tone will play for the duration of the 10- or 20-second delay. When the delay box opens, the rat will choose whether to turn left or right out of the delay box and receive a reward for the correct choice (e.g., 10 seconds = left turn; 20 seconds = right turn). By directly manipulating elapsed time, we can better explore the behavioral relevance of hippocampal time cells and whether the time-dependent activity seen in physiological recordings of hippocampal neurons reflects a neuronal representation of time flow that can be used by the animal for learning and storing memories. [GRAPHICS]

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