Circadian Photoentrainment: Parameters of Phase Delaying
Author(s) -
Patricia J. DeCoursey
Publication year - 1986
Publication title -
journal of biological rhythms
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.484
H-Index - 101
eISSN - 1552-4531
pISSN - 0748-7304
DOI - 10.1177/074873048600100301
Subject(s) - circadian rhythm , nocturnal , rhythm , entrainment (biomusicology) , phase response curve , phase response , light cycle , phase (matter) , circadian clock , biology , audiology , medicine , chemistry , endocrinology , organic chemistry
Experiments were carried out using simulated den cages to delineate specific char acteristics of phase delaying in circadian photoentrainment of a nocturnal rodent, the flying squirrel. The principal experiments entailed presentation of one to five consecutive 15-min white-light pulses per activity cycle at activity onset to animals free-running in darkness, in order to determine the immediate and final phase-shifting effect. Auxiliary experiments recorded entrainment patterns on light-dark (LD) schedules in the den cages. Phase response curves (PRCs) based on 15-min white-light pulses in standard wheel cages were also constructed for these animals as background information for interpreting the phase-delaying experiments. Exposure of a den animal to light by light sampling at the time of initial arousal from the rest state at circadian time (CT) 12, either by an LD schedule or by a 15-min light pulse, resulted in a return to the nest box for a short rest period. The phase delay occurring after a single light exposure at activity onset was equal to the induced rest, thus suggesting an immediate phase shift. The maximum delay was about 11/2 hr/cycle, with the amount of delay related to the number of light exposures. During the photoentrained state on an LD schedule, the activity rhythm of a den-housed animal was essentially free-running on the days following a phase delay. The data are used to expand current models for photoentrainment of circadian activity rhythms in nocturnal rodents.
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