BACKGROUND: There is a daily rhythm in the voluntary intake of ethanol in mice, with greatest consumption in the early night and lowest intake during the day. The role of daily timing of ethanol exposure on the development and control of long-term ethanol self-administration has been neglected. The present study examines these issues using C57BL/6J mice. METHODS: Mice were repeatedly exposed to 10% ethanol for 2 hours early in the night or day for several weeks. Subsequently, ethanol was available at the opposite time (Expt 1) or 24 hours daily (Expts 1 and 2). Lick sensors recorded the patterns of drinking activity in Experiment 2. RESULTS: Mice exposed to ethanol during the night drink more than mice exposed during the day. Prior history did not affect ethanol intake when the schedule was reversed. Under 24-hour exposure conditions, mice with a history of drinking during the night consumed significantly more than mice drinking during the day. The circadian patterns of drinking were not altered. CONCLUSIONS: These results demonstrate that the daily timing of ethanol exposure exerts enduring effects of self-administration of ethanol in mice. Understanding how circadian rhythms regulate ethanol consumption may be valuable for modifying subsequent intake.
BACKGROUND: There is a daily rhythm in the voluntary intake of ethanol in mice, with greatest consumption in the early night and lowest intake during the day. The role of daily timing of ethanol exposure on the development and control of long-term ethanol self-administration has been neglected. The present study examines these issues using C57BL/6J mice. METHODS:Mice were repeatedly exposed to 10% ethanol for 2 hours early in the night or day for several weeks. Subsequently, ethanol was available at the opposite time (Expt 1) or 24 hours daily (Expts 1 and 2). Lick sensors recorded the patterns of drinking activity in Experiment 2. RESULTS:Mice exposed to ethanol during the night drink more than mice exposed during the day. Prior history did not affect ethanol intake when the schedule was reversed. Under 24-hour exposure conditions, mice with a history of drinking during the night consumed significantly more than mice drinking during the day. The circadian patterns of drinking were not altered. CONCLUSIONS: These results demonstrate that the daily timing of ethanol exposure exerts enduring effects of self-administration of ethanol in mice. Understanding how circadian rhythms regulate ethanol consumption may be valuable for modifying subsequent intake.
Authors: Satchidananda Panda; Marina P Antoch; Brooke H Miller; Andrew I Su; Andrew B Schook; Marty Straume; Peter G Schultz; Steve A Kay; Joseph S Takahashi; John B Hogenesch Journal: Cell Date: 2002-05-03 Impact factor: 41.582
Authors: Elizabeth Munn; Mark Bunning; Sofia Prada; Martin Bohlen; John C Crabbe; Douglas Wahlsten Journal: Behav Brain Res Date: 2011-06-01 Impact factor: 3.332
Authors: Jennifer L Trujillo; David T Do; Nicholas J Grahame; Amanda J Roberts; Michael R Gorman Journal: Alcohol Date: 2010-09-29 Impact factor: 2.405
Authors: Bryan E Jensen; Kayla G Townsley; Kolter B Grigsby; Pamela Metten; Meher Chand; Miracle Uzoekwe; Alex Tran; Evan Firsick; Katherine LeBlanc; John C Crabbe; Angela R Ozburn Journal: Brain Sci Date: 2021-02-04