Forced Desynchronization of Activity Rhythms in a Model of Chronic Jet Lag in Mice

Casiraghi, Leandro P.; Oda, Gisele A.; Chiesa, Juan José; Friesen, W. Otto; Golombék, Diego A.

doi:10.1177/0748730411429447

Cited by 58 publications

(74 citation statements)

References 37 publications

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“…Indeed, either a delay (c) or an advance (d) of the LD cycle will impose a delaying or advancing light-input to the clock, respectively, which will gradually entrain to the new conditions. Finally, chronic jet lag schedules (e, f) or T-cycles outside the entrainment range (g, h) (see Casiraghi et al 2012), are used in the laboratory to study the circadian system under extreme entraining conditions. While the clock can entrain to gradual changes in the LD cycle, when animals are subjected to frequent phase advances of the LD cycle, relative coordination and/or forced desynchronization of behavioral rhythms can be observed described as follows: (a) permanent: people work regularly on one shift only, i.e.…”

Section: Shift Workmentioning

confidence: 99%

“…In addition, we have developed a chronic jet lag schedule consisting of a 6 h LD-advance each two days, which generated a stable desynchronization of two activity components in mice (Casiraghi et al 2012) and exerted severe metabolic alterations (unpublished results). Moreover, animals under similar chronic jet lag protocols showed biphasic corticosterone rhythms (Filipski et al 2004), attenuated AVP and Pk2 expression in the SCN (Yan 2011), and alterations in PER2 expression rhythms in the SCN, thymus, and liver (Castañon-Cervantes et al 2010).…”

Section: Simulated Jet Lagmentioning

confidence: 99%

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Effects of Circadian Disruption on Physiology and Pathology: From Bench to Clinic (and Back)

Chiesa

Duhart

Casiraghi

et al. 2014

Mechanisms of Circadian Systems in Animals and Their Clinical Relevance

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Nested within the hypothalamus, the suprachiasmatic nuclei (SCN) represent a central biological clock that regulates daily and circadian (i.e., close to 24 h) rhythms in mammals. Besides the SCN, a number of peripheral oscillators throughout the body control local rhythms and are usually kept in pace by the central clock. In order to represent an adaptive value, circadian rhythms must be entrained by environmental signals or zeitgebers, the main one being the daily light-dark (LD) cycle. The SCN adopt a stable phase relationship with the LD cycle that, when challenged, results in abrupt or chronic changes in overt rhythms and, in turn, in physiological, behavioral, and metabolic variables. Changes in entrainment, both acute and chronic, may have severe consequences in human performance and pathological outcome. Indeed, animal models of desynchronization have become a useful tool to understand such changes and to evaluate potential treatments in human subjects. Here we review a number of alterations in circadian entrainment, including jet lag, social jet lag (i.e., desynchronization between body rhythms and normal time schedules), shift work, and exposure to nocturnal light, both in human subjects and in laboratory animals. Finally, we focus on the health consequences related to circadian/entrainment disorders and propose a number of approaches for the management of circadian desynchronization. Circadian EntrainmentThe circadian clock located in the hypothalamic suprachiasmatic nucleus (SCN) is the central oscillator that regulates daily rhythms in mammals. Peripheral oscillators coupled to the SCN are synchronized by neural and humoral pathways and are able

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Section: Shift Workmentioning

confidence: 99%

Section: Simulated Jet Lagmentioning

confidence: 99%

Effects of Circadian Disruption on Physiology and Pathology: From Bench to Clinic (and Back)

Chiesa

Duhart

Casiraghi

et al. 2014

Mechanisms of Circadian Systems in Animals and Their Clinical Relevance

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“…It has been shown that entrainment of a free-running circadian oscillator occurs only for a specific range of period and light intensity combinations of the light/dark cycle which set the "range of entrainment" (Abraham et al, 2010;Casiraghi et al, 2012;Granada et al, 2011). In our "random pulse" paradigm, we have fixed the period of the For a fixed light intensity L of 1,000 lux, entrainment was lost after I was gradually increased to 20 hours, as predicted by our computer simulations (Flôres et al, 2013).…”

Section: 3)mentioning

confidence: 72%

“…Each day the light stimulus impinges a phase-shift on the oscillator, but the shift occurs only after transient slow changes in amplitude (Abraham et al, 2010;Casiraghi et al, 2012;Granada et al, 2011;Peterson, 1980). If the amplitude were instantly recovered our random pulse regimens would presumably cause equally random back and forth changes in the phase of the circadian oscillator, possibly failing to keep the phase stable within a 24-hour day.…”

Section: Discussionmentioning

confidence: 99%

Sincronização fótica e não fótica dos ritmos circadianos em roedores subterrâneos (Ctenomys aff. knighti) e roedores modelo de laboratório (Mus musculus)

Flôres¹

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São Paulo July 2016 Ficha catalográficaComissão Julgadora: Prof(a). Dr(a).Prof(a). Dr(a). Prof(a). Dr(a).Prof(a). Dr(a Carreira Improta and Jefferson Silva. They were more than my labmates. We have been through some happy and some not so happy moments in the long-lasting travels to Anillaco, helping one another in our experiments. In the paper discussions, together with our supervisors, we ventured into the wilderness of abstract concepts.

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“…Não somente em organismos fotossintetizantes, mas para qualquer modelo tal conceito é essencial, um exemplo são as análises do comportamento de camundongos em rodas de exercício que registram ao longo de meses a frequência da atividade dos animais submetidos a diversas condições. (CASIRAGHI et al, 2012;VALENTINUZZI et al, 2009), utilizando o menor esforço possível do observador.…”

Section: Ensaio Enzimático Da Nrunclassified

Ritmos circadianos em Gracilaria birdiae (Rhodophyta): oscilação do desempenho fotossintético e caracterização enzimática da nitrato redutase

Júnior¹,

Alves²

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Forced Desynchronization of Activity Rhythms in a Model of Chronic Jet Lag in Mice

Cited by 58 publications

References 37 publications

Effects of Circadian Disruption on Physiology and Pathology: From Bench to Clinic (and Back)

Effects of Circadian Disruption on Physiology and Pathology: From Bench to Clinic (and Back)

Sincronização fótica e não fótica dos ritmos circadianos em roedores subterrâneos (Ctenomys aff. knighti) e roedores modelo de laboratório (Mus musculus)

Ritmos circadianos em Gracilaria birdiae (Rhodophyta): oscilação do desempenho fotossintético e caracterização enzimática da nitrato redutase

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