Cardiovascular physiology and sleep

Somers, Virend K.

doi:10.2741/1105

Cited by 80 publications

(13 citation statements)

References 124 publications

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“…Our finding that adrenergic C1 neurons are activated during REMS-like state provides a mechanistic explanation for the mean arterial blood pressure increases that occur during transitions from slow-wave sleep to REMS [113], [114], [115]. Indeed, the average blood pressure increases that we observed during REMS-like episodes were significant and of a similar magnitude as those observed on the average during REMS [113], [114], [115] (as discussed in the preceding section, the model that we used does not generate phasic events of REMS; accordingly, we cannot comment on blood pressure variability that is another characteristic feature of natural REMS but is absent from the carbachol models).…”

Section: Discussionmentioning

confidence: 72%

Evidence That Adrenergic Ventrolateral Medullary Cells Are Activated whereas Precerebellar Lateral Reticular Nucleus Neurons Are Suppressed during REM Sleep

et al. 2013

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Rapid eye movement sleep (REMS) is generated in the brainstem by a distributed network of neurochemically distinct neurons. In the pons, the main subtypes are cholinergic and glutamatergic REMS-on cells and aminergic REMS-off cells. Pontine REMS-on cells send axons to the ventrolateral medulla (VLM), but little is known about REMS-related activity of VLM cells. In urethane-anesthetized rats, dorsomedial pontine injections of carbachol trigger REMS-like episodes that include cortical and hippocampal activation and suppression of motoneuronal activity; the episodes last 4–8 min and can be elicited repeatedly. We used this model to determine whether VLM catecholaminergic cells are silenced during REMS, as is typical of most aminergic neurons studied to date, and to investigate other REMS-related cells in this region. In 18 anesthetized, paralyzed and artificially ventilated rats, we obtained extracellular recordings from VLM cells when REMS-like episodes were elicited by pontine carbachol injections (10 mM, 10 nl). One major group were the cells that were activated during the episodes (n = 10). Their baseline firing rate of 3.7±2.1 (SD) Hz increased to 9.7±2.1 Hz. Most were found in the adrenergic C1 region and at sites located less than 50 µm from dopamine β-hydroxylase-positive (DBH+) neurons. Another major group were the silenced or suppressed cells (n = 35). Most were localized in the lateral reticular nucleus (LRN) and distantly from any DBH+ cells. Their baseline firing rates were 6.8±4.4 Hz and 15.8±7.1 Hz, respectively, with the activity of the latter reduced to 7.4±3.8 Hz. We conclude that, in contrast to the pontine noradrenergic cells that are silenced during REMS, medullary adrenergic C1 neurons, many of which drive the sympathetic output, are activated. Our data also show that afferent input transmitted to the cerebellum through the LRN is attenuated during REMS. This may distort the spatial representation of body position during REMS.

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Section: Discussionmentioning

confidence: 72%

Evidence That Adrenergic Ventrolateral Medullary Cells Are Activated whereas Precerebellar Lateral Reticular Nucleus Neurons Are Suppressed during REM Sleep

et al. 2013

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“…This inflammation may induce a hypercoagulable state that could be directly involved in the pathogenesis of diseases such as coronary artery disease, although the exact mechanisms remain unknown. Many papers have linked poor sleep to increased risk of cardiovascular disease [10,25], and the role of systemic inflammation and hypercoagulable states resulting from disordered sleep or loss of sleep requires further investigation.…”

Section: Discussionmentioning

confidence: 99%

Effects of sleep and sleep deprivation on blood cell count and hemostasis parameters in healthy humans

Liu

Ge-ge

Guihong

et al. 2008

J Thromb Thrombolysis

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“…We found that sleep restriction with CM was associated with higher HR and lower HRV during non-REM stages (i.e., SWS and Stage II) as compared to sleep restriction with CA. Given the importance of SWS and non-REM sleep in cardiovascular restoration, 31 these findings suggest that recurrent or chronic circadian misalignment has adverse cardiovascular effects that are not readily corrected as soon as a normal daytime schedule is re-instated. The rate of recovery of nocturnal autonomous nervous system activity following abrupt shifts of the sleep-wake cycle needs further study to improve our understanding of the adverse cardiovascular consequences of shift work and design preventive strategies.…”

Section: Discussionmentioning

confidence: 99%

Adverse Impact of Sleep Restriction and Circadian Misalignment on Autonomic Function in Healthy Young Adults

et al. 2016

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Insufficient sleep and circadian rhythm disturbances have been each associated with adverse cardiovascular outcomes in epidemiologic studies, but experimental evidence for a causal link is scarce. The present study compares the impact of circadian misalignment (CM) to circadian alignment (CA) on human autonomic function using a nonrandomized parallel group design to achieve the same total sleep time in both conditions. Following baseline assessments (three days with 10h bedtimes), 26 healthy young adults were assigned to sleep restriction (SR; eight 5h bedtimes) with either fixed nocturnal bedtimes (CA; n=13) or bedtimes delayed by 8.5h on 4 of the 8 days (CM; n=13). Daytime ambulatory blood pressure (BP) and heart rate (HR, CA: n=11, CM: n=10), and 24-hour urinary norepinephrine levels (NE, CA: n=13, CM: n=13) were assessed at baseline and the end of SR. Nocturnal HR and heart rate variability (HRV) were analyzed during sleep at baseline and during the 4th and 7th nights of SR (CA: n=8, CM: n=12). SR resulted in a significant increase in daytime HR in both groups, without changes in BP. SR increased 24-hour urinary NE in the CM group (30±4 vs. 21±2 μg), but not in the circadian alignment group (group×condition, p=0.005). In contrast to the lack of detectable impact of CM on daytime autonomic function, SR with CM elicited greater increases in nocturnal HR, as well as greater reductions in vagal indices of HRV, than SR without CM (group×condition, p<0.05). In conclusion, SR and CM both result in impaired autonomic function that could lead, under chronic conditions, to enhanced cardiovascular risk.

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Cardiovascular physiology and sleep

Cited by 80 publications

References 124 publications

Evidence That Adrenergic Ventrolateral Medullary Cells Are Activated whereas Precerebellar Lateral Reticular Nucleus Neurons Are Suppressed during REM Sleep

Evidence That Adrenergic Ventrolateral Medullary Cells Are Activated whereas Precerebellar Lateral Reticular Nucleus Neurons Are Suppressed during REM Sleep

Effects of sleep and sleep deprivation on blood cell count and hemostasis parameters in healthy humans

Adverse Impact of Sleep Restriction and Circadian Misalignment on Autonomic Function in Healthy Young Adults

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