Respiratory-like periodicities in slow eye movements during sleep onset

Rhythms of the body, rhythms of the brain: Respiration, neural oscillations, and embodied cognition

In spite of its importance as a life-defining rhythmic movement and its constant rhythmic contraction and relaxation of the body, respiration has not received attention in Embodied Cognition (EC) literature. Our paper aims to show that (1) respiration exerts significant and unexpected influence on cognitive processes, and (2) it does so by modulating neural synchronization that underlies specific cognitive processes. Then, (3) we suggest that the particular example of respiration may function as a model for a general mechanism through which the body influences cognitive functioning. Finally, (4) we work out the implications for EC, draw a parallel to the role of gesture, and argue that respiration sometimes plays a double, pragmatic and epistemic, role, which reduces the cognitive load. In such cases, consistent with EC, the overall cognitive activity includes a loop-like interaction between neural and non-neural elements.

Breathing as a Fundamental Rhythm of Brain Function

Ongoing fluctuations of neuronal activity have long been considered intrinsic noise that introduces unavoidable and unwanted variability into neuronal processing, which the brain eliminates by averaging across population activity (Georgopoulos et al., 1986; Lee et al., 1988; Shadlen and Newsome, 1994; Maynard et al., 1999). It is now understood, that the seemingly random fluctuations of cortical activity form highly structured patterns, including oscillations at various frequencies, that modulate evoked neuronal responses (Arieli et al., 1996; Poulet and Petersen, 2008; He, 2013) and affect sensory perception (Linkenkaer-Hansen et al., 2004; Boly et al., 2007; Sadaghiani et al., 2009; Vinnik et al., 2012; Palva et al., 2013). Ongoing cortical activity is driven by proprioceptive and interoceptive inputs. In addition, it is partially intrinsically generated in which case it may be related to mental processes (Fox and Raichle, 2007; Deco et al., 2011). Here we argue that respiration, via multiple sensory pathways, contributes a rhythmic component to the ongoing cortical activity. We suggest that this rhythmic activity modulates the temporal organization of cortical neurodynamics, thereby linking higher cortical functions to the process of breathing.

Cardiovascular rhythms in the 0.15-Hz band: common origin of identical phenomena in man and dog in the reticular formation of the brain stem?

Selected examples from experiments in humans and dogs with time series of reticular neurons, respiration, arterial blood pressure and cutaneous forehead blood content fluctuations were analysed using multiscaled time-frequency distribution, post-event-scan and pointwise transinformation. We found in both experiments a "0.15-Hz rhythm" exhibiting periods of spindle waves (increasing and decreasing amplitudes), phase synchronized with respiration at 1:2 and 1:1 integer number ratios. At times of wave-epochs and n:m phase synchronization, the 0.15-Hz rhythm appeared in heart rate and arterial blood pressure. As phase synchronization of the 0.15-Hz rhythm with respiration was established at a 1:1 integer number ratio, all cardiovascular-respiratory oscillations were synchronized at 0.15 Hz. Analysis of a canine experiment supplied evidence that the emergence of the 0.15-Hz rhythm and n:m phase synchronization appears to result from a decline in the level of the general activity of the organism associated with a decline in the level of activity of reticular neurons in the lower brainstem network. These findings corroborate the notion of the 0.15-Hz rhythm as a marker of the "trophotropic mode of operation" first introduced by W.R. Hess.

The process of falling asleep

The process of falling asleep can best be measured by considering a convergence of behavioural, EEG, physiological and subjective information. Doing so allows one to see sleep processes as they unfold, but relying on any single sleep index can bias the description of this complex process. The studies reviewed do not support the idea that sleep begins "in a moment", but rather that entry into sleep is a continuous, interwoven series of changes which begin in relaxed drowsiness and continue through stage 1, often into the first minutes of stage 2. The transition from waking brain to sleeping brain is traced accurately by Hori's nine-stage EEG system. Event-related potential (ERP) studies map complex changes in information processing as sleep begins, while quantitative EEG investigations have identified important spatiotemporal re-organisations of primary EEG frequencies which take place as one moves from waking to sleeping mode. To consider evidence from multiple levels of analysis, a three step electrophysiological model of central nervous system (CNS) regulation during sleep onset is proposed: initial processes appear to be alpha-related; intermediate processes, poorly studied to date, parallel the development of theta and vertex sharp wave activity, while the processes which terminate wakefulness are sigma sleep spindle-related. Clinical investigations of the sleep onset period in people with narcolepsy, insomnia, depression or sleep apnoea appear to indicate the presence of relatively unique electrophysiological signatures which may be of clinical significance. 2001 Harcourt Publishers Ltd

Common slow modulation of respiration, arterial blood pressure and cortical activity during sleep onset while napping

Using healthy subjects, concomitant 30- to 60-s modulations of respiration, arterial blood pressure and EEG activity were found in 21 experiments about napping. Although mean arterial pressure (MAP) modulations above and below 1/30 Hz increased, in respiratory amplitude (RA) only the lower frequency components augmented significantly. This slow modulation of RA was found to be asymmetrical in time, the duration of RA decreasing parts in the modulation waves being 42% longer than the duration of RA increasing parts. The concomitance of the slow modulations in the different organ systems is accounted for by the influence of the common brainstem system (CBS), which regulates and integrates respiratory, cardiovascular and somatomotor systems and the adjustment of central nervous activity (vigilance). The described common, slow modulations outline the importance of dampening influences during sleep onset. They may provide an important tool for the investigation of the regulatory systems during sleep onset, as well as for investigations about sleep apnoea syndrome and Cheyne-Stokes breathing.