TY - JOUR
T1 - Perchance to dream? Primordial motor activity patterns in vertebrates from fish to mammals
T2 - their prenatal origin, postnatal persistence during sleep, and pathological reemergence during REM sleep behavior disorder
AU - Corner, Michael A.
AU - Schenck, Carlos H.
N1 - Publisher Copyright:
© 2015, Shanghai Institutes for Biological Sciences, CAS and Springer-Verlag Berlin Heidelberg.
PY - 2015/12/1
Y1 - 2015/12/1
N2 - An overview is presented of the literature dealing with sleep-like motility and concomitant neuronal activity patterns throughout the life cycle in vertebrates, ectothermic as well as endothermic. Spontaneous, periodically modulated, neurogenic bursts of non-purposive movements are a universal feature of larval and prenatal behavior, which in endothermic animals (i.e. birds and mammals) continue to occur periodically throughout life. Since the entire body musculature is involved in ever-shifting combinations, it is proposed that these spontaneously active periods be designated as ‘rapid-BODY-movement’ (RBM) sleep. The term ‘rapid-EYE-movement (REM) sleep’, characterized by attenuated muscle contractions and reduced tonus, can then be reserved for sleep at later stages of development. Mature stages of development in which sustained muscle atonia is combined with ‘paradoxical arousal’ of cortical neuronal firing patterns indisputably represent the evolutionarily most recent aspect of REM sleep, but more research with ectothermic vertebrates, such as fish, amphibians and reptiles, is needed before it can be concluded (as many prematurely have) that RBM is absent in these species. Evidence suggests a link between RBM sleep in early development and the clinical condition known as ‘REM sleep behavior disorder (RBD)’, which is characterized by the resurgence of periodic bouts of quasi-fetal motility that closely resemble RBM sleep. Early developmental neuromotor risk factors for RBD in humans also point to a relationship between RBM sleep and RBD.
AB - An overview is presented of the literature dealing with sleep-like motility and concomitant neuronal activity patterns throughout the life cycle in vertebrates, ectothermic as well as endothermic. Spontaneous, periodically modulated, neurogenic bursts of non-purposive movements are a universal feature of larval and prenatal behavior, which in endothermic animals (i.e. birds and mammals) continue to occur periodically throughout life. Since the entire body musculature is involved in ever-shifting combinations, it is proposed that these spontaneously active periods be designated as ‘rapid-BODY-movement’ (RBM) sleep. The term ‘rapid-EYE-movement (REM) sleep’, characterized by attenuated muscle contractions and reduced tonus, can then be reserved for sleep at later stages of development. Mature stages of development in which sustained muscle atonia is combined with ‘paradoxical arousal’ of cortical neuronal firing patterns indisputably represent the evolutionarily most recent aspect of REM sleep, but more research with ectothermic vertebrates, such as fish, amphibians and reptiles, is needed before it can be concluded (as many prematurely have) that RBM is absent in these species. Evidence suggests a link between RBM sleep in early development and the clinical condition known as ‘REM sleep behavior disorder (RBD)’, which is characterized by the resurgence of periodic bouts of quasi-fetal motility that closely resemble RBM sleep. Early developmental neuromotor risk factors for RBD in humans also point to a relationship between RBM sleep and RBD.
KW - REM sleep behavior disorder
KW - development
KW - evolution
KW - neuronal networks
KW - neuroplasticity
KW - sleep
KW - spike-train analysis
KW - spontaneous motility
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U2 - 10.1007/s12264-015-1557-1
DO - 10.1007/s12264-015-1557-1
M3 - Review article
C2 - 26319263
AN - SCOPUS:84949109122
SN - 1673-7067
VL - 31
SP - 649
EP - 662
JO - Neuroscience Bulletin
JF - Neuroscience Bulletin
IS - 6
ER -