Your search keyword '"Leerstoel Bolhuis"' showing total 2 results

1. Bird-like propagating brain activity in anesthetized Nile crocodiles

Author

Tisdale, Ryan K, Lesku, John A, Beckers, Gabriel J L, Rattenborg, Niels C, Leerstoel Bolhuis, Experimental Psychology (onderzoeksprogramma PF), Helmholtz Institute, Leerstoel Bolhuis, Experimental Psychology (onderzoeksprogramma PF), and Helmholtz Institute

Subjects

Male, 0301 basic medicine, Dorsum, Brain activity and meditation, Neuronal membrane, Sleep, REM, propagating, Electrophysiological Phenomena, traveling, high-voltage sharp waves, Biology, Electroencephalography, Sleep, Slow-Wave, Membrane Potentials, Birds, isoflurane, 03 medical and health sciences, slow waves, 0302 clinical medicine, Crocodylus niloticus, Physiology (medical), evolution, medicine, Animals, Humans, dorsal ventricular ridge, Neurons, Alligators and Crocodiles, medicine.diagnostic_test, Brain, Eye movement, Brain Waves, Sleep in non-human animals, 030104 developmental biology, Neurology (clinical), Sharp wave, Neuroscience, 030217 neurology & neurosurgery

Abstract

Study Objectives: The changes in electroencephalogram (EEG) activity that characterize sleep and its sub-states-slow-wave sleep (SWS) and rapid eye movement (REM) sleep-are similar in mammals and birds. SWS is characterized by EEG slow waves resulting from the synchronous alternation of neuronal membrane potentials between hyperpolarized down-states with neuronal quiescence and depolarized up-states associated with action potentials. By contrast, studies of non-avian reptiles report the presence of high-voltage sharp waves (HShW) during sleep. How HShW relate to EEG phenomena occurring during mammalian and avian sleep is unclear. We investigated the spatiotemporal patterns of electrophysiological phenomena in Nile crocodiles (Crocodylus niloticus) anesthetized with isoflurane to determine whether they share similar spatiotemporal patterns to mammalian and avian slow waves. Methods: Recordings of anesthetized crocodiles were made using 64-channel penetrating arrays with electrodes arranged in an 8 × 8 equally spaced grid. The arrays were placed in the dorsal ventricular ridge (DVR), a region implicated in the genesis of HShW. Various aspects of the spatiotemporal distribution of recorded signals were investigated. Results: Recorded signals revealed the presence of HShW resembling those reported in earlier studies of naturally sleeping reptiles. HShW propagated in complex and variable patterns across the DVR. Conclusions: We demonstrate that HShW within the DVR propagate in complex patterns similar to those observed for avian slow waves recorded from homologous brain regions. Consequently, sleep with HShW may represent an ancestral form of SWS, characterized by up-states occurring less often and for a shorter duration than in mammals and birds.

Published

2018

2. Intra-'cortical' activity during avian non-REM and REM sleep: variant and invariant traits between birds and mammals

Author

van der Meij, Jacqueline, Martinez-Gonzalez, Dolores, Beckers, Gabriël J L, Rattenborg, Niels C, Leerstoel Bolhuis, Helmholtz Institute, Experimental Psychology (onderzoeksprogramma PF), Afd Psychologische functieleer, Leerstoel Bolhuis, Helmholtz Institute, Experimental Psychology (onderzoeksprogramma PF), and Afd Psychologische functieleer

Subjects

Male, Thalamus, Sleep, REM, Neocortex, Biology, Sleep, Slow-Wave, Non-rapid eye movement sleep, Hippocampus, Birds, 03 medical and health sciences, Mice, 0302 clinical medicine, slow-waves, Physiology (medical), propagation, medicine, Premovement neuronal activity, Animals, Wakefulness, Columbidae, Visual Cortex, Neurons, Sleep Stages, Brain Mapping, avian, Electroencephalography, Sleep in non-human animals, medicine.anatomical_structure, cortex, 030228 respiratory system, NREM sleep, Memory consolidation, Neurology (clinical), REM sleep, Neuroscience, spindles, 030217 neurology & neurosurgery, psychological phenomena and processes

Abstract

Several mammalian-based theories propose that the varying patterns of neuronal activity occurring in wakefulness and sleep reflect different modes of information processing. Neocortical slow-waves, hippocampal sharp-wave ripples, and thalamocortical spindles occurring during mammalian non-rapid eye-movement (NREM) sleep are proposed to play a role in systems-level memory consolidation. Birds show similar NREM and REM (rapid eye-movement) sleep stages to mammals; however, it is unclear whether all neurophysiological rhythms implicated in mammalian memory consolidation are also present. Moreover, it is unknown whether the propagation of slow-waves described in the mammalian neocortex occurs in the avian "cortex" during natural NREM sleep. We used a 32-channel silicon probe connected to a transmitter to make intracerebral recordings of the visual hyperpallium and thalamus in naturally sleeping pigeons (Columba livia). As in the mammalian neocortex, slow-waves during NREM sleep propagated through the hyperpallium. Propagation primarily occurred in the thalamic input layers of the hyperpallium, regions that also showed the greatest slow-wave activity (SWA). Spindles were not detected in both the visual hyperpallium, including regions receiving thalamic input, and thalamus, using a recording method that readily detects spindles in mammals. Interestingly, during REM sleep fast gamma bursts in the hyperpallium (when present) were restricted to the thalamic input layers. In addition, unlike mice, the decrease in SWA from NREM to REM sleep was the greatest in these layers. Taken together, these variant and invariant neurophysiological aspects of avian and mammalian sleep suggest that there may be associated mechanistic and functional similarities and differences between avian and mammalian sleep.

Published

2019