Quantitative EEG findings in patients with acute, brief depression combined with other fluctuating psychiatric symptoms: a controlled study from an acute psychiatric department.
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Development of NREM sleep instability-continuity (cyclic alternating pattern) in healthy term infants aged 1 to 4 months.
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STUDY OBJECTIVES: To evaluate non-rapid eye movement (NREM) sleep instability, as measured by the cyclic alternating pattern (CAP), in the first months of life in a group of normal healthy infants, in order to obtain more information on the maturation of arousal mechanisms during NREM sleep and to set normative data of CAP parameters in this age range (from 1 to 4 months of life). DESIGN: Retrospective study. SETTING: Sleep unit of an academic centre. PARTICIPANTS: Twenty-three healthy newborns and infants with a mean conceptional age (gestational age plus postnatal age) of 47.6 + 3.8 weeks, age range 42 to 55 weeks, 10 boys (43.47%), were studied while they slept in the morning between feedings, by means of a 3-hour video-electroencephalographic (EEG)-polygraphic recording. Sleep was visually scored for sleep architecture and CAP in a blinded fashion, using standard criteria. MEASUREMENTS AND RESULTS: We found 3 different sleep EEG patterns in our infants, according to their age, and we subdivided the entire group into 3 subgroups. Group 1-Trace alternant mixed with high-voltage slow activity included 9 subjects (3 boys), with a mean conceptional age of 43.9 +/- 1.3 weeks; Group 2 (high-voltage slow activity and rudimentary spindles) included 6 subjects (4 boys), with a mean conceptional age of 49.4 +/- 3.1 weeks; and Group 3 (slow-wave activity and spindles, scored as NREM sleep) included 8 subjects (3 boys), with a mean conceptional age of 50.4 +/- 2.9 weeks. CAP rate was 6.83 +/- 3.58 in infants belonging to Group 2 and increased to 12.91 +/- 2.21 in Group 3. We found a statistically significant higher A1 index in only Group 3. The relative percentages of the A1, A2, and A3 subtypes showed non significant changes with age. The duration of CAP events and the cortical and subcortical arousal indexes were not statistically different between Groups 2 and 3. CONCLUSIONS: With this study, we provide the first data on CAP analysis in infants from 1 to 4 months of life, and we found that there is a transitory period when trace alternant disappears and CAP events begin to occur. Furthermore, we suggest that the more appropriate time of life when CAP analysis can be first performed is related to the appearance of mature stage 2 NREM with spindles and slow delta waves mixed with theta waves, at approximately 3 months of life. (+info)
Electrical hippocampal activity during danger and safety signals in classical conditioning in the rat.
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The effect of stimuli predicting danger (DS) and safety (SS) in Pavlovian aversive conditioning on hippocampal local field potentials (LFP) was studied in 25 partially restrained adult male rats (Long-Evans). DS lasting 5 s preceded tail-shock, while SS overlapping DS during DS last 3 s predicted omission of shock. The power spectra of LFPs during trials were analyzed in theta and delta frequency bands. In DS, theta frequency during the last 3 s was lower that in first 2 s. In danger and safety situation theta peak frequency was different for dorsal CA1 activity (5.99 Hz vs. 6.86 Hz, respectively) while delta peak frequency was different for ventral CA1 (1.56 Hz vs. 1.07 Hz) for the last 3 s of trial. Differences in theta frequency in danger and safety situation may reflect differences in sensory processing during induced emotional states and/or related differences in motor behavior. (+info)
Network modulation of a slow intrinsic oscillation of cat thalamocortical neurons implicated in sleep delta waves: cortically induced synchronization and brainstem cholinergic suppression.
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A slow (0.5-4 Hz) oscillation of thalamic neurons was recently described and attributed to the interplay of two intrinsic currents. In this study, we investigated the network modulation of this intrinsic thalamic oscillation within the frequency range of EEG sleep delta-waves. We performed intracellular and extracellular recordings of antidromically identified thalamocortical cells (n = 305) in sensory, motor, associational, and intralaminar nuclei of anesthetized cats. At the resting membrane potential, Vm (-60.3 +/- 0.4 mV, mean +/- SE), cortical stimulation induced spindle-like oscillations (7-14 Hz), whereas at Vm more negative than -65 mV the same stimuli triggered an oscillation within the EEG delta-frequency (0.5-4 Hz), consisting of low-threshold spikes (LTSs) followed by after hyperpolarizing potentials (AHPs). The LTS-AHP sequences outlasted cortical stimuli as a self-sustained rhythmicity at 1-2 Hz. Corticothalamic stimuli were able to transform subthreshold slow (0.5-4 Hz) oscillations, occurring spontaneously at Vm more negative than -65 mV, into rhythmic LTSs crowned by bursts of Na+ spikes that persisted for 10-20 sec after cessation of cortical volleys. Cortical volleys also revived a hyperpolarization-activated slow oscillation when it dampened after a few cycles. Auto- and crosscorrelograms of neuronal pairs revealed that unrelated cells became synchronized after a series of corticothalamic stimuli, with both neurons displaying rhythmic (1-2 Hz) bursts or spike trains. Since delta-thalamic oscillations, prevailing during late sleep stages, are triggered at more negative Vm than spindles characterizing the early sleep stage, we postulate a progressive hyperpolarization of thalamocortical neurons with the deepening of the behavioral state of EEG-synchronized sleep. In view of the evidence that cortical-elicited slow oscillations depend on synaptically induced hyperpolarization of thalamocortical cells, we propose that the potentiating influence of the corticothalamic input results from the engagement of two GABAergic thalamic cell classes, reticular and local-circuit neurons. The thalamocorticothalamic loop would transfer the spike bursts of thalamic oscillating cells to cortical targets, which in turn would reinforce the oscillation by direct pathways and/or indirect projections relayed by reticular and local-circuit thalamic cells. Stimulation of mesopontine cholinergic [peribrachial (PB) and laterodorsal tegmental (LDT)] nuclei in monoamine-depleted animals had an effect that was opposite to that exerted by corticothalamic volleys. PB/LDT stimulation reduced or suppressed the slow (1-4 Hz) oscillatory bursts of high-frequency spikes in thalamic cells.(ABSTRACT TRUNCATED AT 400 WORDS) (+info)