Showing below up to 50 results in range #451 to #500.

View (previous 50 | next 50) (20 | 50 | 100 | 250 | 500)

451. (hist) ‎Remembering to forget: A dual role for sleep oscillations in memory consolidation and forgetting ‎[562 bytes]
452. (hist) ‎Human cortical excitability increases with time awake ‎[562 bytes]
453. (hist) ‎Experience-dependent phase-reversal of hippocampal neuron firing during REM sleep ‎[563 bytes]
454. (hist) ‎REM sleep selectively prunes and maintains new synapses in development and learning ‎[564 bytes]
455. (hist) ‎Sleep contributes to dendritic spine formation and elimination in the developing mouse somatosensory cortex ‎[566 bytes]
456. (hist) ‎Coherence potentials: Loss-less, all-or-none network events in the cortex ‎[573 bytes]
457. (hist) ‎Aging and Adaptation in Infectious Diseases/Session III: Host Pathogen (co)Adaptation, Diversification, and Age ‎[574 bytes]
458. (hist) ‎What is Sleep?/SusanSara ‎[580 bytes]
459. (hist) ‎A Period2 Phosphoswitch Regulates and Temperature Compensates Circadian Period ‎[584 bytes]
460. (hist) ‎Entrainment of the human circadian clock to the natural light-dark cycle ‎[584 bytes]
461. (hist) ‎Population and the Environment: Analytical Demography and Applied Population Ethics/NadiaFarooq ‎[585 bytes]
462. (hist) ‎Population and the Environment: Analytical Demography and Applied Population Ethics/Modeling complex populations - dynamics of age-structured populations ‎[588 bytes]
463. (hist) ‎Mathematical model of the human circadian system with two interacting oscillators. ‎[588 bytes]
464. (hist) ‎Dynamic Multi-System Resilience in Human Aging/Multiscale modeling to help making sense of dynamical multiscale resilience ‎[594 bytes]
465. (hist) ‎Multi-day rhythms modulate seizure risk in epilepsy ‎[594 bytes]
466. (hist) ‎Revisiting spontaneous internal desynchrony using a quantitative model of sleep physiology ‎[594 bytes]
467. (hist) ‎Process-Specific Alliances (PSAs) in Cognitive Neuroscience ‎[596 bytes]
468. (hist) ‎Mammalian sleep dynamics: How diverse features arise from a common physiological framework ‎[599 bytes]
469. (hist) ‎Paradoxical timing of the circadian rhythm of sleep propensity serves to consolidate sleep and wakefulness in humans ‎[602 bytes]
470. (hist) ‎Probabilistic sleep architecture models in patients with and without sleep apnea ‎[603 bytes]
471. (hist) ‎Aging and Adaptation in Infectious Diseases/AndrewPDobson ‎[609 bytes]
472. (hist) ‎Modeling transformations of neurodevelopmental sequences across mammalian species ‎[620 bytes]
473. (hist) ‎Circadian pacemaker interferes with sleep onset at specific times each day: Role in insomnia ‎[621 bytes]
474. (hist) ‎Aging, mortality, and the fast growth trade-off of Schizosaccharomyces pombe ‎[623 bytes]
475. (hist) ‎Intrinsic period and light intensity determine the phase relationship between melatonin and sleep in humans ‎[624 bytes]
476. (hist) ‎Are individual differences in sleep and circadian timing amplified by use of artificial light sources? ‎[626 bytes]
477. (hist) ‎Peak of circadian melatonin rhythm occurs later within the sleep of older subjects ‎[627 bytes]
478. (hist) ‎Hippocampal network oscillations rescue memory consolidation deficits caused by sleep loss ‎[628 bytes]
479. (hist) ‎Quantifying Human Circadian Pacemaker Response to Brief, Extended, and Repeated Light Stimuli over the Phototopic Range ‎[634 bytes]
480. (hist) ‎Input source and strength influences overall firing phase of model hippocampal CA1 pyramidal cells during theta: Relevance to REM sleep reactivation and memory consolidation ‎[635 bytes]
481. (hist) ‎Cholinergic modulation of cognitive processing: Insights drawn from computational models ‎[639 bytes]
482. (hist) ‎An opposite role for tau in circadian rhythms revealed by mathematical modeling ‎[643 bytes]
483. (hist) ‎Homer1a drives homeostatic scaling-down of excitatory synapses during sleep ‎[647 bytes]
484. (hist) ‎Aging in Single-celled Organisms: from Bacteria to the Whole Tree of Life/Bree Aldridge ‎[649 bytes]
485. (hist) ‎Circadian phenotype impacts the brain's resting-state functional connectivity, attentional performance, and sleepiness ‎[662 bytes]
486. (hist) ‎Comparing the Morningness-Eveningness Questionnaire and Munich ChronoType Questionnaire to the dim light melatonin onset ‎[664 bytes]
487. (hist) ‎Antidepressant suppression of non-REM sleep spindles and REM sleep impairs hippocampus-dependent learning while augmenting striatum-dependent learning ‎[667 bytes]
488. (hist) ‎Simulations of light effects on the human circadian pacemaker: Implications for assessment of intrinsic period ‎[672 bytes]
489. (hist) ‎Addition of a non-photic component to a light-based mathematical model of the human circadian pacemaker ‎[674 bytes]
490. (hist) ‎Correlation between genetic regulation of immune responsiveness and host defence against infections and tumours ‎[675 bytes]
491. (hist) ‎Cognitive Regime Shift I - When the Brain Breaks/GeorgeMashour ‎[691 bytes]
492. (hist) ‎Ageing and the circadian and homeostatic regulation of human sleep during forced desynchrony of rest, melatonin and temperature rhythms ‎[694 bytes]
493. (hist) ‎Unstable neurons underlie a stable learned behavior ‎[696 bytes]
494. (hist) ‎Control of Mammalian Circadian Rhythm by CKI -Regulated Proteasome-Mediated PER2 Degradation ‎[696 bytes]
495. (hist) ‎Aging and Adaptation in Infectious Diseases III/Session III: Disease History, Aging, and Complex Time ‎[700 bytes]
496. (hist) ‎Modeling the temporal architecture of rat sleep-wake behavior. ‎[705 bytes]
497. (hist) ‎Cognitive Regime Shift I - When the Brain Breaks/CaterinaGratton ‎[711 bytes]
498. (hist) ‎Exposure to room light before bedtime suppresses melatonin onset and shortens melatonin duration in humans ‎[718 bytes]
499. (hist) ‎Cognitive Regime Shift I - When the Brain Breaks/Consciousness, Cognition, and the Prefrontal Cortex ‎[726 bytes]
500. (hist) ‎Circadian temperature and melatonin rhythms, sleep, and neurobehavioral function in humans living on a 20-h day ‎[726 bytes]

View (previous 50 | next 50) (20 | 50 | 100 | 250 | 500)