Your search keyword '"Inostroza, Marion"' showing total 4 results

1. Unfolding of spatial representation at systems level in infant rats.

Author

Xia Shan, Contreras, María P., Mendez, Marta, Born, Jan, and Inostroza, Marion

Subjects

SPATIAL systems, DENTATE gyrus, INFANTS, PREFRONTAL cortex, HABITUATION (Neuropsychology)

Abstract

Spatial representations enable navigation from early life on. However, the brain regions essential to form spatial representations, like the hippocampus, are considered functionally immature before weaning. Here, we examined the formation of representations of space in rat pups on postnatal day (PD) 16, using a simple habituation paradigm where the pups were exposed to an arena on three occasions, separated by -140 min. Whereas on the first two occasions the arena was the same, on the third "test" occasion either proximal cues (Prox group), or distal cues (Dist group), or proximal and distal cues (Prox-Dist group), or no cues (No-change group) were rearranged. Locomotion (distance traveled) was used as behavioral measure of habituation, and c-Fos expression to measure regional brain activity at test. Locomotion generally decreased across the first two occasions. At test, it reached a minimum in the No-change group, indicating familiarity with the spatial conditions. By contrast, the Prox-Dist group displayed a significant increase in locomotion which was less robust in the Prox group and absent in the Dist group, a pattern suggesting that the pups relied more on proximal than distal cues during spatial exploration. c-Fos activity in the No-change group was significantly suppressed in the hippocampus (CA1, CA3, dentate gyrus) but simultaneously enhanced in the prelimbic area (PL) of the medial prefrontal cortex, compared with untreated Home-cage controls, pointing to a possible involvement of the PL in regulating locomotion in familiar spaces. By contrast, in both Prox-Dist and Prox groups c-Fos activity was enhanced in hippocampal CA1 and CA3 regions, suggesting these regions might be particularly involved in regulating exploration of spatial novelty. Our findings show that functional representations of space at a systems level are formed already in pre-weanling rats. [ABSTRACT FROM AUTHOR]

Published

2022

2. Temporal associations between sleep slow oscillations, spindles and ripples.

Author

Oyanedel, Carlos N., Durán, Ernesto, Niethard, Niels, Inostroza, Marion, and Born, Jan

Subjects

SLOW wave sleep, OSCILLATIONS, PREFRONTAL cortex, THALAMUS, HIPPOCAMPUS (Brain)

Abstract

The systems consolidation of memory during slow‐wave sleep (SWS) is thought to rely on a dialogue between hippocampus and neocortex that is regulated by an interaction between neocortical slow oscillations (SOs), thalamic spindles and hippocampal ripples. Here, we examined the occurrence rates of and the temporal relationships between these oscillatory events in rats, to identify the possible direction of interaction between these events under natural conditions. To facilitate comparisons with findings in humans, we combined frontal and parietal surface EEG with local field potential (LFP) recordings in medial prefrontal cortex (mPFC) and dorsal hippocampus (dHC). Consistent with a top‐down driving influence, EEG SO upstates were associated with an increase in spindles and hippocampal ripples. This increase was missing in SO upstates identified in mPFC recordings. Ripples in dHC recordings always followed the onset of spindles consistent with spindles timing ripple occurrence. Comparing ripple activity during co‐occurring SO‐spindle events with that during isolated SOs or spindles, suggested that ripple dynamics during SO‐spindle events are mainly determined by the spindle, with only the SO downstate providing a global inhibitory signal to both thalamus and hippocampus. As to bottom‐up influences, we found an increase in hippocampal ripples ~200 ms before the SO downstate, but no similar increase of spindles preceding SO downstates. Overall, the temporal pattern is consistent with a loop‐like scenario where, top‐down, SOs can trigger thalamic spindles which, in turn, regulate the occurrence of hippocampal ripples. Ripples, bottom‐up, and independent from thalamic spindles, can contribute to the emergence of neocortical SOs. [ABSTRACT FROM AUTHOR]

Published

2020

3. More Effective Consolidation of Episodic Long-Term Memory in Children Than Adults-Unrelated to Sleep.

Author

Wang, Jing‐Yi, Weber, Frederik D., Zinke, Katharina, Inostroza, Marion, Born, Jan, and Wang, Jing-Yi

Subjects

LONG-term memory in children, AGE factors in sleep, CHILDREN & sleep, TEENAGERS & sleep, MEMORY bias, NAPS (Sleep) -- Physiological aspects, SLEEP-wake cycle, EPISODIC memory

Abstract

Abilities to encode and remember events in their spatiotemporal context (episodic memory) rely on brain regions that mature late during childhood and are supported by sleep. We compared the temporal dynamics of episodic memory formation and the role of sleep in this process between 62 children (8-12 years) and 57 adults (18-37 years). Subjects recalled "what-where-when" memories after a short 1-hr retention interval or after a long 10.5-hr interval containing either nocturnal sleep or daytime wakefulness. Although children showed diminished recall of episodes after 1 hr, possibly resulting from inferior encoding, unlike adults, they showed no further decrease in recall after 10.5 hr. In both age groups, episodic memory benefitted from sleep. However, children's more effective offline retention was unrelated to sleep. [ABSTRACT FROM AUTHOR]

Published

2018

4. Hippocampal corticosterone impairs memory consolidation during sleep but improves consolidation in the wake state.

Author

Kelemen, Eduard, Bahrendt, Marie, Born, Jan, and Inostroza, Marion

Abstract

ABSTRACT We studied the interaction between glucocorticoid (GC) level and sleep/wake state during memory consolidation. Recent research has accumulated evidence that sleep supports memory consolidation in a unique physiological process, qualitatively distinct from consolidation occurring during wakefulness. This appears particularly true for memories that rely on the hippocampus, a region with abundant expression of GC receptors. Against this backdrop we hypothesized that GC effects on consolidation depend on the brain state, i.e., sleep and wakefulness. Following exploration of two objects in an open field, during 80 min retention periods rats received an intrahippocampal infusion of corticosterone (10 ng) or vehicle while asleep or awake. Then the memory was tested in the hippocampus-dependent object-place recognition paradigm. GCs impaired memory consolidation when administered during sleep but improved consolidation during the wake retention interval. Intrahippocampal infusion of GC or sleep/wake manipulations did not alter novel-object recognition performance that does not require the hippocampus. This work corroborates the notion of distinct consolidation processes occurring in sleep and wakefulnesss, and identifies GCs as a key player controlling distinct hippocampal memory consolidation processes in sleep and wake conditions. © 2014 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014