Memory Representation within the Parahippocampal Region

Young, Brian J.; Otto, Tim; Fox, Gregory D.; Eichenbaum, Howard

doi:10.1523/jneurosci.17-13-05183.1997

Cited by 332 publications

(331 citation statements)

References 65 publications

(74 reference statements)

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“…This discrepancy probably stems from a combination of MR technical (Kaza et al 2011;Ojemann 1997Ojemann , 2010 issues combined with local anatomic-physiologic characteristics of odor processing in the entorhinal cortex. In rats entorhinal neurons display odor selectivity (Young et al 1997), and thus both inter-and intraindividual activity to the identified odors may differ, thus contributing to a limited area of activation in the third level group analysis, although activity for each individual was high, as shown in the functional and anatomic entorhinal ROI analyses. These findings provide direct evidence for the proposed connection between entorhinal pathol- The model for spontaneous identified vs. nonidentified odors was event-related.…”

Section: Discussionmentioning

confidence: 98%

The human brain representation of odor identification

Kjelvik

Evensmoen

Brezova

et al. 2012

Journal of Neurophysiology

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Section: Discussionmentioning

confidence: 98%

The human brain representation of odor identification

Kjelvik

Evensmoen

Brezova

et al. 2012

Journal of Neurophysiology

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“…Although we did not establish a contribution of hippocampal CCK, the Fos analysis suggests that CA1 neurons contribute to the expression of associative morphine tolerance. The hippocampus seems to serve as a locus for memory consolidation and to perform the match-mismatch discriminations necessary for memory recognition 46 . Moreover, there are direct, reciprocal connections between the hippocampus and L/BL amygdala 47,48 .…”

Section: Discussionmentioning

confidence: 99%

A locus and mechanism of action for associative morphine tolerance

2000

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Repeated administration of an opioid in the presence of specific environmental cues can induce tolerance specific to that setting (associative tolerance). Prolonged or repeated administration of an opioid without consistent contextual pairing yields non-associative tolerance. Here we demonstrate that cholecystokinin acting at the cholecystokinin-B receptor is required for associative but not non-associative morphine tolerance. Morphine given in the morphineassociated context increased Fos-like immunoreactivity in the lateral amygdala and hippocampal area CA1. Microinjection of the cholecystokinin B antagonist L-365,260 into the amygdala blocked associative tolerance. These results indicate that cholecystokinin acting in the amygdala is necessary for associative tolerance to morphine's analgesic effect.The role of cholecystokinin (CCK) as an anti-opioid peptide is firmly established. CCK suppresses the analgesic effect of morphine and other μ-opioid receptor agonists 1,2 . CCK antagonists potentiate the analgesic effects of exogenous and endogenous μ-opioid receptor agonists 3-8 and enhance the inhibitory effect of morphine on nociceptive dorsal horn neurons 9,10 . Additionally, CCK antagonists impede the acquisition of morphine tolerance yet have no effect on morphine dependence or withdrawal 3,[11][12][13][14][15][16] . Although CCK antagonists potentiate the effects of opioids, they do not alter nociceptive threshold levels when administered independently 8,16 . There are two distinct CCK receptors (CCK-A and CCK-B) in the CNS [17][18][19][20] .Learning can contribute to drug tolerance [21][22][23][24][25][26][27] . When morphine administration is paired with specific environmental cues, these cues can act as conditioned stimuli that elicit a conditioned response opposing the agonist effect of morphine (associative tolerance). Although associative analgesic tolerance following repeated opioid administration is well established, the underlying neurobiological mechanisms are unknown.

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“…Rats with perirhinal-entorhinal lesions were found to be impaired in an olfactory recognition memory tasks (Kaut and Bunsey, 2001;Kaut et al, 2003). Electrophysiological recordings during delayed non-matching tasks also show a role for the perirhinal cortex (Young et al, 1997) and prefrontal cortex (Ramus and Eichenbaum, 2000) in olfactory discrimination. Bearing in mind the anatomical connections between the perirhinal cortex and olfactory regions (see Section 3.2) and that many object recognition studies in rats rely on nose contact as a measure of exploration, it is surprising that more attention has not been focussed on the role of the perirhinal cortex in olfactory recognition memory.…”

Section: Object Recognition Memorymentioning

confidence: 91%

“…3a; Swanson and Cowan, 1977;Wyss, 1981;Kosel et al, 1982Kosel et al, , 1983Deacon et al, 1983;Kö hler, 1988;Van Groen and Wyss, 1990;Insausti et al, 1997;Burwell and Amaral, 1998a,b;Shi and Cassell, 1999;Kloosterman et al, 2003b). Based on anatomical (Witter et al, 2000b;Witter, 2002), electrophysiological (Young et al, 1997;Ivanco and Racine, 2000;Naber et al, 1997Naber et al, , 1999Naber et al, , 2001a and functional evidence (Bussey et al, 2000;Wan et al, 2001;Burwell et al, 2004a,b;Jenkins et al, 2004;Amin et al, 2006;Albasser et al, 2010;Romero-Granados et al, 2010), the hippocampal-parahippocampal region of the brain has been implicated in several aspects of learning and memory. The role of the perirhinal cortex in this hippocampal-parahippocampal network has been traditionally seen as a gateway for sensory information into the hippocampus via the entorhinal cortex (Witter et al, 2000a,b) but, as discussed below, the current evidence does not fully support this model but points to a more complex relationship between the hippocampal-parahippocampal regions.…”

Section: Hippocampal and Parahippocampal Projectionsmentioning

confidence: 99%