Complementary roles of the orbital prefrontal cortex and the perirhinal-entorhinal cortices in an odor-guided delayed-nonmatching-to-sample task.

Otto, Tim; Eichenbaum, Howard

doi:10.1037/0735-7044.106.5.762

Cited by 373 publications

(324 citation statements)

References 75 publications

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“…Supporting evidence is based on the findings that lesions of the AI/LO cortex produce deficits in working memory for affect based on taste or odor information (DeCoteau et al, 1997;Di Pietro et al, 2004;Otto & Eichenbaum, 1992;Ragozzino & Kesner, 1999). Further support can be found in a study where sustained neuronal firing was observed in the AI/LO cortex during the delay period in a non-matching-to-sample for odors task (Ramus & Eichenbaum, 2000).…”

Section: Working Memory (Short-term Memory)mentioning

confidence: 89%

“…Based on the empirical findings that all sensory inputs are processed by the DG subregion of the hippocampus ( (Aggleton, Hunt, & Rawlins, 1986;Jackson-Smith et al, 1993;Kesner et al, 1993;Mumby, Wood, & Pinel, 1992;Otto & Eichenbaum, 1992), it has been suggested that a possible role for the hippocampus might be to provide for sensory markers to demarcate a spatial location, so that the hippocampus can more efficiently mediate spatial information. It is thus possible that one of the main process functions of the hippocampus is to encode and separate spatial events from each other.…”

Section: Pattern Separation --Spatial Attributementioning

confidence: 99%

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Neurobiological foundations of an attribute model of memory

Kesner¹

2013

CCBR

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Memory is a complex phenomenon due to a large number of potential interactions that are associated with the organization of memory at the psychological and neural system level. In this review article a tripartite, multiple attribute, multiple process memory model with different forms of memory and its neurobiological underpinnings is represented in terms of the nature, structure or content of information representation as a set of different attributes including language, time, place, response, reward value (affect) and visual object as an example of sensory-perception. For each attribute, information is processed in the event-based, knowledge-based, and rule-based memory systems through multiple operations that involve multiple neural underpinnings. Of the many processes associated with the event-based memory system, the emphasis will be placed on short-term or working memory and pattern separation. Of the many processes associated with the knowledgebased memory system, the emphasis will be placed on perceptual processes. Of the many processes associated with the rule-based memory system the emphasis will be on short-term or working memory and paired associate learning. For all three systems data will be presented to demonstrate differential neuroanatomical mediation and where available parallel results will be presented in rodents, monkeys and humans.

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Section: Working Memory (Short-term Memory)mentioning

confidence: 89%

Section: Pattern Separation --Spatial Attributementioning

confidence: 99%

Neurobiological foundations of an attribute model of memory

Kesner¹

2013

CCBR

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“…Suzuki, Miller, and Desimone (1997) extended this result to demonstrate that this stimulus-specific firing persisted across multiple intervening stimuli. Buffalo, Reber, and Squire (1998) showed that people with lesions to the perirhinal cortex showed deficits of recognition memory over delays as short as 6 s. Mumby and Pinel (1994) showed that rats with damage to entorhinal and perirhinal cortex were impaired on delayed non-match to sample (DNMS) of trial-unique object at delays as short as 15 s. Otto and Eichenbaum (1992) showed no deficit in a continuous delayed non-match task from fornix transection, but showed a deficit from combined perirhinal/entorhinal lesions at delays of 30 s. This not only points to a role for the parahippocampal regions in memory on the time scale of the recency effect in free recall, but argues against a role of the hippocampus in such processes. Murray and Mishkin (1998), showed that lesions to the amygdala and hippocampus that spared rhinal cortex did not have an effect on DNMS performance, whereas a comparable study showed a severe impairment from rhinal cortex lesions at delays as short as tens of seconds (Meunier, Bachevalier, Mishkin, & Murray, 1993 The first suggestion comes from the finding that hippocampal damage is associated with a disruption of memory for items from the early part of the serial position curve.…”

Section: The Context T a Imentioning

confidence: 99%

The Temporal Context Model in Spatial Navigation and Relational Learning: Toward a Common Explanation of Medial Temporal Lobe Function Across Domains.

Howard¹,

Fotedar²,

Datey³

et al. 2005

Psychological Review

272

334

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The medial temporal lobe (MTL) has been studied extensively at all levels of analysis, yet its function remains unclear. Theory regarding the cognitive function of the MTL has centered along 3 themes. Different authors have emphasized the role of the MTL in episodic recall, spatial navigation, or relational memory. Starting with the temporal context model (M. W. Howard and M. J. , a distributed memory model that has been applied to benchmark data from episodic recall tasks, the authors propose that the entorhinal cortex supports a gradually changing representation of temporal context and the hippocampus proper enables retrieval of these contextual states. Simulation studies show this hypothesis explains the firing of place cells in the entorhinal cortex and the behavioral effects of hippocampal lesion in relational memory tasks. These results constitute a first step towards a unified computational theory of MTL function that integrates neurophysiological, neuropsychological and cognitive findings.The medial temporal lobe (MTL) is a region that includes the hippocampus proper, the subicular complex and parahippocampal cortical regions, including entorhinal, perirhinal, and parahippocampal/postrhinal cortices. A great deal of data from neuropsychology (e.g. Eichenbaum & Cohen, 2001;Scoville & Milner, 1957;Squire, 1992) and functional imaging (e.g. Fernandez, Effern, Grunwald, et al., 1999;Stern, Corkin, Gonzalez, et al., 1996;Wagner et al., 1998) has converged on the idea that the MTL is important in learning and memory. In order to bridge the gap between cognition and cellular-level physiology, we need a mechanistic, mesoscopic description of MTL computational function. We already have several successful verbally-formulated theories of the cognitive function of the MTL. These are described in turn in the following subsections. This paper will attempt to draw these multiple verbal theories together into a single computational framework that is consistent with known neurophysiological and neuroanatomical data.

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“…Given the important role of the entorhinal, perirhinal, and parahippocampal cortices in conveying sensory information to and from the hippocampal formation, it is not surprising that damage to these regions produces a memory impairment in monkeys (Murray and Mishkin, 1986;Zola-Morgan et al, 1989b;Gaffan and Murray, 1992;Suzuki et al, 1993) and rats (Otto and Eichenbaum, 1992). In monkeys, bilateral lesions limited to the perirhinal and parahippocampal cortices (the PRPH lesion) produce a severe anterograde memory impairment that resembles human amnesia.…”

mentioning

confidence: 99%

Topographic organization of the reciprocal connections between the monkey entorhinal cortex and the perirhinal and parahippocampal cortices

1994

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The perirhinal and parahippocampal cortices constitute the major sources of cortical input to the monkey entorhinal cortex. Neuropsychological studies have shown that these three cortical regions contribute in an important way to normal memory function. We have investigated the topographic and laminar organization of the reciprocal projections between the entorhinal cortex and these two adjacent cortical areas by placing anterograde and retrograde tracers in all three regions. There were three major findings. First, the perirhinal and parahippocampal cortices have distinct but partially overlapping interconnections with the entorhinal cortex. The perirhinal cortex tends to be interconnected with the rostral two-thirds of the entorhinal cortex while the parahippocampal cortex tends to be interconnected with approximately the caudal two-thirds of the entorhinal cortex. Second, the degree of reciprocity of the interconnections of the entorhinal cortex with the perirhinal and parahippocampal cortices differs. The parahippocampal/entorhinal connections have a high degree of reciprocity. In contrast, the degree of reciprocity of the perirhinal/entorhinal interconnections varies depending on the mediolateral position within the perirhinal cortex; medial portions of the perirhinal cortex exhibit a higher degree of reciprocity with the entorhinal cortex than lateral portions. Third, the projections from the perirhinal and parahippocampal cortices to the entorhinal cortex resemble a feedforward projection, while the projections from the entorhinal cortex to the perirhinal and parahippocampal cortices resemble a feedback projection pattern.

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Complementary roles of the orbital prefrontal cortex and the perirhinal-entorhinal cortices in an odor-guided delayed-nonmatching-to-sample task.

Cited by 373 publications

References 75 publications

Neurobiological foundations of an attribute model of memory

Neurobiological foundations of an attribute model of memory

The Temporal Context Model in Spatial Navigation and Relational Learning: Toward a Common Explanation of Medial Temporal Lobe Function Across Domains.

Topographic organization of the reciprocal connections between the monkey entorhinal cortex and the perirhinal and parahippocampal cortices

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