perirhinal cortex
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2022 ◽  
Vol 15 ◽  
Author(s):  
Nithya Sethumadhavan ◽  
Christina Strauch ◽  
Thu-Huong Hoang ◽  
Denise Manahan-Vaughan

The perirhinal cortex (PRC), subdivided into areas 35 and 36, belongs to the parahippocampal regions that provide polysensory input to the hippocampus. Efferent and afferent connections along its rostro-caudal axis, and of areas 35 and 36, are extremely diverse. Correspondingly functional tasks in which the PRC participates are manifold. The PRC engages, for example, in sensory information processing, object recognition, and attentional processes. It was previously reported that layer II of the caudal area 35 may be critically involved in the encoding of large-scale objects. In the present study we aimed to disambiguate the roles of the different PRC layers, along with areas 35 and 36, and the rostro-caudal compartments of the PRC, in processing information about objects of different dimensions. Here, we compared effects on information encoding triggered by learning about subtle and discretely visible (microscale) object information and overt, highly visible landmark (macroscale) information. To this end, nuclear expression of the immediate early gene Arc was evaluated using fluorescence in situ hybridization. Increased nuclear Arc expression occurred in layers III and V-VI of the middle and caudal parts of area 35 in response to both novel microscale and macroscale object exposure. By contrast, a significant increase in Arc expression occurred in area 36 only in response to microscale objects. These results indicate that area 36 is specifically involved in the encoding of small and less prominently visible items. In contrast, area 35 engages globally (layer III to VI) in the encoding of object information independent of item dimensions.


2022 ◽  
Vol 416 ◽  
pp. 113573
Author(s):  
Che Jiang ◽  
Xiaona Wu ◽  
Jiajia Wang ◽  
Chunyong Li ◽  
Gaoquan Luo

2021 ◽  
Author(s):  
◽  
Susan Adele Welsh

<p>Kappa opioid peptide receptors (KOPrs) are a class of opioid receptors which shown analgesic and anti-addictive properties. Nonaddictive analgesics would be beneficial as morphine, one of the most commonly prescribed opioids for chronic pain, activates the brain reward system and can lead to addiction. Although medical research is progressing rapidly, there is still no treatment for psychostimulant abuse. KOPr agonists show promise in this regard but display undesirable side effects and could negatively affect memory. Salvinorin A (Sal A), a structurally unusual KOPr agonist, has a reduced side effect profile compared to the more traditional KOPr agonists such as U50,488. The effect of Sal A and U50,488 on memory is controversial as they have both been shown to induce a memory impairment and also to improve memory impairments. Sal A also has a poor pharmacokinetic profile with a short duration of action. Structural analogues of Sal A have improved pharmacokinetic and side effect profiles compared to Sal A yet retain the analgesic and anti-addiction properties. This thesis will investigate whether Sal A analogues, namely Ethynyl Sal A (Ethy Sal A), Mesyl Salvinorin B (Mesyl Sal B), and Bromo Salvinorin A (Bromo Sal A), produce a memory impairment.  Male Sprague-Dawley rats were evaluated in the novel object recognition (NOR) task to determine whether novel Sal A analogues impair long term recognition memory. The degree of novelty was also investigated on a cellular basis through quantifying c-Fos immunoreactive neurons within the perirhinal cortex, an area of the brain shown to respond to novelty.  Acute administration of Sal A (0.3 and 1 mg/kg) and novel analogues Ethy Sal A (0.3 and 1 mg/kg), Mesyl Sal B (0.3 and 1 mg/kg), and Bromo Sal A (1 mg/kg) showed no significant differences compared to vehicle when tested in the NOR task. The prototypical KOPr agonist, U50,488 (10 mg/kg), produced a significant decrease in recognition index compared to vehicle when tested in the same task as the novel analogues. Correlating the recognition indices calculated from U50,488 in the NOR to c-Fos counts in the perirhinal cortex showed a strong positive correlation with an increase in RI relating to an increase in c-Fos activation. U50,488 (10 mg/kg) showed a non-significant trend compared to vehicle in the number of c-Fos immunoreactive cells within the perirhinal cortex.  Neither Sal A nor novel analogues affected NOR, suggesting no impairment of long term recognition memory. The lack of this side-effect, among others, demonstrates that the development of potent KOPr agonists with reduced side-effect profiles is feasible. These novel analogues show improvement over the traditional KOPr agonists.</p>


2021 ◽  
Author(s):  
◽  
Susan Adele Welsh

<p>Kappa opioid peptide receptors (KOPrs) are a class of opioid receptors which shown analgesic and anti-addictive properties. Nonaddictive analgesics would be beneficial as morphine, one of the most commonly prescribed opioids for chronic pain, activates the brain reward system and can lead to addiction. Although medical research is progressing rapidly, there is still no treatment for psychostimulant abuse. KOPr agonists show promise in this regard but display undesirable side effects and could negatively affect memory. Salvinorin A (Sal A), a structurally unusual KOPr agonist, has a reduced side effect profile compared to the more traditional KOPr agonists such as U50,488. The effect of Sal A and U50,488 on memory is controversial as they have both been shown to induce a memory impairment and also to improve memory impairments. Sal A also has a poor pharmacokinetic profile with a short duration of action. Structural analogues of Sal A have improved pharmacokinetic and side effect profiles compared to Sal A yet retain the analgesic and anti-addiction properties. This thesis will investigate whether Sal A analogues, namely Ethynyl Sal A (Ethy Sal A), Mesyl Salvinorin B (Mesyl Sal B), and Bromo Salvinorin A (Bromo Sal A), produce a memory impairment.  Male Sprague-Dawley rats were evaluated in the novel object recognition (NOR) task to determine whether novel Sal A analogues impair long term recognition memory. The degree of novelty was also investigated on a cellular basis through quantifying c-Fos immunoreactive neurons within the perirhinal cortex, an area of the brain shown to respond to novelty.  Acute administration of Sal A (0.3 and 1 mg/kg) and novel analogues Ethy Sal A (0.3 and 1 mg/kg), Mesyl Sal B (0.3 and 1 mg/kg), and Bromo Sal A (1 mg/kg) showed no significant differences compared to vehicle when tested in the NOR task. The prototypical KOPr agonist, U50,488 (10 mg/kg), produced a significant decrease in recognition index compared to vehicle when tested in the same task as the novel analogues. Correlating the recognition indices calculated from U50,488 in the NOR to c-Fos counts in the perirhinal cortex showed a strong positive correlation with an increase in RI relating to an increase in c-Fos activation. U50,488 (10 mg/kg) showed a non-significant trend compared to vehicle in the number of c-Fos immunoreactive cells within the perirhinal cortex.  Neither Sal A nor novel analogues affected NOR, suggesting no impairment of long term recognition memory. The lack of this side-effect, among others, demonstrates that the development of potent KOPr agonists with reduced side-effect profiles is feasible. These novel analogues show improvement over the traditional KOPr agonists.</p>


2021 ◽  
Vol 15 ◽  
Author(s):  
Maximiliano José Nigro ◽  
Hinako Kirikae ◽  
Kasper Kjelsberg ◽  
Rajeevkumar Raveendran Nair ◽  
Menno P. Witter

The wide diversity of cortical inhibitory neuron types populating the cortex allows the assembly of diverse microcircuits and endows these circuits with different computational properties. Thus, characterizing neuronal diversity is fundamental to describe the building blocks of cortical microcircuits and probe their function. To this purpose, the mouse has emerged as a powerful tool to genetically label and manipulate specific inhibitory cell-types in the mammalian brain. Among these cell-types, the parvalbumin-expressing interneuron type (PV-INs) is perhaps the most characterized. Several mouse lines have been generated to target PV-INs. Among these mouse lines, the PV-IRES-Cre lines is the most widely used and demonstrated a high specificity and efficiency in targeting PV-INs in different cortical areas. However, a characterization of the performance across cortical regions is still missing. Here we show that the PV-IRES-Cre mouse line labels only a fraction of PV immunoreactive neurons in perirhinal cortex and other association areas. Our results point to a yet uncharacterized diversity within the PV-INs and emphasize the need to characterize these tools in specific cortical areas.


2021 ◽  
Vol 28 (11) ◽  
pp. 405-413
Author(s):  
Elizabeth H. Shepherd ◽  
Neil M. Fournier ◽  
Robert J. Sutherland ◽  
Hugo Lehmann

Damage to the hippocampus (HPC) typically causes retrograde amnesia for contextual fear conditioning. Repeating the conditioning over several sessions, however, can eliminate the retrograde amnesic effects. This form of reinstatement thus permits modifications to networks that can support context memory retrieval in the absence of the HPC. The present study aims to identify cortical regions that support the nonHPC context memory. Specifically, the contribution of the perirhinal cortex (PRH) and the anterior cingulate cortex (ACC) were examined because of their established importance to context memory. The findings show that context memories established through distributed reinstatement survive damage limited only to the HPC, PRH, or ACC. Combined lesions of the HPC and PRH, as well as the HPC and ACC, caused retrograde amnesia, suggesting that network modifications in the PRH and ACC enable context fear memories to become resistant to HPC damage.


2021 ◽  
Author(s):  
Athula Pudhiyidath ◽  
Neal W Morton ◽  
Rodrigo Viveros Duran ◽  
Anna C. Schapiro ◽  
Ida Momennejad ◽  
...  

AbstractOur understanding of the world is shaped by inferences about underlying structure. For example, at the gym, you might notice that the same people tend to arrive around the same time and infer that they are friends that work out together. Consistent with this idea, after participants are presented with a temporal sequence of objects that follows an underlying community structure, they are biased to infer that objects from the same community share the same properties. Here, we used fMRI to measure neural representations of objects after temporal community structure learning and examine how these representations support inference about object relationships. We found that community structure learning affected inferred object similarity: when asked to spatially group items based on their experience, participants tended to group together objects from the same community. Neural representations in perirhinal cortex predicted individual differences in object grouping, suggesting that high-level object representations are affected by temporal community learning. Furthermore, participants were biased to infer that objects from the same community would share the same properties. Using computational modeling of temporal learning and inference decisions, we found that inductive reasoning is influenced by both detailed knowledge of temporal statistics and abstract knowledge of the temporal communities. The fidelity of temporal community representations in hippocampus and precuneus predicted the degree to which temporal community membership biased reasoning decisions. Our results suggest that temporal knowledge is represented at multiple levels of abstraction, and that perirhinal cortex, hippocampus, and precuneus may support inference based on this knowledge.


2021 ◽  
pp. 174702182110549
Author(s):  
Jasper Robinson ◽  
Peter M Jones ◽  
Emma Whitt

We report findings from two sensory preconditioning experiments in which rats consumed two flavoured solutions, each with two gustatory components (AX and BY), composed of sweet, bitter, salt and acid elements. After this pre-exposure, rats were conditioned to X by pairing with lithium chloride. Standard sensory preconditioning was observed: Consumption of flavour A was less than that of B. We found that sensory preconditioning was maintained when X was added to A and B. Both experiments included one group of rats with lesions of the perirhinal cortex, which did not influence sensory preconditioning. We discuss our findings in the light of other sensory preconditioning procedures that do involve the perirhinal cortex and conclude that differences in experimental variables invoke different mechanisms of sensory preconditioning, which vary in their requirement of the perirhinal cortex.


2021 ◽  
Author(s):  
Maximiliano Jose Nigro ◽  
Hinako Kirikae ◽  
Kasper Kjelsberg ◽  
Rajeevkumar Nair Raveendran ◽  
Menno Witter

The wide diversity of cortical inhibitory neuron types populating the cortex allows the assembly of diverse microcircuits and endows these circuits with different computational properties. Thus, characterizing neuronal diversity is fundamental to describe the building blocks of cortical microcircuits and probe their function. To this purpose, the mouse has emerged as a powerful tool to genetically label and manipulate specific inhibitory cell-types in the mammalian brain. Among these cell-types, the parvalbumin-expressing interneuron type (PV-INs) is perhaps the most characterized. Several mouse lines have been generated to target PV-INs. Among these mouse lines, the PV-IRES-Cre lines is the most widely used and demonstrated a high specificity and efficiency in targeting PV-INs in different cortical areas. However, a characterization of the performance across cortical regions is still missing. Here we show that the PV-IRES-Cre mouse line labels only a fraction of parvalbumin immunoreactive neurons in perirhinal cortex and other association areas. Our results point to a yet uncharacterized diversity within the PV-INs and emphasize the need to characterize these tools in specific cortical areas.


2021 ◽  
Vol 15 ◽  
Author(s):  
Noemi Binini ◽  
Francesca Talpo ◽  
Paolo Spaiardi ◽  
Claudia Maniezzi ◽  
Matteo Pedrazzoli ◽  
...  

The perirhinal cortex (PRC) is a polymodal associative region of the temporal lobe that works as a gateway between cortical areas and hippocampus. In recent years, an increasing interest arose in the role played by the PRC in learning and memory processes, such as object recognition memory, in contrast with certain forms of hippocampus-dependent spatial and episodic memory. The integrative properties of the PRC should provide all necessary resources to select and enhance the information to be propagated to and from the hippocampus. Among these properties, we explore in this paper the ability of the PRC neurons to amplify the output voltage to current input at selected frequencies, known as membrane resonance. Within cerebral circuits the resonance of a neuron operates as a filter toward inputs signals at certain frequencies to coordinate network activity in the brain by affecting the rate of neuronal firing and the precision of spike timing. Furthermore, the ability of the PRC neurons to resonate could have a fundamental role in generating subthreshold oscillations and in the selection of cortical inputs directed to the hippocampus. Here, performing whole-cell patch-clamp recordings from perirhinal pyramidal neurons and GABAergic interneurons of GAD67-GFP+ mice, we found, for the first time, that the majority of PRC neurons are resonant at their resting potential, with a resonance frequency of 0.5–1.5 Hz at 23°C and of 1.5–2.8 Hz at 36°C. In the presence of ZD7288 (blocker of HCN channels) resonance was abolished in both pyramidal neurons and interneurons, suggesting that Ih current is critically involved in resonance generation. Otherwise, application of TTx (voltage-dependent Na+ channel blocker) attenuates the resonance in pyramidal neurons but not in interneurons, suggesting that only in pyramidal neurons the persistent sodium current has an amplifying effect. These experimental results have also been confirmed by a computational model. From a functional point of view, the resonance in the PRC would affect the reverberating activity between neocortex and hippocampus, especially during slow wave sleep, and could be involved in the redistribution and strengthening of memory representation in cortical regions.


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