Detailed analysis of the behavior of Lister and Wistar rats in anxiety, object recognition and object location tasks

The present study, examines some issues in the measure and analysis of behavior in animals. Two strains of rats of both genders were used to illustrate and discuss these issues. We examined to what extent various behavioral measures reflect different or identical emotional or cognitive factors and, how sensitive are the various parameters of a task to differences between strains and genders. Wistar and Lister males and females rats were tested in an anxiety test then in the object recognition task followed by the object location task. Taking advantage of a simple computer program it is possible to: (1) record several parameters of theses tasks and examine the pattern of animal responses toward novelty and/or familiarity; (2) examine whether different measurements of the same response would reflect anxiety response to novelty and, can they discriminate between novelty and familiarity responses to objects; and (3) examine if changes in the pattern of animal responses are reflected by these measurements and, whether anxiety or discrimination is evident mainly during the first minute of the test. The results on the anxiety test show that different measures of the same response proved concordant and revealed significant differences between Lister males and Wistar males. Lister males approached more frequently an object and spent more time on an object in each approach compared to Wistar males in the first 5 min of test and in the total 10 min. They have also shorter latencies between approaches compared to Wistar males. The examination of performance over different time bins was significant with the measure of frequency. Lister male rats approached less frequently the object in the last 5 min of the test compared to the first 5 min. Their performance, however, did not differ from that of the other groups in this last 5 min. In the memory tasks, the measure of the frequency of approaches suggests that Lister male rats were able to discriminate between novel and familiar objects and, between novel and familiar location of objects. The measure of latency of first approach shows that Wistar female rats were able to discriminate between objects only in the spatial memory test. Discrimination in the object recognition task was observed in the first and second minute, and in the total 3 min sessions. Discrimination in the object location task was observed with the measure of frequency of approaches, in the first minute, and in the total 3 min sessions. Results from the total 3 min sessions were more concordant between the different measures of discrimination than results from separate 1 min bins. The results from the two memory tasks show that novelty prevented habituation to re-exposure to the testing environment. In many cases, novelty increased exploration of the objects in the choice phase compared to the sample phase. However, this lack of habituation or increased exploration in the choice phase is not concordant with most results of discrimination between novelty and familiarity from the same type of measurements.     

Early age‐dependent impairments of context‐dependent extinction learning,object recognition,and object‐place learning occur in rats

The hippocampus is vulnerable to age‐dependent memory decline. Multiple forms of memory depend on adequate hippocampal function. Extinction learning comprises active inhibition of no longer relevant learned information concurrent with suppression of a previously learned reaction. It is highly dependent on context, and evidence exists that it requires hippocampal activation. In this study, we addressed whether context‐based extinction as well as hippocampus‐dependent tasks, such as object recognition and object‐place recognition, are equally affected by moderate aging. Young (7‐8 week old) and older (7‐8 month old) Wistar rats were used. For the extinction study, animals learned that a particular floor context indicated that they should turn into one specific arm (e.g., left) to receive a food reward. On the day after reaching the learning criterion of 80% correct choices, the floor context was changed, no reward was given and animals were expected to extinguish the learned response. Both, young and older rats managed this first extinction trial in the new context with older rats showing a faster extinction performance. One day later, animals were returned to the T‐maze with the original floor context and renewal effects were assessed. In this case, only young but not older rats showed the expected renewal effect (lower extinction ratio as compared to the day before). To assess general memory abilities, animals were tested in the standard object recognition and object‐place memory tasks. Evaluations were made at 5 min, 1 h and 7 day intervals. Object recognition memory was poor at short‐term and intermediate time‐points in older but not young rats. Object‐place memory performance was unaffected at 5 min, but impaired at 1 h in older but not young rats. Both groups were impaired at 7 days. These findings support that not only aspects of general memory, but also context‐dependent extinction learning, are affected by moderate aging. This may reflect less flexibility in revising hard‐wired knowledge or reduced adaptability to new learning challenges. © 2013 Wiley Periodicals, Inc.     

Lateral entorhinal cortex is necessary for associative but not nonassociative recognition memory

The lateral entorhinal cortex (LEC) provides one of the two major input pathways to the hippocampus and has been suggested to process the nonspatial contextual details of episodic memory. Combined with spatial information from the medial entorhinal cortex it is hypothesised that this contextual information is used to form an integrated spatially selective, context‐specific response in the hippocampus that underlies episodic memory. Recently, we reported that the LEC is required for recognition of objects that have been experienced in a specific context (Wilson et al. (2013) Hippocampus 23:352‐366). Here, we sought to extend this work to assess the role of the LEC in recognition of all associative combinations of objects, places and contexts within an episode. Unlike controls, rats with excitotoxic lesions of the LEC showed no evidence of recognizing familiar combinations of object in place, place in context, or object in place and context. However, LEC lesioned rats showed normal recognition of objects and places independently from each other (nonassociative recognition). Together with our previous findings, these data suggest that the LEC is critical for associative recognition memory and may bind together information relating to objects, places, and contexts needed for episodic memory formation. © 2013 The Authors. Hippocampus Published by Wiley Periodicals, Inc.     

Object recognition testing: methodological considerations on exploration and discrimination measures

The object recognition task (ORT) is a popular one-trial learning test for animals. In the current study, we investigated several methodological issues concerning the task. Data was pooled from 28 ORT studies, containing 731 male Wistar rats. We investigated the relationship between 3 common absolute- and relative discrimination measures, as well as their relation to exploratory activity. In this context, the effects of pre-experimental habituation, object familiarity, trial duration, retention interval and the amnesic drugs MK-801 and scopolamine were investigated. Our analyses showed that the ORT is very sensitive, capable of detecting subtle differences in memory (discrimination) and exploratory performance. As a consequence, it is susceptible to potential biases due to (injection) stress and side effects of drugs. Our data indicated that a minimum amount of exploration is required in the sample and test trial for stable significant discrimination performance. However, there was no relationship between the level of exploration in the sample trial and discrimination performance. In addition, the level of exploration in the test trial was positively related to the absolute discrimination measure, whereas this was not the case for relative discrimination measures, which correct for exploratory differences, making them more resistant to exploration biases. Animals appeared to remember object information over multiple test sessions. Therefore, when animals have encountered both objects in prior test sessions, the object preference observed in the test trial of 1h retention intervals is probably due to a relative difference in familiarity between the objects in the test trial, rather than true novelty per se. Taken together, our findings suggest to take into consideration pre-experimental exposure (familiarization) to objects, habituation to treatment procedures, and the use of relative discrimination measures when using the ORT.     

Associative recognition and the hippocampus: Differential effects of hippocampal lesions on object‐place,object‐context and object‐place‐context memory

The hippocampus is thought to be required for the associative recognition of objects together with the spatial or temporal contexts in which they occur. However, recent data showing that rats with fornix lesions perform as well as controls in an object‐place task, while being impaired on an object‐place‐context task (Eacott and Norman ( 2004 ) J Neurosci 24:1948–1953), suggest that not all forms of context‐dependent associative recognition depend on the integrity of the hippocampus. To examine the role of the hippocampus in context‐dependent recognition directly, the present study tested the effects of large, selective, bilateral hippocampus lesions in rats on performance of a series of spontaneous recognition memory tasks: object recognition, object‐place recognition, object‐context recognition and object‐place‐context recognition. Consistent with the effects of fornix lesions, animals with hippocampus lesions were impaired only on the object‐place‐context task. These data confirm that not all forms of context‐dependent associative recognition are mediated by the hippocampus. Subsequent experiments suggested that the object‐place task does not require an allocentric representation of space, which could account for the lack of impairment following hippocampus lesions. Importantly, as the object‐place‐context task has similar spatial requirements, the selective deficit in object‐place‐context recognition suggests that this task requires hippocampus‐dependent neural processes distinct from those required for allocentric spatial memory, or for object memory, object‐place memory or object‐context memory. Two possibilities are that object, place, and context information converge only in the hippocampus, or that recognition of integrated object‐place‐context information requires a hippocampus‐dependent mode of retrieval, such as recollection. © 2009 Wiley‐Liss, Inc.     

The effect of the inter-phase delay interval in the spontaneous object recognition test for pigs

In the neuroscience community interest for using the pig is growing. Several disease models have been developed creating a need for validation of behavioural paradigms in these animals. Here, we report the effect of different inter-phase delay intervals on the performance of G?ttingen minipigs in the spontaneous object recognition test. The test consisted of a sample and a test phase. First, the pigs explored two similar objects. After a 10-min, 1-h, or 24-h delay two different objects were presented; one familiar from the sample phase and one novel. An exploration-time difference between the novel and the familiar object was interpreted as recognition of the familiar object. We scored the exploration times both manually and automatically, and compared the methods. A strong discrimination between novel and familiar objects after a 10-min inter-phase delay interval and no discrimination after 24h were found in our set-up of the spontaneous object recognition test. After a 1-h delay, the pigs still showed a significant habituation to the familiar object, but no discrimination was observed. Discrimination between the two objects was mainly confined to the first half of the test phase, and we observed a high between-subject variation. Furthermore, automatic tracking was valid for determination of habituation and discrimination parameters but lead to an overestimation of individual measurements. We conclude that the spontaneous object recognition test for pigs is sensitive to increasing inter-phase delay intervals, and that automatic data acquisition can be applied.     

Dissociation in retrograde memory for object discriminations and object recognition in rats with perirhinal cortex damage

This experiment examined the effects of perirhinal cortex (PeRh) lesions on rats' retrograde memory for object-discriminations and retrograde object recognition. Rats learned one discrimination problem or five concurrent discrimination problems 4 weeks before surgery, and a new problem or five new problems during the week preceding surgery. Each rat was also familiarized with a sample object in an open field, 5, 3, or 1 week before surgery. PeRh-lesioned rats displayed normal retention of the object discrimination problems, but on a test of novelty preference they showed evidence of impaired recognition of the sample objects. A similar dissociation was observed on anterograde tests of object-discrimination learning and object recognition. The findings suggest the perirhinal cortex plays an essential role in rats' ability to discriminate the familiarity of objects previously encountered either before or after surgery, but this ability may not be essential for accurate performance of a simple object-discrimination task.     

Evidence for age‐related deficits in object‐location binding during place recognition

Deciding whether a place is the same or different than places encountered previously is a common task in daily navigation which requires to develop knowledge about the locations of objects (object‐location binding) and to recognize places from different perspectives. These abilities rely on hippocampal functioning which is susceptible to increasing age. Thus, the question of the present study is how they both together impact on place recognition in aging. Forty people aged 20–29, 44 aged 60–69, and 32 aged 70–79 were presented with places consisting of four different objects during the encoding phase. In the test phase, they were then presented with a second place and had to decide whether it was the same or different. Test places were presented from different perspectives (0°, 30°, 60°) and with different object conditions (same, a swap of two objects, a substitution with a novel object). The sensitivity for detecting changes (d′) decreased from 20–29 to 60–69 and to 70–79 years old, and with increasing perspective shifts. Importantly, older adults were less sensitive to object swapping than to object substitution, while young participants did not show any difference. Overall, these results suggest specific age‐related difficulties in object‐location binding in the context of place recognition.     

Enhanced context-dependency of object recognition in rats with hippocampal lesions

Object recognition memory was assessed on a novel-object preference (NOP) task in rats with lesions of the hippocampal formation (HPC). The learning and test phases of NOP trials occurred in either the same context or in different contexts. When the learning and test contexts were the same, rats with HPC lesions performed like control rats, displaying a significant tendency to investigate a novel object more than a familiar sample object. When the test occurred in a context that was familiar but different from the learning context, performance was unaffected in control rats, but rats with HPC lesions no longer discriminated between the objects, and therefore showed no evidence of recognizing the sample object. When the test context was unfamiliar, novel-object preference in control rats was attenuated but still above chance levels, whereas rats with HPC lesions did not show a preference. The data suggest that the HPC is not critical for encoding or retrieving conjunctive representations of the context in which incidental learning occurs, whereas it plays an essential role in recognition of objects that are subsequently encountered in different contexts.     

Retrograde and anterograde object recognition in rats with hippocampal lesions

Retrograde and anterograde object-recognition memory was assessed in rats with cytotoxic lesions of the hippocampal formation (HPC), using a paradigm based on the natural tendency of rats to spend more time exploring novel objects than familiar objects. The rats were allowed to explore a sample object for 5 min/day on 5 consecutive days, either 5 weeks or 1 week before surgery. After surgery, retrograde recognition was assessed by comparing the amount of time spent exploring the sample versus a novel object in a free-choice situation. Control rats spent more time exploring the novel object than the sample objects from both presurgery time periods, whereas rats with HPC lesions did not discriminate between the novel objects and sample objects from either presurgery time period. Despite their deficits on the retrograde recognition test, the rats with HPC lesions performed like control rats on anterograde recognition tests, displaying a strong exploratory preference for novel objects over sample objects, with retention delays of either 15 min or 24 h. The findings suggest that extrahippocampal circuitry is capable of supporting object recognition, but only if the HPC does not participate in encoding the original encounter with the object.     

A new automated method to assess the rat recognition memory: validation of the method

During the last decade, the rodent object recognition memory task had gained popularity in the field of pharmacological studies, and has been proposed as a useful method to evaluate the efficacy of memory enhancing compounds. In this context, it is important to establish reliable and automated methods with high throughput to evaluate recognition memory in the rat. When performed in a Y-maze apparatus, object recognition has been described to be less dependent on spatial information, and we here report a new method to assess novelty discrimination in a Y-maze apparatus recorded via automated video tracking. During the development of the method, many parameters were recorded and some were selected as being the most reliable, i.e. time spent in the distal half-arms during the first 2 min of the test. The method was then validated under memory deficit conditions produced by a pharmacological treatment (scopolamine) and a long retention delay (72 h) between the sample and the test. The time-induced deficit was prevented by administration of a M1 positive allosteric modulator, BQCA at a dose of 10 mg/kg. Altogether, our data show that the novelty discrimination task performed in a Y-maze apparatus is a reliable method to assess the recognition memory of the rat. This new automated method is as sensitive as the classical object recognition test, and provides advantages such as easily definable parameters and the possibility to use an automated video tracking system that makes the measurement independent of the investigator.     

Retroactive interference of object‐in‐context long‐term memory: Role of dorsal hippocampus and medial prefrontal cortex

Retroactive interference (RI) is a type of amnesia in which a new learning experience can impair the expression of a previous one. It has been studied in several types of memories for over a century. Here, we aimed to study in the long‐term memory (LTM) formation of an object‐in‐context task, defined as the recognition of a familiar object in a context different to that in which it was previously encountered. We trained rats with two sample trials, each taking place in a different context in association with different objects. Test sessions were performed 24 h later, to evaluate LTM for both object‐context pairs using separate groups of trained rats. Furthermore, given the involvement of hippocampus (Hp) and medial prefrontal cortex (mPFC) in several recognition memories, we also analyzed the participation of these structures in the LTM formation of this task by the local infusion of muscimol. Our results show that object‐in‐context LTM formation is sensitive to RI by a different either familiar or novel object‐context pair trial, experienced 1 h later. This interference occurs in a restricted temporal window and works on the LTM consolidation phase, leaving intact short‐term memory expression. The second sample trial did not affect the object recognition part of the memory. Besides, muscimol treatment before the second sample trial blocks its object‐in‐context LTM and restores the first sample trial memory. We hypothesized that LTM‐RI amnesia is probably caused by resources or cellular machinery competition in these brain regions when they are engaged in memory formation of the traces. In sum, when two different object‐in‐context memory traces are being processed, the second trace interferes with the consolidation of the first one requiring mPFC and CA1 dorsal Hp activation. © 2014 Wiley Periodicals, Inc.     

The effect of scene context on episodic object recognition: parahippocampal cortex mediates memory encoding and retrieval success

Previous research has investigated intentional retrieval of contextual information and contextual influences on object identification and word recognition, yet few studies have investigated context effects in episodic memory for objects. To address this issue, unique objects embedded in a visually rich scene or on a white background were presented to participants. At test, objects were presented either in the original scene or on a white background. A series of behavioral studies with young adults demonstrated a context shift decrement (CSD)-decreased recognition performance when context is changed between encoding and retrieval. The CSD was not attenuated by encoding or retrieval manipulations, suggesting that binding of object and context may be automatic. A final experiment explored the neural correlates of the CSD, using functional Magnetic Resonance Imaging. Parahippocampal cortex (PHC) activation (right greater than left) during incidental encoding was associated with subsequent memory of objects in the context shift condition. Greater activity in right PHC was also observed during successful recognition of objects previously presented in a scene. Finally, a subset of regions activated during scene encoding, such as bilateral PHC, was reactivated when the object was presented on a white background at retrieval. Although participants were not required to intentionally retrieve contextual information, the results suggest that PHC may reinstate visual context to mediate successful episodic memory retrieval. The CSD is attributed to automatic and obligatory binding of object and context. The results suggest that PHC is important not only for processing of scene information, but also plays a role in successful episodic memory encoding and retrieval. These findings are consistent with the view that spatial information is stored in the hippocampal complex, one of the central tenets of Multiple Trace Theory.     

Differential roles of the dorsal hippocampal regions in the acquisition of spatial and temporal aspects of episodic-like memory

Episodic memory refers to the recollection of what, where and when an event occurred. Computational models suggest that the dentate gyrus (DG) and the CA3 hippocampal subregions are involved in pattern separation and the rapid acquisition of episodes, while CA1 is involved in the formation of a temporal context. Most of the studies performed to test this hypothesis failed to simultaneously address the aspects of episodic memory. Recently, a new task of object recognition was validated in rats. In the first sample trial, the rat is exposed to four copies of an object. In second sample, the rat is exposed to four copies of a different object. In the test trial, two copies of each of the previous objects are presented. One copy of the object used in sample trial one is located in a different place, and it is expected to be the most explored. Our goal was to evaluate whether the pharmacological inactivation of the dorsal DG/CA3 and CA1 subregions could differentially impair the acquisition of the task. Inactivation of the DG/CA3 subregions impaired the spatial discrimination, while the temporal discrimination was preserved. Rats treated with muscimol in CA1 explored all the objects equally well, irrespective of place or presentation time. Our results are consistent with computational models that postulate a role for DG/CA3 in rapid encoding and in spatial pattern separation, and a role for CA1 in the in the formation of the temporal context of events and as well as in detecting spatial novelty.     

Lateral entorhinal cortex is critical for novel object‐context recognition

Episodic memory incorporates information about specific events or occasions including spatial locations and the contextual features of the environment in which the event took place. It has been modeled in rats using spontaneous exploration of novel configurations of objects, their locations, and the contexts in which they are presented. While we have a detailed understanding of how spatial location is processed in the brain relatively little is known about where the nonspatial contextual components of episodic memory are processed. Initial experiments measured c‐fos expression during an object‐context recognition (OCR) task to examine which networks within the brain process contextual features of an event. Increased c‐fos expression was found in the lateral entorhinal cortex (LEC; a major hippocampal afferent) during OCR relative to control conditions. In a subsequent experiment it was demonstrated that rats with lesions of LEC were unable to recognize object‐context associations yet showed normal object recognition and normal context recognition. These data suggest that contextual features of the environment are integrated with object identity in LEC and demonstrate that recognition of such object‐context associations requires the LEC. This is consistent with the suggestion that contextual features of an event are processed in LEC and that this information is combined with spatial information from medial entorhinal cortex to form episodic memory in the hippocampus. © 2013 Wiley Periodicals, Inc.     

Effects of hippocampal administration of a cannabinoid receptor agonist WIN 55,212-2 on spontaneous object and place recognition in rats

Involvement of hippocampal cannabinoid receptors in short-term memory was investigated in rats using spontaneous object and place recognition memory tasks. Rats were allowed to explore the field in which two identical objects were presented. Then after a delay period, they were placed again in the same field in which one of the two objects was replaced by another object (object recognition task) or moved to another place (place recognition task), and their exploration behavior to these objects were analyzed. Activation of hippocampal cannabinoid receptors by an agonist WIN 55,212-2 (1–2 μg/side) dose-dependently decreased the exploration of object in a new place, while it did not affect the exploration of a new object. Disruptive effect of WIN 55,212-2 on place recognition was antagonized by the pretreatment with a cannabinoid receptor antagonist AM 281 (2 mg/kg, i.p.). Results suggest that hippocampal cannabinoid receptors play an important role in place recognition or spatial memory.     

Perirhinal cortex lesions impair tests of object recognition memory but spare novelty detection

The present study examined why perirhinal cortex lesions in rats impair the spontaneous ability to select novel objects in preference to familiar objects, when both classes of object are presented simultaneously. The study began by repeating this standard finding, using a test of delayed object recognition memory. As expected, the perirhinal cortex lesions reduced the difference in exploration times for novel vs. familiar stimuli. In contrast, the same rats with perirhinal cortex lesions appeared to perform normally when the preferential exploration of novel vs. familiar objects was tested sequentially, i.e. when each trial consisted of only novel or only familiar objects. In addition, there was no indication that the perirhinal cortex lesions reduced total levels of object exploration for novel objects, as would be predicted if the lesions caused novel stimuli to appear familiar. Together, the results show that, in the absence of perirhinal cortex tissue, rats still receive signals of object novelty, although they may fail to link that information to the appropriate object. Consequently, these rats are impaired in discriminating the source of object novelty signals, leading to deficits on simultaneous choice tests of recognition.     

Findings from animals concerning when interactions between perirhinal cortex, hippocampus and medial prefrontal cortex are necessary for recognition memory

Loss of recognition memory is a prominent feature of the human classical amnesic syndrome. Recognition memory requires judgments concerning prior occurrence. Such judgments can be made in a variety of ways using different types of information such as the relative familiarity of individual objects or locations, or the location of a previously encountered object, or when an object was previously encountered. We review findings of selective ablation studies which demonstrate that the perirhinal cortex, hippocampus and medial prefrontal cortex are differently involved in recognition memory processes involving these different types of information. This review also presents data from a series of disconnection analyses, which test whether the perirhinal cortex, hippocampus and medial prefrontal cortex form components of an integrated system for these recognition memory processes. These analyses reveal that it is necessary for the perirhinal cortex, medial prefrontal cortex and the hippocampus to interact, forming an integrated network, in recognition memory involving judgment of whether an object has been previously encountered in a particular place (object-in-place recognition memory) and in judging which of two objects was encountered longer ago (temporal order memory). In contrast, such interactions are not necessary when judgments are made concerning the prior occurrence of an individual item without positional information being necessary for the judgment (object memory) or concerning the prior occurrence of some item at a particular location without object information being necessary for the judgment (location memory).     

Neurotoxic methamphetamine regimen severely impairs recognition memory in rats

Methamphetamine (mAMPH), when administered repeatedly to rodents or primates, is neurotoxic to some cortical neurons and to forebrain dopaminergic and serotonergic axon terminals. The aim of the present study was to investigate the effects of a neurotoxic regimen of mAMPH on two hippocampus-dependent memory tasks: object recognition, a nonspatial memory task, and the Morris water maze, a spatial memory task. Male rats were treated with mAMPH (4 x 4.0 mg/kg, s.c.) or saline and trained in the object recognition task 1 week and 3 weeks later. During training, animals explored two identical copies of the same object. In retention test sessions one of the objects was replaced by a novel object. mAMPH-treated rats showed no recognition memory during the short-term memory (STM) test, given 90 min after the training session, and showed marked impairments in the long-term memory (LTM) test, given 24 h after training. Even 3 weeks after drug injections, the mAMPH-treated animals were unable to discriminate between the novel and familiar objects during both STM and LTM tests. Despite the severe deficits observed in the recognition memory, no effects of prior mAMPH treatment were seen in the water maze task. Damage to monoamine terminals was confirmed by significant 30-40% losses of [(125)I]RTI-55 binding to striatal dopamine transporter and hippocampal serotonin transporter sites at both 1 and 3 weeks after mAMPH treatments. Thus, administration of mAMPH restricted to a single day can produce a profound, persistent, and selective deficit in a nonspatial hippocampus-dependent memory.     

Modulation of theta phase synchronization in the human electroencephalogram during a recognition memory task

To the extent that recognition memory relies on interactions among widely distributed neural assemblies across the brain, phase synchronization between brain rhythms may play an important role in meditating those interactions. As the theta rhythm is known to modulate in power during the recognition memory process, we aimed to determine how the phase synchronization of the theta rhythms across the brain changes with recognition memory. Fourteen human participants performed a visual object recognition task in a virtual reality environment. Electroencephalograms were recorded from the scalp of the participants while they either recognized objects that had been presented previously or identified new objects. From the electroencephalogram recordings, we analyzed the phase-locking value of the theta rhythms, which indicates the degree of phase synchronization. We found that the overall phase-locking value recorded during the recognition of previously viewed objects was greater than that recorded during the identification of new objects. Specifically, the theta rhythms became strongly synchronized between the frontal and the left parietal areas during the recognition of previously viewed objects. These results suggest that the recognition memory process may involve an interaction between the frontal and the left parietal cortical regions mediated by theta phase synchronization.