Thalamic-Cortical-Striatal Circuitry Subserves Working Memory during Delayed Responding on a Radial Arm Maze

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The Journal of Neuroscience, December 15, 1999, 19(24):11061-11071

Thalamic-Cortical-Striatal Circuitry Subserves Working Memory during Delayed Responding on a Radial Arm Maze
Stan B. Floresco, Deanna N. Braaksma, and Anthony G. Phillips
Department of Psychology, University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z4

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
GENERAL DISCUSSION
REFERENCES

The medial dorsal nuclei of the thalamus (MDNt), the prefrontal cortex, and the ventral striatum form an interconnected neuralcircuit that may subserve certain types of working memory. Thepresent series of experiments investigated functional interactionsbetween these brain regions in rats during the performance ofdelayed and nondelayed spatially cued radial-arm maze tasks. InExperiment 1, transient inactivation of the MDNt by a bilateralinjection of lidocaine selectively disrupted performance on adelayed task but not on a nondelayed random foraging version ofthe radial arm maze task. In Experiment 2, asymmetrical lidocaineinjections into the MDNt on one side of the brain and the prefrontalcortex on the other transiently disconnected these two brain regionsand significantly impaired foraging during the delayed task. Similarly,disconnections between the prefrontal cortex and the nucleus accumbensalso disrupted foraging on this task, whereas disconnections betweenthe MDNt and the nucleus accumbens had no effect. These data suggestthat serial transmission of information among the MDNt, the prefrontalcortex, and the nucleus accumbens is required when trial-unique,short-term spatial memory is used to guide prospective searchbehavior. The results are discussed with respect to a distributedneural network linking limbic, thalamic, cortical, and striatalregions, which mediates executive functions of workingmemory.

Key words: medial-dorsal thalamus; prefrontal cortex; nucleus accumbens; working memory; neural networks; lidocaine-induced reversible lesions; rats

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
GENERAL DISCUSSION
REFERENCES

Working memory is defined as the ability to retain and manipulate mnemonic information to guide ongoing behavior (Baddeley,1986). An important component of working memory is the short-termstorage of trial-unique information (Goldman-Rakic, 1995), wherebyunique information about specific stimuli (e.g., spatial locationand object information) is retained briefly in a short-term memorybuffer and discarded after an appropriate response is executed.Another element of working memory involves cognitive processesthat are characterized as "executive functions," which includethe supervisory processes for the temporal organization of behavior,and the use of short-term memory to plan a sequence of forthcomingresponses (Shallice, 1982; Baddeley and Della Sala, 1996; Shalliceand Burgess, 1996; Kimberg et al., 1997).

There is a general consensus that the prefrontal cortex (PFC) is intimately involved in one or both aspects of working memory.Damage to the PFC in primates (Goldman-Rakic, 1987) or rats (Dunnett,1990) impairs delayed responding on delayed response tasks withshort delays. Likewise, electrophysiological recordings from PFCneurons in behaving primates (Fuster, 1995; Goldman-Rakic, 1995)or rodents (Orlov et al., 1988; Batuev et al., 1990) show sustainedfiring throughout the delay period of a delayed response task,and this may serve as an internal representation of previouslypresented stimuli. Lesion and electrophysiological recording studiesalso have shown that the PFC mediates behaviors that require themanipulation of information for the purposes of executive motorcontrol, including route planning in a Morris water maze (Granonand Poucet, 1995), switching of behavioral strategies (Seamanset al., 1995: Ragozzino et al., 1999), and the use of previouslyacquired information to guide prospective responding (Seamanset al., 1995; Rainer et al., 1999). Collectively, these studiessuggest that the PFC plays an important role in both the short-termmemory and executive components of workingmemory.

A growing body of evidence suggests that interactions between the PFC and its cortical and subcortical connections facilitatebehaviors that require working memory. In primates, inactivationof either the parietal cortex (Quintana et al., 1989) or the inferotemporalcortex (Fuster et al., 1985) disrupts both behavioral performanceand task-related neural activity in the PFC during a delayed matching-to-sampletask, suggesting that information transfer between these brainregions meditates performance of this task. Similarly, disconnectionsbetween the temporal and frontal lobes disrupts learning of aconditional visual discrimination task (Gutnikov et al., 1997).Along similar lines, research in our laboratory has examined theinteractions between the PFC and its limbic and striatal connectionsduring the performance of a delayed spatial win-shift (SWSh) versionof the radial arm maze task. During this task, rats are giveninformation about the location of food on a maze during a trainingphase, 30 min before a test session. This procedure biases ratsto forage prospectively (Cook et al., 1985), enabling them toplan a response strategy that ensures that food is located efficiently.Performance of this task is dependent, in part, on a neural circuitlinking the hippocampus, PFC, and the nucleus accumbens (N.Acc.)(Floresco et al., 1997). We hypothesize that a distributed neuralnetwork involving the frontal and temporal corticies mediatesthe retrieval and use of trial-unique spatial information overextended delays, whereas a circuit linking the PFC to the ventralstriatum is involved in integrating a prospective code into appropriatemotoroutput.

The PFC is also linked anatomically to the medial dorsal nuclei of the thalamus (MDNt). The MDNt shares reciprocal connectionswith the PFC (Krettek and Price, 1977; Leonard, 1969; Ray andPrice, 1992) and the hippocampal formation (Beckstead, 1978; Suand Bentivoglio, 1990) and also sends projections to the N.Acc.(Berendse and Groenewegen, 1990; Otake and Nakamura, 1998). Thedistributed interconnectivity of the MDNt suggests that this regionof the thalamus may play an important role in different componentsof working memory subserved by these other brain regions. Thisconjecture is supported by lesion and electrophysiological studiesimplicating the MDNt in a broad range of cognitive processes,including object recognition (Mumby et al., 1993), short-termmemory (Harrison and Mair, 1996), planning and prospective coding(Joyce and Robbins, 1991; Gallassi et al., 1992; Daum and Ackermann,1994), strategy selection and behavioral flexibility (Hunt andAggleton, 1998), the encoding of the motivational significanceof stimuli (Gabriel, 1993; Oyoshi et al., 1996), and working memory(Freeman et al., 1996; Callicott et al., 1999).

The present study investigated the role of the MDNt during performance of two variants of the radial arm maze task in rats,each of which required a different type of memory processing,one involving retrospective and the other prospective use of previouslyacquired information. The first experiment assessed the effectsof bilateral reversible lidocaine inactivation of the MDNt beforeeither the training or the test phase of the delayed SWSh task,or the nondelayed random foraging (RF) version of the radial mazetask. The second experiment used asymmetrical disconnection lesions(Floresco et al., 1997) among the MDNt, the PFC, and the N.Acc.to elucidate the routes of information transfer in thalamic-cortical-striatalcircuits essential for performance of the delayed SWSh task

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
GENERAL DISCUSSION
REFERENCES

Subjects
The subjects were male Long-Evans rats weighing between 300 and 450 gm before surgery. All rats were given ad libitum accessto water and were maintained at 85% of their free-feeding weightby providing 25-30 gm of Purina lab chow pellets once daily. Ratswere tested 5-7 d/week.

Surgery
Rats were anesthetized with 100 mg/kg ketamine hydrochloride and 7 mg/kg xylazine. Twenty-three gauge stainless-steel guidecannulae were implanted into the brain regions using standardstereotaxic techniques. The stereotaxic coordinates (flat skull)were derived from those of Paxinos and Watson (1986). For thebilateral MDNt inactivation experiments (Experiment 1), threegroups of rats were implanted with one set of bilateral cannulainto the MDNt [anteroposterior (AP), $-$ 2.9 mm from bregma; mediolateral(ML), ±0.7 mm from midline; and dorsoventral (DV), $-$ 4.9 mm fromdura].
For the disconnection experiments (Experiment 2), three groups of rats were implanted with two sets of bilateral cannula.One group of rats was implanted with one pair of cannula in theMDNt and a second pair in the prelimbic region of the PFC (AP,+2.7 mm; ML, ±0.7 mm from bregma; and DV, $-$ 3.0 mm from dura).This region of the PFC was chosen because it receives projectionsfrom the hippocampus (Conde et al., 1995), and because it is involvedselectively in delayed radial maze foraging (Seamans et al., 1995;Floresco et al., 1997). A second group was implanted with onepair of cannula in the MDNt and a second pair in the N.Acc. (AP,+1.5 mm; ML, ±1.3 mm from bregma; and DV, $-$ 6.0 mm from dura).A third group of rats was implanted with one pair of cannula inthe PFC and a second pair in the N.Acc. In this group, the corpuscallosum was transected with a 30 gauge needle (AP, +1.6 to +0.5 mm; ML, ±1.0 mm from bregma; and DV, $-$ 4.0 mm from dura). Thisprocedure ensured that there would be no projections from onehemisphere of the PFC that would reach the contralateral N.Acc.(Brog et al., 1993). Unilateral infusions of lidocaine were administeredin the hemisphere opposite to the side that received the transection.Thirty gauge obdurators flush with the end of the guide cannulaeremained in place until the injections were made. Each rat wasgiven at least 7 d to recover from surgery beforetesting.

Microinfusion procedure
On injection days, the obdurators were removed, and 30 gauge stainless steel injection cannulae were inserted 0.8 mm beyondthe tip of the guide cannulae. Lidocaine (20 µg in 0.5 µl of saline;Astra Pharmaceuticals and Research Biochemicals) or saline (0.5µl) were delivered at a rate of 0.5 µl/1.2 min by a microsyringepump (Sage Instruments model 341). Injection cannulae were leftin place for an additional 1 min after each injection to allowfor diffusion. Each rat remained in its home cage for an additional3 min before being placed on the maze. The functional spread oflidocaine infused at this volume and concentration has been estimatedpreviously at no greater than 1 mm in diameter (Floresco et al.,1997; Tehovnik and Sommer, 1997). Based on these estimates, itcould be expected that the lidocaine infusions in the presentstudy would inactivate the medial, central, and lateral regionsof the medial dorsal thalamus, as well as the paraventricularnuclei.

Apparatus
An eight-arm radial maze was used for all experiments. The maze had an octagonal center platform 40 cm in diameter connectedto eight equally spaced arms, each measuring 50 × 9 cm, with acylindrical food cup at the end. Removable pieces of white opaqueplastic (9 × 13 cm) were used to block the arms of the maze. Themaze was elevated 40 cm from the floor and was surrounded by numerousextra maze cues (e.g., cupboards, posters, doors, and the experimenter),in a room 4 × 5 × 3 m, which was illuminated with overhead fluorescentlights (100W).

Foraging tasks
The two foraging tasks used in the present study were the delayed SWSh and the nondelayed RFtasks.
The delayed SWSh task. This task was adapted from that of Packard et al. (1990) and has been described in detail elsewhere(Floresco et al., 1997). On the first 2 d of testing, rats werehabituated to the maze environment. Subsequent training trialswere given once daily. These trials consisted of a training phaseand a test phase, separated by a delay. Before the training phase,a set of four arms was chosen randomly and blocked. Food pellets(Bioserv, Frenchtown, NJ) were placed in the food cups of thefour remaining open arms. During the training phase, each ratwas given 5 min to retrieve the pellets from the four open armsand then was returned to its home cage for the delay period (seebelow). During the test phase of each daily trial, all arms wereopen, but only the arms that were previously blocked containedfood. Rats were allowed a maximum of 5 min to retrieve the fourpellets during the testphase.
The initial delay between training and test phases was 5 min. After achieving criterion performance in which all four pelletswere retrieved in five or fewer choices during the test phasefor two consecutive days, the delay was increased to 30 min. Thefirst intracranial injections were administered after rats attained2 consecutive days of criterion performance at a 30 min delay.After the first injection day, animals were again retrained tothe criterion performance. The following day, a second intracranialinjection was administered. This procedure was repeated untilan animal had received the designated sequence of injections,according to the protocols described below (seeProcedure).
On injection days the number and order of arm entries were recorded. An arm entry was recorded when a rat moved down the entirelength of an arm and reached the food cup at the end of the arm.Errors were scored as entries into nonbaited arms and furtherbroken down into two error subtypes. An across-phase error wasdefined as any initial entry into an arm that had been visitedpreviously during the training phase. A within-phase error wasany reentry into an arm that had been entered earlier during thetest phase. The latencies to reach the food cup of the first armvisited and to complete the phase also wererecorded.
The nondelayed RF task. This task also has been described elsewhere (Floresco et al., 1997). Habituation to the maze duringthe first 2 d of training was identical to the delayed SWSh proceduredescribed above. On subsequent daily trials animals were requiredto forage for pellets placed at random in the food cups of fourof the eight arms (hence the term random foraging). A novel setof arms was baited each day. Animals were trained to a criterionof no more than one reentry error per trial for 4 consecutivedays. The day after criterion performance was achieved, the firstintracranial injections were administered. After the first injectionday, animals were retrained to criterion for 2 consecutive days.As with the delayed SWSh task, this procedure was repeated untileach animal had received all the designatedinjections.
Errors were scored as reentries into arms visited previously within a trial. These errors were broken down further into reentriesinto baited arms (arms that had been baited at the start of thetrial) and reentries to nonbaited arms (arms that were not baitedbefore the start of the trial). The number of reentry errors madeon each of the injection days was recorded and used for data analysis.As with the delayed SWSh paradigm, the latencies to reach thefirst food cup (either baited or nonbaited) after being placedon the maze and the time required to retrieve all four pelletswere alsorecorded.

Histology
After completion of behavioral testing, the rats were killed in a carbon dioxide chamber. Brains were removed and fixed ina 10% formalin solution. The brains were frozen and sliced in50 µm sections before being mounted and stained with cresyl violet.Placements were verified with reference to the neuroanatomicalatlas of Paxinos and Watson (1986).

Data analysis
The number and type of errors made on the day before the first injection sequence and for all injection days for each experimentwere analyzed using separate two-way within-subjects design ANOVAwith the treatment and error type as two within-subjects factors.In this design, a significant main effect of treatment indicatesthat one or more infusion treaments caused an increase in thetotal number of errors observed during the task, releative toother treatments. A significant main effect of error type wouldindicate that rats made significantly more of one type of error(e.g., across-phase errors) versus the other type of error (e.g.,within-phase) over all treatment conditions. The n values listedfor each group represent the number of rats that had acceptablecannulae placements. Main effects of Treatment were further analyzedusing Tukey's post hoc tests for repeated measures. Whenever asignificant main effect of treatment was observed, one plannedcomparison was made, analyzing the number of each type of errormade on lidocaine injectiondays.
The latency data to reach the first food cup and the average time per subsequent choice on injection days were analyzed witha one-way repeated measures ANOVA. The average time per subsequentchoice was calculated using the formula: (time to complete trial $-$ time to initiate trial) $divide$ number of choices fortrial.
Whenever a significant main effect of treatment was observed in Experiment 2, three one-way ANOVAs were conducted, assessingthe number of errors made on tests after a unilateral inactivationof the MDNt, PFC, or N.Acc., as well as after disconnection inactivations,with the side of the injection as a between-subjects factor. Thisanalysis was conducted to rule out the possibility that unilateralinactivations in one hemisphere would lead to a greater increasein errors than inactivations of the otherhemisphere.

  EXPERIMENT 1: REVERSIBLE, BILATERAL MDNt LESIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
GENERAL DISCUSSION
REFERENCES

Procedure

A within-subjects design was used for all three parts of Experiment 1. Three groups of rats with bilateral cannulae implantedinto the MDNt were trained on either the delayed SWSh task orthe RF task. On the first injection days, these three groups ofrats received bilateral infusions of either lidocaine or salineinto the MDNt before the nondelayed RF task (group 1), beforethe training phase (group 2), or before the test phase of thedelayed SWSh (group 3). Animals were subsequently retrained untilthey reattained criterion performance. On the day after the criterionwas reattained, a second infusion of either saline or lidocainewas administered in a counterbalancedorder.

Results

Nondelayed RF
Before a daily trial of the nondelayed RF task, 11 rats received bilateral infusions of lidocaine or saline into the MDNton separate days. The analysis of these data revealed no significantmain effect of treatment (F_(2,20) =1.12; not significant; Fig.1A). There were also no significant differences between treatmentdays in the latencies to reach the first food cup or on the averagetime per subsequent choice (all F < 0.55; not significant).

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Figure 1. Effects of bilateral inactivation of the MDNt on performance of delayed and nondelayed radial arm maze tasks. A, Number of errors (mean ± SEM) made by rats on the day before the first injection (open bar) and after infusions of saline (hatched bar) or lidocaine (black bar) into the MDNt before the nondelayed RF task. B, Number of errors (mean ± SEM) made by rats during the test phase on the day before the first injection (open bar) and after infusions of saline (hatched bar) or lidocaine (black bar) into the MDNt before the training phase of the delayed SWSh task. Inset, Number of errors made during the training phase on the day before the first injection (open bar) and on saline (hatched bar) and lidocaine (black bar) injection days. C, Number of errors (mean ± SEM) made by rats during the test phase on the day before the first injection (open bar) and after infusions of saline (hatched bar) or lidocaine (black bar) into the MDNt before the test phase of the delayed SWSh task. Significance at p < 0.001 relative to saline and previous day. Inset, Number of across-phase errors (cross-hatched bar) and within-phase errors (striped bar) made by rats on lidocaine injection days. D, Location of infusions (black circles) for all rats with acceptable placements receiving infusions into the MDNt before the test phase of the delayed SWSh task. Plates are computer-generated adaptations from Paxinos and Watson (1986). Numbers beside each slide correspond to millimeters from bregma.

Delayed SWSh, pretraining injections
Before the training phase of the delayed SWSh task, eight rats received bilateral infusions of lidocaine or saline into theMDNt on separate days. There were no significant differences inthe number of errors made on either the training phase (F_(2,12)= 1.00; not significant; Fig. 1B, inset) or the test phase (F_(2,12)= 1.28; not significant; Fig. 1B) on any of the treatment days.In addition, there were no significant differences in latenciesto reach the first food cup or in the average time per subsequentchoice of arms on either the training or the test phases (allF < 2.3; notsignificant).

Delayed SWSh, pretest injections
Before the test phase of the delayed SWSh task, eight rats received bilateral infusions of lidocaine or saline into the MDNton separate days. Analyses of the number of errors made on theday before the first injection and on saline and lidocaine injectiondays revealed a significant main effect of treatment (F_(2,12)= 24.08; p < 0.001; Fig. 1C). Tukey's post hoc analysis for repeatedmeasures showed that rats made significantly more errors on lidocaineinjection days relative to both the day before the first injectionand the saline injection days (p < 0.001). Subsequent plannedcomparisons on the type of errors made on lidocaine injectiondays revealed that rats made the same number of across-phase andwithin-phase errors (F_(1,7) = 0.07; not significant; Fig. 1C,inset). Furthermore, there were no significant differences betweeninjection days on the latencies to reach the first food cup (F_(2,14)= 1.31; not significant.). However, lidocaine infusions into theMDNt did increase the average time per subsequent choice (mean,19.38 sec) relative to saline treatments and the day before thefirst injection (mean, 13.48 sec; F_(2,14) = 3.80; p < 0.05; andTukey's p < 0.05).

Histology
The locations of the infusion sites for all rats receiving inactivation of the MDNt before the test phase of the delayed SWShtask are shown in Figure 1D. Rats whose infusions were asymmetricalin the dorsoventral plane or whose placements encroached on eitherthe hippocampus or were near the region of the mammillothalamictract-gelatinosus nucleus were not included in the analysis (n= 5). It is notable that rats whose placements encroached on thehippocampus tended to be impaired on the tasks, and those ratswith placements near the level of the mammillothalamic tract showedno discernible impairment on any of the tasks. The data from theserats were not included in theanalyses.

Discussion

Reversible lesions of the MDNt selectively disrupted performance of the delayed SWSh task only when administered before thetest phase. Lidocaine infusions had no effect on performance whenthey were administered before the training phase of the delayedSWSh task or before the nondelayed RF task. The data from thisexperiment suggest that the MDNt does not play a significant rolein either the acquisition of trial-unique information or in exploratorygoal-directed locomotion in the absence of previous knowledgeabout the location of food. Rather, these data support the conclusionthat the MDNt plays a specific role in the retrieval and use ofpreviously acquired information to guide ongoing behaviors aftera delay. As such, the present data are consistent with previousreports that lesions to the rat MDNt do not impair performanceof nondelayed radial arm maze tasks (Kessler et al., 1982; Kolbet al., 1982; but see Stokes and Best, 1990) but do disrupt theperformance of radial maze tasks with delays between choices (Kessleret al., 1982; Harrison and Mair, 1996; Mair et al., 1998).

Analysis of the type of errors made by rats after reversible lesions of the MDNt was particularly revealing. During the delayedSWSh task, rats made an equal number of errors to arms entered30 min previously during the training phase (across-phase errors)and those entered more recently during the test phase (within-phaseerrors; Fig. 1B, inset). This finding is consistent with otherstudies demonstrating that lesions of the MDNt result in similarimpairments on a variety of delayed memory tasks (Winocur, 1985;Mumby et al., 1993; Savage et al., 1997; Mair et al., 1998). Itis interesting to note that the pattern of deficits after inactivationsof the MDNt was identical to those observed after similar inactivationsof the prelimbic cortex of the PFC (Seamans et al., 1995), orafter disconnections between the PFC and the hippocampus (Florescoet al., 1997). In those studies, the observation of an equal numberof across- and within-phase errors on the delayed SWSh task, incombination with no impairment on the nondelayed RF task, wasinterpreted as a disruption in the ability to use previously acquiredinformation to guide behavior toward arms predictive of food reward,as opposed to an impairment in short-term memory processes. Asimilar explanation may follow for the selective impairment indelayed SWSh behavior after reversible lesions of the MDNt. Inactivationsof the MDNt may have disrupted the ability of rats to use informationacquired during the training phase to discriminate which armswould contain food during the testphase.

Insight into the exact role played by the MDNt in delayed SWSh behavior may be obtained by examining interactions with itsefferent structures. As mentioned previously, the MDNt is reciprocallyconnected with the PFC (Leonard, 1969; Krettek and Price, 1977;Ray and Price, 1992) and also sends projections to the N.Acc.(Berendse and Groenewegen, 1990; Otake and Nakamura, 1998). Itis notable that bilateral inactivations to either of these structuresresult in impairment on delayed SWSh performance similar to thoseobserved here after MDNt inactivations (Seamans and Phillips,1994; Seamans et al., 1995). Therefore, the MDNt may interactwith the PFC and/or the N.Acc. when rats are engaged in prospectiveforaging behavior on the delayed SWSh task. Experiment 2 testedthis hypothesis by using asymmetrical disconnection lesions betweenthe MDNt and either the PFC or the N.Acc. before the test phaseof the delayed SWSh task. In addition, the PFC also sends a denseprojection to the N.Acc. (Sesack et al., 1989; Brog et al., 1993),and it has been proposed that this corticostriatal pathway isresponsible for the transformation of mnemonic information intoa sequence of goal-directed motor responses (Robbins, 1990, 1991;Goldman-Rakic et al., 1992; Seamans et al., 1995; Floresco etal., 1997). Thus it was of interest to assess the effect of disconnectionsbetween the PFC and the N.Acc. on performance of the delayed SWShtask. A disruption in foraging behavior after asymmetrical lesionsbetween the PFC and the N.Acc. would confirm the importance ofthis corticostriatal circuit in the transformation of a prospectiveplan of action into efficient behavioraloutput.

  EXPERIMENT 2: DISCONNECTION LESIONS BETWEEN THE MDNt AND THE PFC, THE MDNt AND THE N.Acc, OR THE PFC AND THE N.Acc

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
GENERAL DISCUSSION
REFERENCES

Procedure

A within-subjects design was used for all three lesion conditions of Experiment 2. Three groups of rats were implanted withtwo sets of bilateral cannulae in the following combinations:MDNt-PFC (group 1), MDNt-N.Acc. (group 2), and PFC-N.Acc. (group3). After recovery from surgery they were trained to criterionon the delayed SWShtask.

After achievement of criterion performance, animals in each of the disconnection lesion experiments received injections on4 separate days, each before the test phase of the delayed SWShtask. The following combinations of asymmetrical bilateral infusionswere used for groups 1 and 2 (MDNt-PFC and MDNt-N.Acc.): (1) aunilateral lidocaine infusion into the MDNt in combination witha contralateral lidocaine infusion into either the PFC or theN.Acc. (disconnection); (2) a unilateral lidocaine infusion intothe MDNt in combination with a saline infusion into the contralateralPFC or N.Acc.; (3) a unilateral lidocaine infusion into the PFCor N.Acc. in combination with a saline infusion into the contralateralMDNt; and (4) unilateral infusions of saline into the MDNt andsaline infusions into either the contralateral PFC or the N.Acc.For group 3 (PFC-N.Acc.), the following combinations of asymmetricalbilateral infusions were used: (1) a unilateral lidocaine infusioninto the PFC in combination with a contralateral lidocaine infusionthe N.Acc. (disconnection); (2) a unilateral lidocaine infusioninto the PFC in combination with a saline infusion into the contralateralN.Acc.; (3) a unilateral lidocaine infusion into the PFC in combinationwith a saline infusion into the contralateral N.Acc.; and (4)unilateral infusions of saline into both PFC and contralateralN.Acc. The order of infusions was counterbalanced between animalsusing a quasi-Latin square design. The counterbalancing was designedto ensure that a given sequence of injections was not repeated.The hemisphere (left or right) used for the first injection wasalso counterbalanced and was alternated for subsequent injections.Each animal was tested separately on the delayed SWSh task, andthe injection procedure was repeated until the animal had beentested four times with each sequence of intracranialinjections.

Results

PFC-MDNt disconnections
Rats (n = 8) with two sets of bilateral cannulae implanted into the prelimbic region of the PFC and the MDNt received theinjection protocol described above before the test phase of thedelayed SWSh task on 4 separate days. An analysis of these datarevealed a significant main effect of treatment (F_(4,28) = 6.41;p < 0.001). Tukey's post hoc test for repeated measures revealedthat rats made significantly more errors on injection days onwhich the PFC and the MDNt both received lidocaine infusions andwere disconnected versus all other injections days (p < 0.01;Fig. 2A). There were no other significant differences in the numberof errors made on any of the other injection days. There was asignificant main effect of error type (F_(1,7) = 25,95; p < 0.001).Subsequent planned comparisons on the type of errors made afterPFC-MDNt disconnections showed that rats made significantly moreacross-phase versus within-phase errors (F_(1,7) = 18.1; p < 0.01;Fig. 2A, inset). There was no significant treatment × error typeinteraction (F_(4,28) = 2.30; not significant). A separate seriesof tests was conducted to assess any hemispheric biases on thenumber of errors made after unilateral PFC inactivations, unilateralMDNt inactivations, and the disconnection lesions. The analysisrevealed no significant effects of the side of the injection onthe number of errors made by rats on the three injection days(all F < 1.1; not significant).

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Figure 2. Effects of PFC-MDNt disconnections on performance of the delayed SWSh task. A, Number of errors (mean ± SEM) made by rats on the day before the first injection (open bar) and after unilateral infusions of saline into both the PFC and the MDNt (hatched bar), unilateral infusions of lidocaine (Lido) into the PFC and contralateral saline in the MDNt (gray bar), unilateral infusions of Lido into the MDNt and contralateral saline into the PFC (stripped bar), and unilateral Lido into the MDNt and contralateral Lido into the PFC (disconnection; black bar) before the test phase of the delayed SWSh task. Significance at p < 0.001 versus all other treatment conditions. Inset, Number of across-phase (cross-hatched bar) versus within-phase (striped bar) errors made by rats during Lido/Lido (disconnection) injection days. Significance at p < 0.001 across- versus within-phase errors. B, Location of cannulae tips (black circles) for all rats used for data analysis receiving PFC-MDNt disconnections before the delayed SWSh task. Plates are computer-generated adaptations from Paxinos and Watson (1986). Numbers beside each plate correspond to millimeters from bregma. For clarity, B and all subsequent histology figures represent the locations of cannulae tips on sides that received infusions on disconnection injection days. All animals received infusions of either lidocaine or saline in each hemisphere.

Histology. The location of cannulae tips for all rats receiving PFC-MDNt disconnections are represented in Figure 2B. Bilateralplacements in the MDNt were similar to those observed in Experiment1. Placements in the PFC were limited to the prelimbic cortex,similar to placements observed by Seamans et al. (1995).

MDNt-N.Acc. disconnections
A separate group of rats (n = 7) with two sets of bilateral cannulae implanted into the N.Acc. and the MDNt received the injectionprotocol described above before the test phase of the delayedSWSh task on 4 separate days. The analysis of these data revealedno significant main effect of treatment (F_(4,24) = 1.31; not significant;Fig. 3A). There was a significant main effect of error type (F_(1,6)= 103.89; p < 0.001). There was no significant treatment × errortype interaction (F_(4,24) = 1.25; not significant).

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Figure 3. Effects of MDNt-N.Acc. disconnections on performance of the delayed SWSh task. A, Number of errors (mean ± SEM) made by rats on the day before the first injection (open bar) and after unilateral infusions of saline into both the N.Acc. and the MDNt (hatched bar), unilateral infusions of lidocaine (Lido) into the N.Acc. and contralateral saline in the MDNt (gray bar), unilateral infusions of Lido into the MDNt and contralateral saline into the N.Acc. (striped bar), and unilateral Lido into the MDNt and contralateral Lido into the N.Acc. (disconnection; black bar) before the test phase of the delayed SWSh task. B, Location of cannulae tips (black circles) for all rats used for data analysis receiving MDNt-N.Acc. disconnections before the delayed SWSh task. Plates are computer-generated adaptations from Paxinos and Watson (1986). Numbers beside each plate correspond to millimeters from bregma.

Histology. The location of cannulae tips for all rats receiving MDNt-N.Acc. disconnections are represented in Figure 3B. Bilateralplacements in the MDNt were similar to those observed in Experiment1, whereas placements in the N.Acc. were located primarily inthe medial shell region, similar to placements observed by Florescoet al. (1997).

PFC-N.Acc. disconnections
A separate group of rats (n = 8) with two sets of bilateral cannulae implanted into the prelimbic region of the PFC and theN.Acc. received the injection protocol described above beforethe test phase of the delayed SWSh task on 4 separate days. Ananalysis of these data revealed a significant main effect of treatment(F_(4,28) = 10.85; p < 0.001). Tukey's post hoc test for repeatedmeasures revealed that rats made significantly more errors oninjection days on which the PFC and the N.Acc. both received lidocaineinfusions and were disconnected versus all other injection days(p < 0.01; Fig. 4A). There were no significant differences inthe number of errors made on any of the other injection days.There was a significant main effect of error type (F_(1,7) = 25.84;p < 0.001). Subsequent planned comparisons on the type of errorsmade after PFC-N.Acc. disconnections showed that rats made anequivalent number of across- and within-phase errors (F_(1,7) =0.33; not significant; Fig. 4A, inset). There was no significanttreatment × error type interaction (F_(4,28) = 2.30; not significant).A separate series of tests was conducted to assess any hemisphericbiases on the number of errors made after unilateral PFC inactivations,unilateral N.Acc. inactivations, and the disconnection lesions.The analysis revealed no significant effects of the side of theinjection on the number of errors made by rats on the 3 injectiondays (all F < 0.5; not significant).

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Figure 4. Effects of PFC-N.Acc. disconnections on performance of the delayed SWSh task. A, Number of errors (mean ± SEM) made by rats on the day before the first injection (open bar) and after unilateral infusions of saline into both the PFC and the N.Acc. (hatched bar), unilateral infusions of lidocaine (Lido) into the PFC and contralateral saline in the N.Acc. (gray bar), unilateral infusions of Lido into the N.Acc. and contralateral saline into the PFC (striped bar), and unilateral Lido into the N.Acc. and contralateral Lido into the PFC (disconnection; black bar) before the test phase of the delayed SWSh task. Significance at p < 0.001 versus all other treatment conditions. Inset, Number of across-phase (cross-hatched bar) versus within-phase (striped bar) errors made by rats during Lido/Lido (disconnection) injection days. B, Location of cannulae tips (black circles) for all rats used for data analysis receiving PFC-N.Acc. disconnections before the delayed SWSh task. Plates are computer generated adaptations from Paxinos and Watson (1986). Numbers beside each plate correspond to millimeters from bregma.

Histology. The location of cannulae tips for all rats receiving PFC-N.Acc. disconnections are represented in Figure 4B. Bilateralplacements in the prelimbic region of the PFC were similar tothose observed after PFC-MDNt disconnections, whereas placementsin the N.Acc. were located primarily in the medial shell region,similar to placements observed in rats receiving MDNt-N.Acc.disconnections.
Latencies. Analysis of the latency data for all three groups in Experiment 2 revealed that there were no significant differencesbetween treatment conditions for either the time to enter thefirst arm or on the average time per subsequent choice (all F< 1.6; notsignificant).

Discussion

Lidocaine infusions in an asymmetrical pattern, which disconnected the flow of information between the PFC and the MDNt, disruptedthe correct choice of arms containing food when administered beforethe test phase of the delayed SWSh task (Fig. 5A). These datasuggest that intact serial transmission in this corticothalamicpathway is essential for performance of working memory tasks withextended delays. Analysis of the type of errors revealed thatrats made more across-phase errors than within-phase errors. Thisresult was unexpected, because bilateral inactivations of eitherstructure alone (Seamans et al., 1995; Experiment 1) caused anequal number of both types of errors, a pattern that has beeninterpreted as a disruption in planning a foraging strategy, asopposed to a memory deficit per se. One possible explanation ofincreased visits to arms baited in the training session may bethat disconnections between the PFC and the MDNt caused an impairmentin behavioral flexibility (Hunt and Aggleton, 1998), resultingin preseveration. However, this explanation seems unlikely, giventhat bilateral inactivation of either the MDNt (Experiment 1)or the prelimbic region of the PFC (Seamans et al., 1995) didnot result in preseverative responding on the delayed SWSh task.A more likely explanation for the selective increase in across-phaseerrors is that this neural circuit is specifically involved inthe retrieval and use of trial-unique information acquired beforea delay to guide choice behavior toward the probable locationof food during the test phase. The finding that PFC-MDNt disconnectionsdid not significantly disrupt within-phase performance indicatesthat this pathway does not play a role in monitoring choice behaviorwithin a trial. The finding that bilateral inactivations of theMDNt disrupted within-phase performance, whereas PFC-MDNt disconnectionsdid not, suggests that another population of MDNt neurons thatdoes not project to the PFC may mediate within-phase performance.Support for this idea comes from the finding that a subset ofMDNt neurons show selective increases in activity when an animalis presented with a conditional stimulus that requires the animalto inhibit an instrumental response (Kubota et al., 1996). Thusit may be that other efferent projections of the MDNt, such asto the orbitofrontal cortex or the hippocampal formation, areinvolved in monitoring responses within a trial. (Su and Bentivoglio,1990; Ray and Price, 1992; Floresco et al., 1997; Rolls, 1998).

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Figure 5. Diagram of the anatomical connections investigated in the present study between the MDNt, the prelimbic cortex region of the PFC and the N.Acc. X, Location of the unilateral inactivations to the MDNt, PFC, or N.Acc. for the delayed SWSh task; solid arrows, intact pathways; open arrows, pathways that are not blocked but do not carry the relevant information because of a concomitant lidocaine-induced lesion upstream of this pathway; T symbols, blocked, nonfunctional pathways. A, Proposed route of information transfer between the PFC and MDNt during the delayed SWSh task. By disconnecting the PFC-MDNt pathway, information cannot be processed by the PFC to generate appropriate responses after a delay, thereby disrupting appropriate output (impairment). B, Proposed route of information transfer between the PFC and N.Acc. during the delayed SWSh task. Disconnection of the PFC-N.Acc. pathway prevents the flow of information from the PFC through the N.Acc. to motor output centers (impairment). C, Proposed route of information transfer between the MDNt and N.Acc. during the delayed SWSh task. Information from the MDNt may be routed primarily through the PFC and subsequently to the N.Acc. Thus, although the pathway from the MDNt to the N.Acc. is disconnected, relevant information may still be transferred from the unanesthetized MDNt to the ipsilateral PFC and subsequently routed to the contralateral N.Acc., allowing for appropriate output (no impairment).

It is notable that the MDNt can be subdivided into separate regions based on cytoarchitectural properties and connectivityto cortical and subcortical regions (Groenewegen, 1988). Specifically,the medial segments of the MDNt receive projections from a numberof limbic regions (e.g., amygdala and entorhinal cortex), whereasthe central segments receive a more dense input from olfactory-relatedstructures (Groenewegen, 1988). Similarly, the lateral segmentsof the MDNt send projections to the dorsal anterior cingulatecortex, whereas the medial segments send afferents to the prelimbicand infralimbic regions of the PFC (Conde et al., 1995). Withrespect to the present study, infusions of lidocaine into theMDNt would be expected to inactivate multiple subregions of thisnucleus, including the central, lateral, and medial segments.Thus, it is difficult to determine the functional roles that eachof these subnuclei play during the delayed SWSh task. However,in light of the results of Experiment 2, in which disconnectionsbetween the MDNt and the prelimbic region of the PFC disrupteddelayed SWSh performance, it is reasonable to speculate that themore medial components of the MDNt (which project to the prelimbicand infralimbic areas) may play an important role in this formof working memory. More research is needed to ascertain the preciserole that each of these thalamic subregions plays in working memoryprocesses.

Disconnection of the projection between the PFC and the N.Acc. also disrupted performance on the delayed SWSh task. Rats madean equal number of across- and within-phase errors, which maybe interpreted as a complete disruption of a prospective foragingstrategy. These data confirm our previous hypothesis (Florescoet al., 1997) that inputs from the PFC to the N.Acc. are essentialfor the transformation of a prospective plan of action into appropriatebehavioral output. Furthermore, these data are consistent withthe more general theory that executive control over motor functionsrequires interactions between the PFC and striatal systems (Robbins,1990, 1991; Goldman-Rakic et al., 1992). Thus, a unilateral inactivationof the PFC could deprive the N.Acc. in one hemisphere of informationregarding a prospective foraging strategy, whereas direct inactivationof the contralateral N.Acc. blocks the integration of this informationinto accurate goal-directed responses, thereby leading to randomresponding and impaired foraging behavior (Fig. 5B).

In contrast to the above-mentioned findings, disconnections between the MDNt and the N.Acc. had no disruptive effect on delayedSWSh performance. This finding may seem contradictory, becausebilateral inactivations of either the MDNt (Experiment 1) or theN.Acc. (Seamans and Phillips, 1994) impaired foraging on the delayedtask. However, we have observed a similar pattern of results afterdisconnections between the ventral CA1-subiculum and the N.Acc.(Floresco et al., 1997). In that study, bilateral inactivationsof the ventral subiculum disrupted delayed SWSh performance, whereasdisconnections between the ventral subiculum and the N.Acc. didnot. It was conjectured that during the delayed SWSh task, informationwas transferred serially from the hippocampus initially to thePFC and then to the N.Acc. Given the multiple efferent projectionsfrom the hippocampus, asymmetrical disconnections between thehippocampus and the N.Acc. would not disrupt foraging behavior,because information from the intact PFC would still have accessto motor systems through the N.Acc via contralateral corticostriatalprojections (Sesack et al., 1989; Brog et al., 1993; Conde etal., 1995). A similar mechanism may explain the lack of effectof MDNt-N.Acc. disconnections in the present study. Informationarising from the MDNt in the intact hemisphere would still beable to access the PFC, and in turn, outputs from the PFC wouldbe able to interact with the intact N.Acc. in the opposite hemispherevia its contralateral connections (Fig. 5C). Thus, the presentresults in combination with our previous findings (Floresco etal., 1997) suggest that serial inputs from both the MDNt and theventral subiculum converge in the PFC, and the resulting informationis subsequently transferred to the N.Acc.

  GENERAL DISCUSSION

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The present data demonstrate a critical role for the MDNt in the performance of working memory tasks with extended delays.In Experiment 1, bilateral transient lesions of the MDNt selectivelydisrupted performance when administered before the test phaseof the delayed SWSh task. Similar treatments had no effect whenadministered before the training phase or when administered beforea nondelayed RF trial. Experiment 2 used asymmetrical disconnectionlesions to assess the routes of serial transmission among theMDNt, the PFC, and the N.Acc. during the delayed SWSh task. Thelogic underlying the use of disconnection lesions to identifycomponents of a functional neural circuit is based on the assumptionthat information is transferred serially from one structure toan efferent region on both sides of the brain in parallel. Furthermore,the design assumes that dysfunction will result from blockadeof neural activity at the origin of a pathway in one hemisphereand the termination of the efferent pathway in the contralateralhemisphere. It follows that a unilateral inactivation at eithersite should have no effect on behavior. Using this procedure,it was revealed that performance on the delayed SWSh task is dependenton an intact neural circuit linking the MDNt to the PFC and thePFC to the N.Acc.

A distributed circuit for working memory

Previous research in our laboratory has examined the importance of interactions between the PFC and its subcortical afferentsduring working memory with extended delays. Specifically, we haveshown that performance of the delayed SWSh task is criticallydependent on a distributed cortical-subcortical network linkingthe PFC and the ventral subiculum (Floresco et al., 1997), suggestingthat information maintained in a spatial memory buffer is routedfrom the hippocampus to the PFC, where it may be integrated intoa prospective foraging strategy. Furthermore, we posited that"interactions between the PFC and the ventral striatum are involvedin the transformation of spatial memory, processed by hippocampal-corticalcircuits, into an efficient sequence of goal-directed motor responses"(Floresco et al., 1997, p 1889). This hypothesis was confirmedby the present finding that disconnections between the PFC andthe N.Acc. disrupted delayed SWSh performance in a manner similarto PFC-hippocampal disconnections. We have also shown the importanceof the mesocortical dopaminergic projection from the ventral tegmentalarea to the PFC in this type of working memory. Infusions of aD1 receptor antagonist bilaterally or asymmetrical infusions ofa D1 antagonist into the PFC combined with an inactivation ofthe ventral subiculum disrupted performance on the delayed SWShtask (Seamans et al., 1998). These results suggested that PFCdopamine transmission plays an important neurmodulatory or "gain-amplifying"role (Robbins and Everitt, 1992), and may enhance task-relevanthippocampal inputs to thePFC.

Evidence from both clinical and preclinical studies suggests that the PFC interacts with the MDNt during certain types oflearning and memory. Humans with thalamic damage show frontal-typedeficits on a variety of neuropsychiatric tasks (Bogousslavskyet al., 1988; Joyce and Robbins, 1991; Daum and Ackermann, 1994).Likewise, it is well established that animals with experimentallyinduced lesions of the MDNt show behavioral deficits resemblingthose observed after PFC damage (Goldman et al., 1971; Isseroffet al., 1982; Gabriel, 1993; Harrison and Mair, 1996; Dias andAggleton, 1997; Hunt and Aggleton, 1998). The present findingsare consistent with the hypothesis that an interaction betweenthe MDNt and the PFC forms an important neural component of executiveprocessing in which previously acquired trial-unique informationmust be used to guide memory-based behavior after a delay. Disconnectionsbetween the PFC and the MDNt disrupted foraging during the testphase of the delayed SWSh task, causing a selective increase inacross-phase errors. This pattern of errors suggests that thisthalamocortical pathway is selectively involved in the retrievalof previously acquired information over a delay but not for themonitoring of choices within a trial. This result, in additionto our previous findings (Floresco et al., 1997), is consistentwith the theoretical model of discriminative learning proposedby Gabriel (1990, 1993) and Freeman et al. (1996), which positsthat topographically organized patterns of neural activity, spanningacross a distributed neural circuit connecting the hippocampus,the MDNt, and cingulate cortex, mediates "working memory involvedwith context-based retrieval for relatively brief time intervals(minutes to hours)" (Freeman et al., 1996, p 1548). With respectto the delayed SWSh task, it is apparent that the synchronousconvergence to the PFC of inputs originating in the hippocampus,the ventral tegmental area, and the MDNt is essential for thecontext-dependent retrieval and manipulation of recently acquiredinformation. Subsequently, this information is integrated intoa prospective foraging strategy that guides the animals towardarms that are predicted to contain food. The transformation ofthis strategy into behavioral output is mediated by an interactionbetween the PFC and the N.Acc. Furthermore, recent evidence suggeststhat the ventral striatum can interact with the ventral pallidum(Floresco et al., 1999) and the pedunculopontine nuclei (Winnand Keating, 1998), forming a subsequent stage of limbic-motorintegration (Fig. 6).

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Figure 6. Summary diagram of the neural regions involved in delayed SWSh behavior. See General Discussion for details. VTA, Ventral tegmental area; MD Thalamus, mediodorsal thalamus; VP, ventral pallidum; PPTg, pedunculopontine nuclei.

Further insight into the specific contribution of the MDNt to the executive processes that are engaged during the delayedSWSh task comes from electrophysiological recording studies inawake rodents. During conditional discrimination tasks, neuronsin the MDNt or the PFC show a selective increase in activity whenthe animal is presented with a simple or configural conditionalstimulus that is predictive of a motivationally significant event(e.g., shock or reinforcement) (Gabriel, 1990, 1993; Freeman etal., 1996; Oyoshi et al., 1996). These selective increases inneural activity by MDNt neurons suggest that these cells encodethe motivational significance of particular stimuli in an environment.Moreover, these increases in neural activity occur shortly beforean appropriate motor response is initiated. The increase in discriminatoryneural activity in the MDNt precedes that observed in the PFC,and lesions to the MDNt abolish increased activity in PFC neurons(Gabriel, 1990), suggesting that information is transferred fromthe MDNt to the PFC when an animal discriminates between variousstimuli. A neural system such as this, which is activated selectivelywhen an animal is presented with stimuli that are predictive offorthcoming motivationally relevant events, is similar to theproposed "selective attention" module of the central executive(Baddeley, 1998). A selective attention mechanism, mediated bythalamocortical circuits, working in concert with hippocampalinputs that provide spatial and contextual information to thePFC, would facilitate the recognition of particular stimuli thathave motivational significance. This concept is consistent withthe theoretical framework of Fuster (1997), in which the presentationof specific external stimuli that are signals for prospectiveaction could activate a distributed cortical and subcortical network(including the PFC, hippocampus, and MDNt), which represents thataction, and then prepare the motor systems (including the ventralstriatum) for the appropriate response. In the context of thepresent study, asymmetrical lesions would prevent the transferof information concerning the "stimulus significance" (Oyoshiet al., 1996) of individual arms on the maze from the MDNt tothe PFC, thereby impairing the rat's ability to attend to andsubsequently enter arms that are predicted to contain food (Fig.6).

Different neural circuits mediate different forms of working memory

It is becoming increasingly apparent that working memory is not a unitary phenomenon but rather a collection of distinct yetinterrelated cognitive processes that facilitate the transformationof memory into action (Baddeley and Della Sala, 1996; Fuster,1997; Goldman-Rakic, 1998; Callicott et al., 1999). It followstherefore that these different types of working memory are mediatedby distinct neural circuits. One subtype of working memory discussedfrequently in the rodent literature, derived from the originalconcept of Honig (1978) and developed further by Olton and Papas(1979), refers to the use of a simple retrospective strategy thatcan be used for the "remembrance of places past" (Olton and Samuelson,1976). It is well established that this form of spatial workingmemory is mediated primarily by the hippocampal formation (Oltonand Papas, 1979; Packard et al., 1989; Floresco et al., 1997)and not the PFC or the MDNt. A more complex form of working memory,discussed more frequently in primate and human studies, refersto the storage, manipulation, and use of recently acquired informationto guide prospective action. These processes are more akin tothe models of working memory put forth by Baddeley (1998), Fuster(1997), and Goldman-Rakic (1998), in which a central executivemanipulates information stored in a short-term memory buffer toguide action. This is similar to the "working-with-memory" conceptof Winocur (1992). This form of working memory is essential forcognitive processes used during delayed response tasks, includingthe delayed SWSh task used in the present study, and is subservedby a more complex prefrontal cortical neural network linked tohippocampus and the MDNt. It is important to note that althoughthese different types of working memory use different neural circuitsfor the respective cognitive operations needed to solve problemsrequiring retrospective versus prospective strategies, both systemsmust interact with the same subcortical, striatal, pallidal, andmesencephallic output regions to transform these processes intobehavioral responses (Seamans and Phillips, 1994; Floresco etal., 1997, 1999; Keating and Winn, 1998; Winn and Keating., 1998).

  FOOTNOTES

Received Aug. 12, 1999; revised Oct. 5, 1999; accepted Oct. 7, 1999.

This research was supported by a grant from the Natural Sciences and Engineering Research Council of Canada to A.G.P. S.B.Fis a recipient of a University Graduate Fellowship. We wish thankSheheen Mithani and Kam Brar for their assistance with behavioraltesting and Jeremy K. Seamans for useful discussions. Part ofthis paper were presented in abstract form at the 27th AnnualMeeting of the Society for Neuroscience, San Diego, CA,1997.
Correspondence should be addressed to Anthony G. Phillips, Department of Psychology, University of British Columbia, 2136West Mall, Vancouver, BC, Canada V6T 1Z4. E-Mail: stanbf{at}unixg.ubc.ca.

Ms. Braaksma's present address: Dalhousie University, Halifax, Nova Scotia, Canada B3H1J4.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
EXPERIMENT 1: REVERSIBLE,...
EXPERIMENT 2: DISCONNECTION...
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REFERENCES

Baddeley AD (1986) In: Working memory. Oxford: Clarendon.
Baddeley AD (1998) Recent developments in working memory. Curr Opin Neurobiol 8:234-238[ISI][Medline].
Baddeley A, Della Sala S (1996) Working memory and executive control. Philos Trans R Soc Lond B Biol Sci 351:1397-1404[ISI][Medline].
Batuev AS, Kurina NP, Shutov AP (1990) Unit activity of the medial wall of the frontal cortex during delayed performance in rats. Behav Brain Res 41:95-102[ISI][Medline].
Beckstead RM (1978) Afferent connections of the entorhinal area in the rat as demonstrated by retrograde cell-labeling with horseradish peroxidase. Brain Res 152:249-264[ISI][Medline].
Berendse HW, Groenewegen HJ (1990) Organization of the thalamostriatal projections in the rat, with special emphasis on the ventral striatum. J Comp Neurol 299:187-228[ISI][Medline].
Bogousslavsky J, Ferrazzini M, Regli F, Assal G, Tanabe H, Delaloye-Bischof A (1988) Manic delirium and frontal-like syndrome with paramedian infarction of the right thalamus. J Neurol Neurosurg Psychiatry 51:116-119[Abstract].
Brog JS, Salyapongse A, Deutch A, Zahm DS (1993) The pattern of afferent innervation of the core and shell in the "accumbens" part of the ventral striatum: immunohistochemical detection of retrogradely transported fluoro-gold. J Comp Neurol 338:255-278[ISI][Medline].
Callicott JH, Mattay VS, Bertolino A, Finn K, Coppola R, Frank JA, Goldberg TE, Weinberger DR (1999) Physiological characteristics of capacity constraints of working memory as revealed by functional MRI. Cereb Cortex 9:20-26[Abstract/Free Full Text].
Conde F, Maire-Lepoivre E, Audinat E, Crepel F (1995) Afferent connections of the medial frontal cortex of the rat. II. cortical and subcortical afferents. J Comp Neurol 325:567-593.
Cook RG, Brown RF, Riley DA (1985) Flexible memory processing by rats: use of prospective and retrospective information in the radial arm maze. J Exp Psychol Anim Behav Process 11:453-469[Medline].
Daum I, Ackermann H (1994) Frontal-type memory impairment with thalamic damage. Int J Neurosci 77:187-198[ISI][Medline].
Dias R, Aggleton JP (1997) A comparison of the effects of prelimbic and anterior cingulate cortex lesions in the rat. Soc Neurosci Abstr 23:1606.
Dunnett SB (1990) Role of the prefrontal cortex and striatal output systems in short-term memory deficits associated with aging, basal forebrain lesions, and cholinergic-rich grafts. Can J Psychiatry 44:210-232.
Floresco SB, Seamans JK, Phillips AG (1997) Selective roles for hippocampal prefrontal cortical, and ventral striatal circuits in radial-arm maze tasks with or without a delay. J Neurosci 17:1880-1890[Abstract/Free Full Text].
Floresco SB, Braaksma DN, Phillips AG (1999) Involvement of the ventral pallidum in working memory tasks with or without a delay. Ann NY Acad Sci 877:711-716[Free Full Text].
Freeman JH, Cuppernell C, Flannery K, Gabriel M (1996) Context-specific multi site cingulate cortical, limbic thalamic, and hippocampal neuronal activity during concurrent discriminative approach and avoidance training in rabbits. J Neurosci 16:1538-1549[Abstract/Free Full Text].
Fuster JM (1995) In: Memory in the cerebral cortex: an emperical approach to neural networks in the human and nonhuman primate. Cambridge, MA: MIT.
Fuster JM (1997) Network memory. Trends Neurosci 20:451-459[ISI][Medline].
Fuster JM, Bauer RH, Jervey JP (1985) Functional interactions between inferotemporal and prefrontal cortex in a cognitive task. Brain Res 330:299-307[ISI][Medline].
Gabriel M (1990) Functions of anterior and posterior cingulate cortex during avoidance learning in rabbits. In: Progress in brain research, Vol 85 (Uylings HBM, Van Eden CG, De Bruin JPC, Corner MA, Feeustra MGP, eds), pp 467-483. Amsterdam: Elsevier.
Gabriel M (1993) In: Discriminative avoidance learning: a model system. In: Neurobiology of the cingulate cortex and limbic thalamus: a comprehensive handbook (Vogt BA, Gabriel M, eds), pp 478-523. Boston: Birkhäuser.
Gallassi R, Morreale A, Montagna P, Gambetti P, Lugaressi E (1992) "Fatal familial insomnia": neuropsychological study of a disease with thalamic degeneration. Cortex 28:175-187[ISI][Medline].
Goldman PS, Rosvold HE, Vest B, Galkin TW (1971) Analysis of the delayed-alternation deficit produced by dorsolateral prefrontal lesions in the rhesus monkey. J Comp Physiol Psychol 77:212-220[ISI][Medline].
Goldman-Rakic PS (1987) Circuitry of the prefrontal cortex an