Coding and Monitoring of Motivational Context in the Primate Prefrontal Cortex

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The Journal of Neuroscience, March 15, 2002, 22(6):2391-2400

Coding and Monitoring of Motivational Context in the Primate Prefrontal Cortex
Masataka Watanabe¹, Kazuo Hikosaka¹, Masamichi Sakagami¹^,², and Shu-ichiro Shirakawa¹^,³
¹ Department of Psychology, Tokyo Metropolitan Institute for Neuroscience, Fuchu, Tokyo 183-8526, Japan, ² Brain Science Research Center, Tamagawa University Research Institute, Machida, Tokyo 194-8610, Japan, and ³ Division of Geriatric Mental Health, National Institute of Mental Health, National Center of Neurology and Psychiatry, Ichikawa, Chiba 272-0827, Japan

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The prefrontal cortex is involved in acquiring and maintaining information about context, including the set of task instructionsand/or the outcome of previous stimulus-response sequences. Moststudies on context-dependent processing in the prefrontal cortexhave been concerned with such executive functions, but the prefrontalcortex is also involved in motivational operations. We thus wishedto determine whether primate prefrontal neurons show evidenceof representing the motivational context learned by the monkey.We trained monkeys in a delayed reaction task in which an instructioncue indicated the presence or absence of reward. In random alternationwith no reward, the same one of several different kinds of foodand liquid rewards was delivered repeatedly in a block of ~50trials, so that reward information would define the motivationalcontext. In response to an instruction cue indicating absenceof reward, we found that neurons in the lateral prefrontal cortexnot only predicted the absence of reward but also representedmore specifically which kind of reward would be omitted in a giventrial. These neurons seem to code contextual information concerningwhich kind of reward may be delivered in following trials. Wealso found prefrontal neurons that showed tonic baseline activitythat may be related to monitoring such motivational context. Thedifferent types of neurons were distributed differently alongthe dorsoventral extent of the lateral prefrontal cortex. Suchoperations in the prefrontal cortex may be important for the monkeyto maximize reward or to modify behavioral strategies and thusmay contribute to executivecontrol.

Key words: context; reward; motivation; prefrontal cortex; monkey; delayed reaction task

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

It is well established that the lateral part of the prefrontal cortex (LPFC) plays important roles in executive control, suchas planning, problem solving, and behavioral inhibition (Luria,1980; Stuss and Benson, 1986; Grafman et al., 1995; Shallice andBurgess, 1996; Fuster, 1997). It has been proposed that such executivefunctions are supported by the ability of the LPFC to acquireand represent task-relevant context information, consisting ofthe set of task instructions and/or the outcome of previous stimulus-responsesequences (Pribram, 1971; Cohen et al., 1996). The activity ofLPFC neurons is context dependent; they show differential activityto identical visual cues depending on the task requirement (Nikiand Watanabe, 1976; Asaad et al., 2000; Wallis et al., 2001),or they show different patterns of activity changes dependingon the way cues are presented in a delayed response task (Watanabe,1996).

Although the LPFC has been investigated mostly in relation to its executive functions (Roberts et al., 1998; Schneider etal., 2000), the LPFC is also involved in motivational operations.Although the orbitofrontal cortex (OFC) is indicated to be moreconcerned with motivational operations than the LPFC (Stuss andBenson, 1986; Damasio, 1994; Fuster, 1997), a noninvasive studyhas shown activations of the LPFC, as well as of the OFC in relationto motivational operations, e.g., delivery of monetary reward(Thut et al., 1997). Neuronal activity related to reward and/orexpectancy of reward is observed in the LPFC, as well as the OFC,of the monkey (Niki and Watanabe, 1979; Rosenkilde et al., 1981;Watanabe, 1996; Leon and Shadlen, 1999; Tremblay and Schultz,1999, 2000; Hikosaka and Watanabe, 2000). Thus, given that theLPFC represents task-relevant context information, as well asinformation about rewards, we hypothesized that these two typesof processes may be integrated in the LPFC to generate motivationalcontext.

To test this hypothesis, we devised a paradigm in which the monkey could expect different kinds of rewards depending on thecontext. We trained the monkey in a delayed reaction task in whichthe instruction cue indicated whether a reward would be deliveredrather than which response the monkey should make. In random alternationwith no reward, the same one of several different kinds of rewardswas repeatedly delivered in a block of ~50 trials. In this way,the monkey would have context information concerning which rewardcould or could not be expected in any given trial within ablock.

We wished to determine how such context information is represented in neuronal activities of the LPFC. In response to a cuepresentation indicating future no reward, we found that LPFC neuronsnot only predicted the absence of reward but also representedmore specifically which kind of reward would be omitted. Theseneurons seem to code contextual information concerning which rewardmay be delivered in subsequent trials. We also found LPFC neuronsshowing tonic baseline activity that may be related to monitoringof motivationalcontext.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects and behavioral training. Three male Japanese monkeys (Macaca fuscata) weighing 5.5-6.5 kg were used in the experiment.Monkeys were trained on a delayed reaction task. The monkey faceda panel that was placed at 33 cm from the monkey at eye leveland on which a rectangular window (6 × 7.5 cm), a circular key(5 cm in diameter), and a holding lever (5 cm wide, protruding5 cm) were vertically arranged (Fig. 1). The window containedone opaque screen and one transparent screen with thin verticallines. The monkey first depressed the lever for 10-12 sec (Pre-Inst).Then the opaque screen was raised and revealed a food tray for1 sec with (rewarded trial) or without (unrewarded trial) a rewardbehind the transparent screen as an instruction (Inst) (Fig. 1a,Visible food). After a delay of 5 sec (Delay), a white light appearedon the key as a go signal (Go Signal). When the monkey releasedthe hold lever and pressed the key within 2 sec after the go signal,both screens were raised and the monkey either collected the foodreward (rewarded trials) or went unrewarded (unrewarded trials)depending on the trial type. Rewarded and unrewarded trials alternatedpseudorandomly at a ratio of 3:2. The monkey had to press thekey even on unrewarded trials to advance to the next trial. Themonkey was also trained in other task situations in which a colorinstruction (red or green) of 1 sec duration on the key indicatedwhether a reward would be delivered (Fig. 1b, Cued food, c, Cuedliquid). In the cued food task, depending on the instruction,food reward could be collected (rewarded trials) or not (unrewardedtrials) behind the screens at the end of the trial. In the liquidreward task, the window was kept closed throughout the trial,and a drop of liquid was delivered through a spout close to themonkey's mouth (rewarded trials) or not (unrewarded trials). Pieces(~0.5 gm) of raisin, sweet potato, cabbage, or apple were usedas food rewards. Drops (0.3 ml) of water, sweet isotonic beverage,orange juice, or grape juice were used as liquid rewards. Thesame reward was used for a block of ~50 trials, so that the usedreward would define the motivational context for the current blockof trials. The monkey was not required to perform any differentialoperant action related to differences between rewards. On foodreward tasks, both windows were closed when the monkey returnedits hand to the holding lever after the key press. The trial wasaborted when the monkey released the hold lever before the gosignal. From time to time, the meaning of the color cue (red orgreen) was reversed after a block of ~100-200 trials in the cuedfood or cued liquid task. Monkeys were also trained on a right-leftdelayed response task, and part of the results obtained in thistask was presented previously (Watanabe, 1996). The task was controlledby a personal computer (PC9801FA; NEC, Tokyo, Japan). No attemptwas made to restrict or control the monkey's eye movements. Onweekdays, the monkeys received their daily liquid requirementwhile performing the task. Water was available ad libitum duringweekends. Monkey pellets were available ad libitum at the homecage at all times, whereas more preferable foods were used asrewards in the laboratory.

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Figure 1. Sequence of events in the three different kinds of delayed reaction tasks (a, Visible food; b, Cued food; c, Cued liquid). For each task, the top panel indicates rewarded trials, whereas the bottom panel indicates unrewarded trials. Inst, Instruction; Resp, response; R, red light cue; G, green light cue.

Reward preference tests. Preferences for different kinds of food rewards by individual monkeys were examined by free choicetests among different kinds of foods and by choice tests betweeneach pair. Preferences for different kinds of food or liquid rewardswere also examined by testing the monkey's willingness to performthe task with one kind of reward after refusing to perform itwith another kind ofreward.

Surgery and recording. On completion of training, the monkey was surgically prepared under sodium pentobarbital anesthesia(Nembutal; 30 mg/kg, i.p.). A stainless steel cylinder (18 mmin diameter) was implanted as a microdrive receptacle at appropriatelocations on the skull. A hollow rod (15 mm in diameter) for headfixation was attached to the skull using dental acrylic. Antibioticswere administered for 10 d postoperatively. During recording sessions,the monkey's head was rigidly fixed to the frame of the monkeychair by means of the head holder, and a hydraulic microdrive(MO95-C; Narishige, Tokyo, Japan) was attached to the implantedcylinder. Elgiloy electrodes (Suzuki and Azuma, 1976) were usedfor recording. Neuronal activity was recorded from the principalis,inferior convexity, and arcuate areas of the LPFC of both hemispheresof three monkeys. Because we were interested in how motivationalcontext is represented in the LPFC, we focused on reward-relatedneurons. This caused sampling bias. Action potentials were passedthrough a window discriminator and converted into square-wavepulses. The action potentials, shaped pulses, and task eventswere monitored on a computer display and stored on a digital datarecorder (PC208A; Sony, Tokyo, Japan). Data on shaped pulses andtask events were also stored on magneto-optical disks for off-lineanalysis. During the recording, we changed the type of task and/orthe type of reward approximately every 50 trials. After havingexamined each neuron on one kind of reward, we tested the sameneuron on the same kind of reward at several separate times toascertain the stability and consistency of neuronal activity,(1) from time to time by visually inspecting the activity forfour to five trials and (2) as far as possible by recoding theactivity for another 50 trials. Because we concentrated on examiningneuronal activity in relation to changing the reward block ratherthan in relation to the reversal of the meaning of the instructioncue, we did not extensively examine each neuron in the reversal(green instruction) situation. We monitored the position and movementof the monkey's eyes with an infrared eye-camera system (samplingrate, 4 msec; R-21C-A, RMS, Hirosaki, Japan) during the task performanceafter the neuronal recording experiment was over. The data werestored on a digital data recorder. We examined how long the monkeylooked at the instructional cue during the instruction periodby measuring the total time when the eye was located within avertical window of 5 × 5° around the instruction cue. We alsoexamined the frequency of saccadic eye movements during the delayperiod by counting the number of saccades whose magnitudes wereof >10°.

Histology. After termination of recording, the monkeys were deeply anesthetized with sodium pentobarbital (45 mg/kg) and perfusedwith saline, followed by 10% formalin. The brains were frozenand sectioned in the coronal plane (50 µm). Electrode tracks werereconstructed from traces of electrode penetrations and electrolyticlesions that had been made at selected penetration sites at theend of a recordingsession.

Data analysis. Impulse data were displayed as raster display and frequency histograms. Nonparametric statistics were usedfor analysis. The data on the initial few trials after changingthe kind of task and/or the kind of reward were omitted from analysis.Magnitudes of neuronal activity in relation to task events (preinstruction,instruction presentation, delay, go signal, monkey's key pressresponse, reward delivery, and no-reward delivery) were firstcompared with control activity (2-3 sec before the instruction)within the same block of trials, separately for rewarded and unrewardedtrials by the Mann-Whitney U test. The criterion for statisticalsignificance was set at p < 0.05 (two tailed). Then the magnitudesof neuronal activity in relation to each task event (includingthe control period) were compared between rewarded and unrewardedtrials by the U test and among different reward blocks by theKruskal-Wallis H test. The U test served for post hoc analysisafter a significant difference was observed on the H test. Reactiontime (RT) (the time between the go signal presentation and themonkey's key press) data were also examined by nonparametric Uand H tests. All experiments were conducted following the NationalInstitutes of Health guidelines for animal experiments and wereapproved by the ethics committee of ourinstitute.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Behavioral results

Reward preference tests revealed that the monkeys consistently preferred cabbage and apple to potato to raisin within foodrewards (>95% on free choice tests). Preferences for cabbage andapple did not significantly differ. Among liquid rewards, theyinvariably preferred grape juice, orange juice, and isotonic beverageto water, and they preferred grape juice to orange juice and isotonicbeverage. It was found that RTs of the monkey were influencedby the reward used in each trial. Details of RT data were presentedseparately (Watanabe et al., 2001). RTs of the monkey were significantlyshorter on rewarded than on unrewarded trials on any kind of rewardblock. RTs were shorter when a highly preferred reward was usedcompared with a less preferred reward, on rewarded and/or on unrewardedtrials. For example, median (50th percentile) RTs ± quartile deviations((75th $-$ 25th percentiles)/2) observed in one animal for cabbage(most preferred food) and raisin (least preferred food) rewardswere 340 ± 15 versus 370 ± 25 msec on rewarded trials and 440± 53 versus 535 ± 80 msec on unrewarded trials, respectively (Watanabeet al., 2001). Because the monkey's gaze was not controlled, themonkey moved its eyes spontaneously and randomly during the preinstructionand delay periods. At the time of the instruction presentation,an eye movement was elicited to the instruction cue, but the animaldid not continue to fixate it throughout the instruction period.Except for an initial few trials after changing the type of reward,there was no significant difference both in the duration of instruction-lookingtime during the instruction period and in the frequency of saccadiceye movements during the delay period, between rewarded and unrewardedtrials, as well as among different kinds of reward blocks. Medianinstruction-looking time ± quartile deviations during the instructionalperiod in the cued food task on rewarded and unrewarded trialsin one monkey, for example, were 288 ± 72 versus 270 ± 50.5 msecwith raisin, 277 ± 61.5 versus 280 ± 54 msec with potato, and290 ± 62.5 versus 287.5 ± 58 msec with cabbage as reward. Medianfrequency of saccadic eye movements (with amplitudes of >10° degrees)± quartile deviations during the delay period on rewarded andunrewarded trials were 4.5 ± 3.0 and 5.0 ± 2.0 with raisin, 5.5± 3.0 and 4.25 ± 2.0 with potato, and 5.0 ± 1.5 and 4.5 ± 2.0with cabbage as reward. Neither between rewarded and unrewardedtrials (p > 0.05; two-tailed U test) nor among different rewardblocks (p > 0.05; H test) were there significant differences inthesevalues.

Reward-dependent instruction-delay activity

Of 230 task-related LPFC neurons recorded in three monkeys, 179 discriminated between rewarded and unrewarded trials duringthe instruction and/or delay period. One hundred six of them showeda higher firing rate and 69 a lower firing rate on rewarded comparedwith unrewarded trials with any type of reward tested. Four ofthese neurons showed an inconsistent pattern across tasks, inone task firing more and in another task firing less on rewardedtrials than on unrewarded trials. Here we focus on 91 of theseneurons that were examined on several kinds of reward blocks andcould be tested repeatedly on each kind of reward block acrosstime. Of these, 72 (79%) showed instruction and/or delay activitythat differed depending on which particular reward was used ina given block of trials, with the reward effect reproducible acrossrepeatedtests.

The neuron shown in Figure 2a discriminated between rewarded and unrewarded trials as well among different reward blocks.This neuron, which was examined in the visible food task, showeda significantly higher firing rate on rewarded than on unrewardedtrials during the delay period on any kind of reward block (two-tailedU tests; raisin, p < 0.05; potato and cabbage, p < 0.01). On rewardedtrials, this neuron showed significantly different activity changesdepending on the reward block, showing the highest firing ratefor cabbage, an intermediate firing rate for potato, and the lowestfiring rate for raisin as the reward in a block of trials. H testindicated that activity changes of this neuron during the delayperiod were not significantly different on unrewarded trials,whereas they were significantly different on rewarded trials ( $chi$ ² = 31.62; df = 2; p < 0.001) among the three different rewardblocks. Paired comparisons using two-tailed U tests indicatedthat activity changes during the delay period on rewarded trialssignificantly differ between any pair of reward blocks (all pairs,p < 0.01).

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Figure 2. An example of an LPFC neuron that responded differently between rewarded and unrewarded trials, as well as showing differential activity during the delay period on rewarded trials depending on the reward block. a shows the activity of this neuron when examined for the first time on each reward block. b shows the activity for the same neuron examined at a later time, after being examined on several kinds of liquid rewards. For both a and b, neuronal activity is shown separately for each reward block in raster and histogram displays, with the top display for rewarded trials and the bottom display for unrewarded trials. For each display, the first two vertical lines from the left indicate instruction onset and offset, and the third line indicates the end of the delay period. Each row indicates one trial. The reward used is stated. Leftmost scales indicate impulses per second, and the time scale at the bottom indicates 1 sec. I, Instruction; D, delay; Reward, rewarded trials; No reward, unrewarded trials.

Figure 2b shows the activity of the same neuron when we repeated the tests in the visible food task after having examinedit on several kinds of liquid rewards. On these repeated testsalso, this neuron showed a significantly higher firing rate onrewarded than on unrewarded trials during the delay period onany kind of reward block (U tests; raisin, p < 0.05; potato andcabbage, p < 0.01). H test indicated that activity changes ofthis neuron during the delay period were not significantly differenton unrewarded trials, whereas they were significantly differenton rewarded trials ( $chi$ ² = 14.63; df = 2; p < 0.001) among the three different rewardblocks. Paired comparisons indicated that activity changes duringthe delay period on rewarded trials significantly differ betweenany pair of reward blocks (raisin vs potato, p < 0.05; raisinvs cabbage and potato vs cabbage, p < 0.01). This figure demonstratesthat this neuron consistently discriminated between rewarded andunrewarded trials, as well as among different reward blocks, asconfirmed by repeatedtests.

The neurons in Figure 3 showed activations only on unrewarded trials during the instruction period (a) or during the delayperiod (b). Considering only unrewarded trials, the neuron inFigure 3a, which was examined in the visible food task, showedthe highest firing rate when cabbage and the lowest firing ratewhen raisin was used as reward in a block of trials. Statisticaltests revealed that this neuron showed a significantly higherfiring rate during the instruction period on unrewarded than onrewarded trials on any reward block (all food blocks, p < 0.01).H test indicated that activity changes of this neuron during theinstruction period were not significantly different on rewardedtrials, whereas they were significantly different on unrewardedtrials ( $chi$ ² = 15.54; df = 2; p < 0.001) among the three different rewardblocks. Paired comparisons using U tests indicated that therewere significant differences in activity changes during the instructionperiod on unrewarded trials between raisin and potato (p < 0.01),as well as between raisin and cabbage (p < 0.01), but not betweenpotato and cabbage reward blocks.

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Figure 3. Example of LPFC neurons that showed significant activations during the instruction (a) or during the delay (b) period only on unrewarded trials and showed differential activity depending on the reward block. In a, neuronal activity is shown for 4 sec, whereas in b, it is shown for 12 sec. Isotonic, Sweet isotonic beverage reward. Conventions are as in Figure 2.

Similarly, the neuron in Figure 3b, examined in the cued liquid task, was sensitive to the reward context only on unrewardedtrials, showing the highest firing rate when grape juice and thelowest firing rate when water was used as reward in a block oftrials. Statistical tests indicated that the neuron also showeda significantly higher firing rate during the delay period onunrewarded than on rewarded trials on any reward block (all liquidblocks, p < 0.01). H test indicated that activity changes of thisneuron during the delay period were not significantly differenton rewarded trials, whereas they were significantly differenton unrewarded trials ( $chi$ ² = 20.22; df = 2; p < 0.001) among the three different rewardblocks. Paired comparisons using U tests indicated that therewere significant differences in activity changes during the delayperiod on unrewarded trials between any pair of reward blocks(water vs isotonic and water vs grape, p < 0.01; isotonic vs grape,p < 0.05).

Reward-discriminative LPFC activity (depending on the type of reward used in a block of trials) appeared to be related tothe monkey's preference among different types of reward. Among72 LPFC neurons examined, eight neurons showed reward-discriminativeactivity only on rewarded trials (Fig. 2), 14 only on unrewardedtrials (Fig. 3), and 50 on both rewarded and unrewarded trials(Fig. 4) (see Fig. 6). A majority of them (55 of 72, 76.4%; 6of 8, 8 of 14, and 41 of 50) showed a higher firing rate (Figs.2, 3) (see Fig. 6), whereas 13 of them (2 of 8, 6 of 14, and 5of 50) showed a lower firing rate on more preferred reward blocksthan on less preferred reward blocks. Four neurons (5.6%) showeda complex activity pattern, with different directions on rewardedversus unrewarded trials: on rewarded trials, a higher firingrate and, on unrewarded trials, a lower firing rate for the morepreferred reward blocks than for the less preferred reward blocks.Figure 4 shows such an example, which was examined in the visiblefood task. On rewarded trials, this neuron showed the highestactivity in the apple block and the least activity in the raisinblock. In contrast, on unrewarded trials, the neuron showed thehighest activity in the raisin block and the least activity inthe apple block. Statistical tests revealed that this neuron showeda significantly higher firing rate during the instruction anddelay periods on rewarded than on unrewarded trials on any rewardblock (all reward blocks, p < 0.01). H tests revealed that thisneuron showed significantly different activity changes among thethree different reward blocks both on rewarded ( $chi$ ² = 35.61; df = 2; p < 0.001) and unrewarded ( $chi$ ² = 9.45; df = 2; p < 0.01) trials. Paired comparisons among differentreward blocks showed that this neuron showed significantly differentfiring rates between any pair of reward blocks on rewarded trials(all pairs, p < 0.01), as well as on unrewarded trials (raisinvs apple, p < 0.01; raisin vs potato and potato vs apple, p <0.05). None of the 72 reward-discriminative neurons showed instruction-delayactivity changes exclusively in a particular reward block withoutshowing activity changes in other reward blocks.

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Figure 4. An example of an LPFC neuron that showed differential activity depending on the reward block, during both the instruction and delay periods on both rewarded and unrewarded trials. This neuron showed greater activation on rewarded trials and less activation on unrewarded trials as more preferred rewards were used within the block. Conventions are as in Figure 2.

Neither among rewarded trials nor among unrewarded trials within a certain reward block was there significant correlationbetween RT and the magnitude of neuronal activity during the instruction-delayperiods in all 72 neurons examined, whereas there were sometimessignificant correlations between them when both rewarded and unrewardeddata were combined, probably because of the large differencesin both RT and the magnitude of neuronal activity between rewardedand unrewardedtrials.

Reward discriminability of prefrontal neurons

We qualitatively examined whether the discriminability of LPFC neurons between rewarded and unrewarded trials differed dependingon what reward was used in a block of trials, more specificallydepending on whether the reward was the most preferred or theleast preferred by the monkey within a task. To do so, we calculatedthe "reward-no reward discrimination index (RNRDI)" of individualneurons for each kind of reward block using the following formula:RNRDI = (absolute value) (rewarded $-$ unrewarded)/(rewarded + unrewarded)(absolute value), where "rewarded" and "unrewarded" indicate themean discharge rate during the cue and delay periods in a certainreward block for rewarded and unrewarded trials, respectively.We also examined whether the discriminability of LPFC neuronsbetween two different kinds of reward blocks, more specificallybetween the monkey's most preferred and the least preferred rewardblocks within a task, on rewarded trials differed from that onunrewarded trials. To do so, we calculated the "reward differencediscrimination index (RDDI)" of individual neurons, separatelyfor rewarded and unrewarded trials, using the following formula:RDDI = (absolute value) (preferred $-$ unpreferred)/(preferred +unpreferred) (absolute value), where "preferred" and "unpreferred"indicate the mean discharge rate during the cue and delay periodsfor the monkey's most preferred and the least preferred rewardblocks within a task, respectively. Both indices were calculatedfrom data obtained in 29 LPFC neurons that were examined on boththe most preferred (cabbage or grape juice) and the least preferred(raisin or water) rewards in one or more of the three kinds oftasks. Both indices ranged from 0 to 1, with the larger valueindicating greater discriminability between rewarded and unrewardedtrials (RNRDI) for a certain kind of reward block and greaterdiscriminability between preferred and unpreferred reward blocks(RDDI) within atask.

In Figure 5a, RNRDI values of individual LPFC neurons on the unpreferred reward block are plotted against those on the preferredreward block separately for three different kinds of tasks. MedianRNRDI values ± quartile deviations on preferred and unpreferredreward blocks were 0.196 ± 0.171 and 0.189 ± 0.088 in the cuedliquid, 0.162 ± 0.181 and 0.265 ± 0.139 in the visible food, and0.190 ± 0.089 and 0.250 ± 0.091 in the cued food task, respectively.There was no significant difference in this value (U test; p >0.05) between preferred and unpreferred reward blocks for anykind of task. However, there were significant correlations inRNRDI value between preferred and unpreferred reward blocks inLPFC neurons, with correlation coefficients being 0.815 in thecued liquid, 0.812 in the visible food, and 0.831 in the cuedfood tasks. Thus, discriminability of LPFC neurons between rewardedand unrewarded trials on the preferred reward block did not differfrom that on the unpreferred reward block. Also, there was nosignificant difference in RNRDI value for both preferred and unpreferredfood reward blocks between the visible food and cued food tasks,indicating that discriminability of LPFC neurons between rewardedand unrewarded trials was not dependent on whether food itselfor a vacant food tray was presented as an instruction or simplya color instruction indicated the presence or absence of a reward.

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Figure 5. Discriminability of LPFC neurons (a) between rewarded and unrewarded trials observed on preferred and unpreferred reward blocks and that (b) between preferred and unpreferred reward blocks observed on rewarded and unrewarded trials. a, RNRDI values of individual LPFC neurons on the unpreferred reward block are plotted against those on the preferred reward block. b, RDDI values of individual LPFC neurons on unrewarded trials are plotted against those on rewarded trials. For both a and b, filled squares indicate data in the cued liquid task, open triangles in the visible food task, and open circles in the cued food tasks, respectively. Dashed line indicates 45° line.

In Figure 5b, RDDI values of individual LPFC neurons on unrewarded trials are plotted against those on rewarded trials separatelyfor three different kinds of tasks. Median RDDI values ± quartiledeviations on rewarded and unrewarded trials were 0.216 ± 0.110and 0.228 ± 0.097 in the cued liquid, 0.239 ± 0.120 and 0.1615± 0.075 in the visible food, and 0.186 ± 0.103 and 0.159 ± 0.101in the cued food task, respectively. There was no significantdifference in this value between rewarded and unrewarded trialsfor any kind of task. However, there were significant correlationsin RDDI value between rewarded and unrewarded trials in LPFC neurons,with correlation coefficients being 0.680 in cued liquid, 0.320in visible food, and 0.821 in cued food tasks. Thus, discriminabilityof LPFC neurons between preferred and unpreferred reward blockson rewarded trials (in which the monkey could expect actual rewarddelivery) did not differ from that on unrewarded trials (in whichthe animal could expect no reward). There was also no significantdifference in RDDI value for both rewarded and unrewarded trialsbetween the visible food and cued food tasks, indicting that discriminabilityof LPFC neurons between preferred and unpreferred reward blockswas not dependent on whether food itself or color cue was presentedas aninstruction.

Reward context monitored in baseline activity

Among different reward blocks, we compared baseline activities of LPFC neurons during the 3 sec preinstruction period, aswell as during all periods throughout the trial (from the preinstructionperiod to the monkey's response). We found that 28 of 72 reward-discriminativeinstruction-delay LPFC neurons also showed differences in baselineactivity, during the preinstruction period and often even throughoutthe entire trial, among different reward blocks (Fig. 6). Therelative magnitude of neuronal activity during the instruction-delayperiods compared with the preinstruction period differed significantlyamong different reward blocks for 11 neurons. However, the relativemagnitude was not significantly different for the remaining 17neurons whose reward-discriminative activity during the instruction-delayperiods directly reflected differences in the preinstruction baselinelevel (Fig. 6). Statistical tests indicated that the preinstructionactivity of this neuron, which was examined in the cued food task,differed significantly among the three different reward blocks( $chi$ ² = 19.2; df = 2; p < 0.001). Paired comparisons among differentreward blocks indicated that there were significant differencesin preinstruction activity between any pair of reward blocks (allpairs, p < 0.01). This neuron showed a significantly higher firingrate on unrewarded than on rewarded trials during the instructionand delay periods on any kind of reward block (all reward blocks,p < 0.01). This neuron showed significantly different activitychanges during the instruction and delay periods among the threedifferent reward blocks on both rewarded ( $chi$ ² = 29.44; df = 2; p < 0.001) and unrewarded ( $chi$ ² = 14.38; df = 2; p < 0.001) trials. Paired comparisons amongdifferent reward blocks revealed that this neuron showed significantlydifferent firing rates between raisin and potato (p < 0.01), aswell as between raisin and cabbage (p < 0.01), but not betweenpotato and cabbage reward blocks on rewarded trials, while showingsignificantly different firing rates between any pair of rewardblocks on unrewarded trials (raisin vs potato and raisin vs cabbage,p < 0.01; potato vs cabbage, p < 0.05) during the instructionand delay periods.

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Figure 6. An example of an LPFC neuron showing differential preinstruction baseline activity depending on the reward block. This neuron also showed differential activity during the cue and delay periods depending on the reward block on both rewarded and unrewarded trials. For this neuron, the activity is shown from 9 sec before the instruction presentation to 3 sec after the go signal presentation. Other conventions are as in Figure 2. The magnitude of activity (in impulses per second expressed by median ± quartile deviation) of this neuron during the preinstruction period after rewarded and unrewarded trials were 2 ± 2 and 3 ± 1 for the raisin block, 6 ± 2 and 5 ± 2.5 for the potato block, and 9 ± 2 and 10 ± 4 for the cabbage block, respectively. H test indicated significant differences in preinstruction baseline activity among different reward blocks both for the preinstruction period after rewarded trials ( $chi$ ² = 11.0; df = 2; p < 0.01) and for that after unrewarded trials ( $chi$ ² = 11.9; df = 2; p < 0.01). Paired comparisons using U test indicated significant differences in preinstruction baseline activity between any pair of reward blocks (all pairs, p < 0.01), except that there was no significant difference between potato and cabbage reward blocks after unrewarded trials. However, there was no significant difference in preinstruction baseline activity after rewarded compared with unrewarded trials within any reward block.

In most of these neurons (24 of 28; 85.7%), the magnitude of activity changes during the preinstruction period after rewardedtrials did not significantly differ from that after unrewardedtrials. Only two neurons showed higher activations, whereas theremaining two neurons showed lower activations during the preinstructionperiod after rewarded trials compared with those after unrewardedtrials.

Location of prefrontal neurons responsive to reward context

Histological examination revealed that neurons that showed changes in baseline activity depending on the reward block wereobserved predominantly in and above the upper bank of the principalsulcus (Fig. 7a). Neurons that showed differential activity duringthe instruction-delay periods depending on the kind of rewardused in a block of trials, but did not show differential preinstructionbaseline activity, were observed mostly in and below the lowerbank of the principal sulcus and in the arcuate area of the LPFC(Fig. 7b). We compared the numbers of both types of neurons locatedin and above the upper bank of the principal sulcus with thoselocated in and below the lower bank of the sulcus (excluding thosein the arcuate area) by $chi$ ² test. A significant difference ( $chi$ ² = 14.60; df = 1; p < 0.001) provided statistical support fordifferential distribution between neurons with and without differentialpreinstruction baseline activities.

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Figure 7. a, Locations of penetrations of LPFC neurons that changed their preinstruction baseline activity, with the relative magnitude of neuronal activity during the instruction-delay periods compared with the baseline level being significantly different ( $black-down-triangle$ ) or not () among different reward blocks. b, Locations of penetrations of LPFC neurons that showed instruction-delay-related, but not preinstruction baseline-related, differential activity among different reward blocks only on rewarded ( $open circle$ ), only on unrewarded ( $triangle$ ), or on both rewarded and unrewarded trials (). AS, Arcuate sulcus; PS, principal sulcus.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study examined neuronal activity of the primate LPFC in relation to motivational information during a delayed reactiontask. We found the following. (1) LPFC neurons showed differentialinstruction-delay activity between rewarded and unrewarded trials(Figs. 2-4, 6). (2) On rewarded trials, LPFC neurons showed differentialinstruction-delay activity among different reward blocks (Figs.2, 4, 6). (3) Most importantly, LPFC neurons coded not only theabsence of reward but also which reward would be absent on unrewardedtrials (Figs. 3, 4, 6). (4) Thirty-three percent of reward-discriminativeneurons showed reward block dependent differential preinstructionbaseline activity (Fig. 6), and these neurons were observed predominantlyin and above the upper bank of the principal sulcus (Fig. 7).

We reported previously LPFC neurons that discriminated juice-rewarded and -unrewarded trials (Watanabe, 1990, 1992). We replicatedthe previous finding using several different kinds of food andliquid rewards. We also reported LPFC neurons that showed differentialactivity depending on which reward was expected during a delayedresponse task (Watanabe, 1996). We obtained similar neuronal activitiesin the present nonworking memorytask.

Coding of motivational context in prefrontal neurons

Of particular interest are the LPFC neurons that showed differential activity during the instruction-delay periods on unrewardedtrials depending on the reward block, despite the fact that themonkey could not expect to obtain anything as a reward on unrewardedtrials and the monkey was not required to respond differentlyaccording to the reward information. Each block implied only onepossible kind of reward. With the pseudorandom alternation ofrewarded and unrewarded trials, this task provides a context inwhich neuronal activity in one trial type may be influenced byevents in another trial type. Thus, these neurons may be involvedin coding and representing the motivational context that is incidentallyacquired by themonkey.

Because there are LPFC neurons that retain visual stimuli in working memory (Rosenkilde et al., 1981; Watanabe, 1986; Quintanaet al., 1988; Quintana and Fuster, 1992; Miller et al., 1996;Rao et al., 1997; Rainer et al., 1999), the reward-dependent delayactivity in the present study could also be related to a mentalimage of visual, gustatory, and olfactory aspects of the rewardingobject in rewarded trials and to that of the absence of a particularreward in unrewarded trials. However, there were no neurons thatresponded exclusively to the presence or absence of a particularreward, indicating that the activity of LPFC neurons is not sharplytuned to the stimulus properties of the reward. The activity ofthese neurons was related to the monkey's reward preference asassessed by behavioral tests. Thus, the neuronal activity seemsto reflect rather the motivational value of the outcome, suchas the degree of pleasure or aversion associated with the presenceor absence of a particular reward. A few neurons showed a complexactivity pattern with different directions for rewarded versusunrewarded trials (Fig. 4). Considering that the absence of themore preferred reward would be more disappointing for the monkeythan the absence of the less preferred reward, the neuron activitymay reflect the degree of desirability of the outcome associatedwith the presence or absence of a specificreward.

The discriminability of LPFC neurons between rewarded and unrewarded trials did not differ depending on the reward block (Fig.5a), indicating that the discrimination by LPFC neurons betweenrewarded and unrewarded trials was not facilitated by using themore preferable reward. The discriminability of LPFC neurons betweenpreferred and unpreferred reward blocks on unrewarded trials didnot differ from that on rewarded trials (Fig. 5b). Also, the discriminabilitydid not differ between the visible food and cued food tasks. Thus,activity of reward-discriminative LPFC neurons seems to dependmore on the motivational context, i.e., what reward is used ina current block of trials, rather than on the presence or absenceof the reward in each trial or on whether the instruction is anactual food or colorcue.

Both prefrontal neuronal activity and RTs varied depending on the reward block. However, neither in rewarded nor in unrewardedtrials within a certain reward block was there significant correlationbetween the magnitude of neuronal activity and the monkey's RT.Thus, the reward-discriminative instruction-delay activities shouldnot be directly associated with differences in behavioralreactions.

There are LPFC neurons that show fixation-related (Suzuki and Azuma, 1977) and saccade-related (Funahashi et al., 1991) activitychanges in task situations in which the monkey is required tocontrol eye position. However, when the monkey was not requiredto control eye position to obtain reward, there were no significantdifferences in eye movements between rewarded and unrewarded trialsnor among different reward blocks. Thus, the observed reward-discriminativeneuronal activities do not reflect the monkey's eyemovements.

Monitoring of motivational context in prefrontal neurons

Simulation studies indicate that the prefrontal cortex is indispensable for representing and maintaining context informationfor executive control (Cohen et al., 1996). LPFC neurons showdifferential baseline activity depending on the task requirement(Sakagami and Niki, 1994; Asaad et al., 2000). To code the motivationalcontext, context information should be monitored continuouslyduring task performance. Our data show that LPFC neurons are involvedin this process with their reward-discriminative tonic baselineactivities. It might be argued that such differential baselineactivity reflects differences among taste stimuli in the mouth.However, there was no significant difference in preinstructionbaseline activity after rewarded compared with unrewarded trialsin most LPFC neurons in the present experiment, although the tastestimuli were different in these twocases.

Functional differentiation of the lateral prefrontal cortex in relation to the baseline activity

The present study found that neurons with and without preinstruction baseline activities were distributed differently alongthe dorsoventral extent of the LPFC (Fig. 7). The dorsal and ventralLPFC are proposed to be concerned, respectively, with spatialand object working memory (Wilson et al., 1993; Goldman-Rakic,1996), although there also exists evidence against this hypothesis(Fuster et al., 1982; Rao et al., 1997; White and Wise, 1999).It has also been proposed that the ventral LPFC is involved inmaintaining information in working memory, whereas the dorsalLPFC is concerned with monitoring information in working memory(Petrides, 1994, 1996). The present study suggests a new dimensionin the differentiation of LPFC in relation to motivational operations,the dorsal LPFC being more involved in monitoring the motivationalcontext and the ventral LPFC and arcuate area being more concernedwith coding and representing the motivational value associatedwith the presence or absence of a specific reward. Such differentiationmay reflect the fact that the ventral and dorsal LPFC have differentcortico-cortical and limbic connections (Pandya et al., 1971;Barbas, 1993). Additional studies are needed to clarify how LPFCis functionally differentiated in relation to different kindsofoperations.

Functional significance of representation of motivational context in the prefrontal cortex

The level of attention modifies baseline neuronal activity in the LPFC (Lecas, 1995). Hasegawa et al. (2000) reported LPFCneurons whose precue activity reflects the monkey's performancelevel in the past trial, or predicts the performance level inthe future trial, but not in the present trial. Such activityis considered to reflect the monkey's motivational or arousallevel. The preinstruction baseline activity observed in the presentexperiment may also be related to the monkey's attention or motivationallevel because the monkey may be more attentive to the task situationand more motivated on preferred than on nonpreferred rewardblocks.

The OFC plays important roles in motivational operations. Rodent OFC neurons encode the incentive value of expected outcomes(Schoenbaum et al., 1998). Primate OFC neurons code reinforcement-error(Rosenkilde et al., 1981; Tremblay and Schultz, 2000), are relatedto expectancy of the presence or absence of reward (Hikosaka andWatanabe, 2000), and reflect the relative but not absolute valueof the reward (Tremblay and Schultz, 1999). If motivational operationsin the PFC are supported mainly by OFC (Fuster, 1997; Rolls, 1999),then what is the functional significance of neuronal activitiesrelated to the motivational context in LPFC? Although such activitiesare not directly associated with correct task performance, theymay be essential for detecting the congruency or discrepancy betweenexpectancy and outcome, even in the case in which no reward canbe expected, and thus serve for the acquisition-maintenance andmodification of behavioral strategies according to the responseoutcome. Such a neural mechanism may have survival value for ananimal seeking the more preferable reward in givencircumstances.

Whereas neurons related to spatial working memory are quite rare in the OFC (Tremblay and Schultz, 1999), LPFC neurons areinvolved in both working memory and reward expectancy (Watanabe,1996; Leon and Shadlen, 1999). Interestingly, working memory-relatedactivity of primate LPFC neurons is enhanced when a more preferredreward is used (Leon and Shadlen, 1999). Thus, the functionalsignificance of motivational operations of the LPFC may lie inthe integration of motivational and cognitive operations for goal-directedbehavior.

  FOOTNOTES

Received July 9, 2001; revised Dec. 27, 2001; accepted Jan. 4, 2002.

This study was supported by a Grant-in-Aid for scientific research from the Ministry of Education, Science, Sports, and Cultureof Japan and a Grant-in-Aid for target-oriented research and developmentin brain science from Japan Science and Technology Corporation.We thank W. Schultz and J. Lauwereyns for comments and suggestionsand T. Kodama, M. Odagiri, T. Kojima, H. Takenaka, and K. Tsutsuiforassistance.

Correspondence should be addressed to Masataka Watanabe, Department of Psychology, Tokyo Metropolitan Institute for Neuroscience,Musashidai 2-6, Fuchu, Tokyo 183-8526, Japan. E-mail: masataka{at}tmin.ac.jp.

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DISCUSSION
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