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Emotional Arousal Can Impair Feature Binding in Working Memory Mara Mather1, Karen J. Mitchell2, Carol L. Raye2, Deanna L. Novak1, Erich J. Greene2, and Marcia K. Johnson2 Abstract & To investigatewhether emotional arousalaffectsmemorial netic resonance imaging experiments showed that relative to feature binding, we had participants complete a short-term low-arousal trials, high- and medium-arousal trials resulted in source-monitoring task—remembering the locations of four greateractivityinareasassociatedwithvisualprocessing(fusi- different pictures over a brief delay. On each trial, the four form gyrus, middle temporal gyrus/middle occipital gyrus, lin- pictures were all either high arousal, medium arousal, or low gual gyrus) and less activity in superior precentral gyrus and arousal. Memory for picture–location conjunctions decreased theprecentral–superiortemporalintersect.Thesefindingssug- asarousalincreased.Inaddition,sourcememoryfortheloca- gestthatarousal(andperhapsnegativevalencefordepressed tion of negative pictures was worse among participants with people)recruitsattentiontoitemstherebydisruptingworking higher depression scores. Two subsequent functional mag- memoryprocessesthathelpbindfeaturestogether. & INTRODUCTION tional nature of an event may enhance memory for its In this study, we investigated the impact of emotion on emotionally arousing components but impair binding of theencodingofepisodicmemories.Peopleoftenseemto other aspects of the event to the emotional elements remember shocking events particularly vividly (Pillemer, (Johnson, Nolde, & De Leonardis, 1996; but see MacKay Goldsmith,Panter,&White,1988;Rubin&Kozin,1984). & Ahmetzanov, 2005; Doerksen & Shimamura, 2001). People are also more likely to remember emotional To study feature binding during encoding of neutral than neutral stimuli (Charles, Mather, & Carstensen, events (line drawings of objects in various locations), 2003; Canli, Desmond, Zhao, & Gabrieli, 2002; Ochsner, Mitchell, Johnson, Raye, and D’Esposito (2000) used a 2000;Bradley,Greenwald,Petry,&Lang,1992).Yet,emo- short-term source memory paradigm. In the present tional memories are often less accurate than we believe study, we used a similar working memory task (see Fig- theyare(e.g.,Schmolck,Buffalo,&Squire,2000). ure 1) to examine how the emotional content of a Inparticular,althoughemotionaleventsmayresultin pictureaffectspeople’sabilitytorememberwhereitap- excellent memory for their central aspects, the ‘‘what’’ peared(atypeofsourcememory,Johnson,Hashtroudi, of the event (Reisberg & Heuer, 2004), other elements & Lindsay, 1993). Our participants saw four pictures ofthe event are ofteneither forgottenor confused with from the International Affective Picture System (IAPS; elements of other events (Christianson & Loftus, 1991). Lang,Bradley,&Cuthbert,1999) presentedsequentially For example, police officers recall fewer details from in different locations on a computer screen. After each scenarios in which a shooting occurred than those with- sequence of four pictures, there was a brief delay out a shooting (Stanny & Johnson, 2000), and memory followedbyoneofthosepicturesinoneofthelocations for contextual details is worse for emotionally arousing occupied on that trial. Participants indicated whether than nonemotional events (Kensinger, Piguet, Krendl, & the picture–location pairing was the same or different Corkin, 2005; Schmidt, 2002). Memories for shocking than at study. The critical manipulation was that all the events may import elements from other events, such as pictures on a given trial were either high, medium, or television footage seen later (Pezdek, 2003; Neisser & low in arousal, based on normative ratings (Lang et al., Harsch,1992),andmemoryforperipheraldetailsofsuch 1999). For generality, the high- and medium-arousal events is worst among people who find the event most pictures each included an equal number of negatively emotionally powerful (Schmidt, 2004). Thus, the emo- and positively valenced pictures; the low-arousal pic- tures were neutral in valence. Experiment 1 was a behavioral study in which we also examined the relationship between individual dif- 1University ofCalifornia, Santa Cruz,2Yale University ferences in levels of depression and source memory. D 2006Massachusetts Institute ofTechnology Journal ofCognitiveNeuroscience 18:4,pp.614–625 Figure1. Aschematic representationofone behavioralworkingmemory trialwithlow-arousal,neutral pictures.Notethatthepicture toscreensizeproportionis nottoscale. Negative stimuli are especially likely to capture the of four pictures from the same emotion category (e.g., attention of depressed people (Gotlib & Neubauer, high arousal negative). 2000),andthisselectiveattentionmightnegativelyaffect memory-binding processes. That is, depressed people may be especially likely to process the content of Procedure negative stimuli at the expense of binding the con- On each trial (see Figure 1), participants first saw the tent with location. To further clarify the cognitive pro- cue ‘‘STUDY’’ for 500 msec, followed by four pictures cesses associated with the arousal-induced deficits in shown sequentially for 750 msec each. Each picture source memory revealed in Experiment 1, in Experi- appeared in a different one of eight possible locations. ments 2A and 2B we used functional magnetic reso- After a 7000 msec delay a ‘‘TEST’’ cue appeared for nance imaging (fMRI) to identify brain regions where 500 msec, followed by one of the four pictures from activity differed depending on the arousal level of the the trial for 500 msec in one of the locations used pictures. during that trial. Participants pressed one key to indi- cate the picture–location conjunction was the ‘‘same’’ as during study and another to indicate it was ‘‘differ- EXPERIMENT 1 ent.’’ The intertrial interval (ITI) was 2000 msec, during which the screen was blank. Participants were given Methods three practice trials with pictures not used during the Participants experiment. Twentyundergraduates(15women,meanage=18years) We were interested in people’s memory for picture– participatedforcoursecredit. location pairings (source memory). Half of the test pictures of each emotion type were presented in their correct location (‘‘same’’ trials) and half in a different Materials location (these ‘‘different’’ test probes were a picture Wecompiledfivecategoriesof16pictureseachfromthe and a location from the current trial, but they were re- IAPS (Lang et al., 1999):1 (1) high arousal negative paired). Each set of four pictures appeared in four (M = 6.38 on a scale of 1–9), (2) high arousal different trials (picture location and ordinal position arousal positive (M = 6.38), (3) medium arousal negative within trial was different across repetitions); each pic- arousal (M =4.56),(4)mediumarousalpositive(M = ture was tested once during the session (for a total of arousal arousal 4.53),and(5)lowarousal/neutral(M =3.24).Each 80 trials). Whether a picture was tested in its correct arousal of the 80 pictures was randomly assigned to one set location was counterbalanced across participants. Two Mather etal. 615 different versions of the sets varied which pictures ap- a 2 (valence: negative, positive) (cid:3) 2 (arousal: high, me- peared in the same set across participants. Thus, there dium) repeated measures analysis of variance (ANOVA) were four versions of the session. The presentation showed only a main effect of arousal, F(1,19) = 9.32, order of picture sets was random. MSE=.28,p<.01,h 2=.33.Therewasnomaineffect p Participants completed four 5-min blocks of the task. of valence and no interaction of valence and arousal Between blocks, they completed various questionnaires (both F < 1). Thus, unlike arousal, valence did not for5min.Inthelastbreak,theycompletedadepression influence source accuracy. scale (Sheikh & Yesavage, 1986). Correlations with Depression Scale Scores Results and Discussion Scores on the depression scale ranged from 0 to 8 out of a possible 15 (M = 2.9, SD = 3.36). Scores of six Short-term Source Memory Data or higher indicate probable depression (Ferraro & Participants’ source accuracy when responding to the Chelminski, 1996). Participants’ depression scores were picture–location conjunctions is expressed as d0 scores. negatively correlated with source accuracy for negative Proportions of hits (H) and false alarms (FA) were pictures (r = (cid:2).52, p < .05); participants with higher adjusted as follows: p(H) = 1 was recalculated as 1 (cid:2) depression scores were less likely to remember the 1/(2N),p(FA)=0wasrecalculatedas1/(2N),whereNis negative picture–location conjunctions correctly, but de- the maximum number of hits or false alarms possible pressionscoreswerenotcorrelatedwithsourceaccuracy (Macmillan&Creelman,1991).Alinearcontrastshowed forneutral(r=.07,p=.80)orpositive(r=.14,p=.50) thatthe more arousingthe pictureswere, the lesslikely pictures. people were to remember where they had occurred, F(1,19)=10.16,MSE=.42,p<.01,h 2=.35(seeFig- p ure2).Omittingthelow-arousal(neutralvalence)items, EXPERIMENTS 2A AND 2B In Experiment 1, the emotional arousal associated with picturesinterferedwithparticipants’abilitytoremember wherethepictureswereseenonlyafewsecondsbefore. Source accuracy was poorest for highly arousing pic- tures, somewhat better for medium-arousal pictures, and best for the low-arousal pictures. One possible explanation isthat emotionallyarousing picturesrecruit attention to picture content, which disrupts processes thathelpbindthepictureswithlocationinformation.To explore this hypothesis, in Experiments 2A and 2B we assessed participants’ brain activity during the short- term source memory task using fMRI. A long-term memory test was included to assess whether recall of high-arousal pictures was impaired, like conjunction accuracy, or enhanced, as might be expected if arousal recruits attention to the contents of the picture. Exper- iment 2A was conducted on a 1.5T scanner, Experi- ment 2B on a 3T scanner; otherwise, the procedures were identical.2 Thus, for ease of exposition, they are discussedtogether.Minorchangestothetimingusedin Experiment 1 were made to accommodate fMRI con- straints. See Figure 3 for the trial event sequence. Methods Participants Participants were healthy, right-handed, college-aged students (Experiment 2A: n = 16, eight women, mean Figure2. Sourceaccuracyd0forhigh-,medium-,andlow-arousal age = 22 years.; Experiment 2B: n = 10, four women, workingmemory(WM)trialsinExperiments1,2A,and2B(left); meanage=20years.).Allparticipantsreportedbeingin proportionofstudiedhigh-,medium-,andlow-arousalpicturesthat good health, with normal (or corrected-to-normal) vi- wererecalled(LTM)inExperiments2Aand2B(right).Errorbars arestandarderrorsofthemean. sion and no history of psychiatric diagnosis or primary 616 Journalof CognitiveNeuroscience Volume18, Number 4 Figure3. TrialtimelineforthefMRIexperiments,shownwithlow-arousal,neutralpictures.Notethatthepicturetoscreensizeproportionis nottoscale.Eachtrialincludedninescansandthechartatthebottomapproximatesthelaginthehemodynamicresponse,withthefirsttwoscans ineachtrialreflectingactivityfromtheITIintheprevioustrial. degenerative neurological disorder; none were taking saw four pictures presented sequentially for 900 msec psychotropic medications. All participants were paid. each, with a 100-msec ISI. Again, all pictures in a trial were similar in arousal level (high, medium, or low), each picture appeared in a different one of eight po- Task and Design tential locations, and participants were told to study During scanning, stimuli were projected onto a screen, each item and its location for an upcoming test. After whichparticipantsviewedthroughamirrormountedon 5500 msec of unfilled time, a cue (TEST) appeared for the head coil (Experiment 2A used a front projection 500 msec to alert participants that the next picture system, with the screen at the foot of the scanner; would be the test probe. As in Experiment 1, the probe Experiment 2B used a back projection system with the was either a studied picture in its original location screen at the back of the scanner). Sixteen low-arousal (same) or a studied picture in a location filled by a pictures were added to those from Experiment 1 for a different picture on that trial (different). The probe was totalof 32pictures at each arousallevel (high, medium, shown for 2000 msec and participants pressed a button low). Each trial took 18 sec (see Figure 3). Participants on a response pad in their right (left) hand if the test Mather etal. 617 item was a picture–location conjunction that was the significant at p < .001 (Forman et al., 1995), except as same (different) as at study. In both experiments, the noted in Table 1. We focus discussion on areas of testprobewasfollowedbya6000-msecITIthatincluded activation that replicated across two independent ex- two arrows each presented for 1400 msec. Participants periments and therefore appear highly reliable. The re- were told to press a button with their left hand if the sultant F maps were transformed to Talairach space arrow pointed left and with their right hand if it pointed using AFNI (Cox, 1996, version 2.50), and areas of right. The arrows provided a task common to all con- activation were localized using Talairach Daemon soft- ditionstoallowtimeforthehemodynamicresponseand ware (Lancaster, Summerlin, Rainey, Freitas, & Fox, to decrease variability among participants from uncon- 1997), as well as manually checked using the Talairach trolled mental activity between trials. and Tournoux (1988) and other brain atlases. For Therewereeightrunsof12trialseach,withhigh,me- region-of-interest analyses of the amygdala and hippo- dium, and low trials randomly intermixed in each run. campus, each anatomical area was drawn separately on Random assignment and counterbalancing procedures the left and on the right side of the reference brain were similar to Experiment 1. image and applied to each participant’s data to extract About 5 min after exiting the scanner, there was a timecourse information for each subject. Analyses surprise written recall test. Participants were told that were then conducted on the group-averaged time there were 96 pictures shown during the scan session course information to determine which arousal levels and that they should try to recall as many as possible, differed. providingasmuchdetailaspossiblesothatthedescrip- The hemodynamic response that indexes brain activ- tions could be matched to the corresponding pictures. ityinfMRIrespondsslowly,risingtoapeak4–6secafter the critical event. Therefore, to determine which con- ditions significantly differed (p < .05, unless otherwise Imaging Details noted) in each region identified, subsequent analyses were conducted on the mean percent BOLD change Anatomical images were acquired for each participant (from time 1) at times 3 and 4 and at times 6 and 7, to using a 1.5T Siemens (Malvern, PA) Sonata (Experi- assess activity that should include processing during ment2A)ora3TSiemensTrio(Experiment2B)scanner picture presentation and during the retention interval, at the Magnetic Resonance Research Center at Yale respectively. University.Functionalscanswereacquiredwithasingle- shot echoplanar gradient-echo pulse sequence (TR = 2000 msec, TE = 35 msec [Experiment 2A] or 25 msec [Experiment 2B], flip angle = 808, FOV = 24). The Results and Discussion 26axialslices (slicethickness3.8mm,resolution3.75(cid:3) Behavioral Data 3.75 mm in plane) were aligned with the AC–PC line. As in Experiment 1, conjunction accuracy during the Eachrunbeganwith12blanksecondstoallowtissueto working memory task was measured using d0. A linear reach steady-state magnetization, and was followed by contrast indicated that, in Experiment 2A, the arousal- a 1-min rest interval. One volume was collected every induced impairment in source memory was replicated, 2 sec, or nine full brain scans for each trial (288 images F(1,15) = 10.16, MSE = .42, p < .05, h 2 = .27 (see perarousallevelforeachparticipant). p Figure 2). In Experiment 2B, the pattern of means was thesameasinExperiments1and2A,butfailedtoreach significance (see Figure 2). fMRI Analyses To assess long-term memory for individual pictures, Data were motion corrected using a 6-parameter auto- two coders matched each picture description from mated algorithm (AIR, Woods, Cherry, & Mazziotta, participants’picturerecalltothestudiedpictures.Inter- 1992). A 12-parameter AIR algorithm was used to coreg- raterreliabilitywas84%anddiscrepancieswereresolved ister participants’ images to a common reference brain. by a third judge. A linear contrast conducted on the Data were mean-normalized across time and partici- proportionofrecalleditemsthatwerefromeacharousal pants,andspatiallysmoothed(3-D,8mmFWHMgauss- level showed that, in Experiment 2A, arousal increased ian kernel). thelikelihoodofrecallingapicture,F(1,15)=5.96,MSE= fMRI data were analyzed using ANOVA with partici- .01, p < .05, h 2 = .28 (see Figure 2). In Experiment 2B, p pant as a random factor (NIS software, University of high arousal items were recalled at a numerically higher PittsburghandPrincetonUniversity).Run(1–8),Arousal rate,althoughnotsignificantlyso(seeFigure2). (high, medium, low), and Time within trial (scan 1–9) were fixed factors. Brain regions were identified that fMRI Data showed an Arousal by Time (scan) interaction. We re- port areas of activation identified using a cluster thresh- Table 1 summarizes areas of activation identified as oldofaminimumofsixspatiallycontiguousvoxels,each showingArousal(cid:3) Time interactions inExperiments2A 618 Journalof CognitiveNeuroscience Volume18, Number 4 Table 1. Brain Areas Identifiedin Experiments 2Aand2B Contrasts Anatomical No.of Figure Experiment L/R BA Area x y z Max F Voxels t3,4 t6,7 Areas thatreplicated acrossExperiments2A and2B Areas wherehigh and/or medium >low 4 2A R 37 GF 41 (cid:2)51 (cid:2)13 3.51 9 H > Ly H > L M> L 4 2B R 37,(20) (36) GF, (Gh) 36 (cid:2)41 (cid:2)11 4.35 16 H > Ly H > L M> L M> L M> Hy 5 2A R 39,37/19,18 GTm/GOm 45 (cid:2)70 9 6.72 105 H > L H > L M> L H > M 5 2B R 39,37, 19 GTm, GOm, 42 (cid:2)69 9 5.22 53 H > L (GTi) M> L 5 2A L 17/18 GL, Sca,Cu, (cid:2)9 (cid:2)85 0 3.71,3.67 78 M> L H > L Gom (cid:2)20 (cid:2)92 0 M> L H > M 5 2B L 17,18, (19) Sca, GL, (cid:2)21 (cid:2)92 2 3.57 28 H > Ly H > L (GOm) M> L Areas wherelow >high and/or medium 6 2A* L 6 GPrC (cid:2)57 0 33 2.59 6 L> H 6 2B L 6/4 GPrC (cid:2)53 (cid:2)5 43 3.01 6 L> H L> H L> My M> H M> H 7 2A* R 6,(44) GPrC, (GFi) 57 5 10 2.94 15 L> H L> M 7 2B R 44,(22, 6,13) GPrC(GTs, 50 6 10 5.90 197 L> H GFi,INS) M> H 7 2A L 22/6 GTs/GPrC (cid:2)58 (cid:2)1 9 3.39 10 L> My L> H L> M 7 2B L 6,(22, 42,44) GPrC, (GTs, (cid:2)48 2 10 5.05 30 L> H GFi) M> Hy Other areasinExperiments 2Aand2B Areas wherehigh and/or medium >low 2A M 10/9 GFs, GFd (cid:2)11 57 29 4.34 72 H > M H > L H > M R 47,(45/13) GFi, (INS) 41 31 (cid:2)4 4.01 13 H > L H > M L 39/19 GTm, GOm (cid:2)38 (cid:2)61 16 3.61 45 H > L M> L H > M M 7 PCu (cid:2)12 (cid:2)48 33 3.19 7 H > L H > L M> Ly M> L H > M L 40 LPi (cid:2)42 (cid:2)51 42 3.11 37 H > L 2B R 19 GOm,GOi, 35 (cid:2)76 (cid:2)7 3.24 7 M> Ly (GL) Mather etal. 619 Table 1. (continued) Contrasts Anatomical No.of Figure Experiment L/R BA Area x y z Max F Voxels t3,4 t6,7 Areas wherelow>high and/or medium 2A NONE 2B M 18 Cu,(Sca) 6 (cid:2)80 20 3.24 6 L> H L> My M >H M 6,24, 32 GFd,GC 1 (cid:2)2 48 3.30 14 L> M L >H L >M M >H R 7 LPs 17 (cid:2)64 48 3.73 9 L >H L 6,(4) GFs,(GFm)/ (cid:2)25 (cid:2)12 51 4.12 7 L> H M >Ly GPrC M >H M >H L 40,42, 22,(2) LPi,GTs, (cid:2)65 (cid:2)34 26 3.57 14 L >Hy (GPoC) All areas showed an Arousal (cid:3) Time interaction with a minimum of six contiguous voxels, each significant at p < .001 (Forman et al., 1995), except for the two marked with an asterisk (*) in the Experiment column where p < .01. Subsequent contrasts between conditions, shown in the rightmost columns, were performed on percent signal change from Time 1 at Times 3, 4 (early) and Times 6, 7 (late), p < .05, exceptas indicatedwithadagger(y),where.05<p<.10.AbbreviationsofbrainareasfollowTalairachandTournoux(1988).L=left;M= medial; R = right; BA = Brodmann’s area; Cu = cuneus; GC = cingulate gyrus; GF = fusiform gyrus; GFd = medial frontal gyrus; GFi = inferiorfrontalgyrus;GFm=middlefrontalgyrus;GFs=superiorfrontalgyrus;Gh=parahippocampalgyrus;GL=lingualgyrus;GOi=inferior occipital gyrus; GOm = middle occipital gyrus; GPrC = precentral gyrus; GTi = inferior temporal gyrus; GTm = middle temporal gyrus; GTs=superiortemporalgyrus;INS=insula;LPi=inferiorparietallobule;LPs=superiorparietallobule;PCu=precuneus;Sca=calcarine sulcus. BA and anatomical areas are listed left to right in descending order of approximate size, with approximately equal areas of activation indicatedbyaslash;parenthesesindicateasmallextentrelativetootherareaslisted.Talairachcoordinatesareforthelocalmaximumineachregion ofactivation. and 2B. Our discussion focuses on areas that replicated precentral gyrus and superior temporal gyrus (see Fig- across experiments and that showed differences be- ure 7). It is interesting that differences between condi- tween arousing versus neutral pictures during the early tions in the areas shown in Figures 6 and 7 tended to (Times 3 and 4) or late (Times 6 and 7) portion of the emerge later in the trial thanthe differences in the areas trial (see event trial sequence in Figure 3 and subse- shown inFigures4 and 5.Thispattern isconsistent with quent analyses summarized in Table 1). These areas are a positive impact of arousal on attention given to visual showninFigures4–7. features of individual pictures and a negative impact of As shown in Figures 4 and 5, emotional pictures arousal on rehearsal processes important for binding resulted in greater activation than neutral pictures in individualpicturestotheirlocations,althoughourexper- regions associated with visual processing including imental design does not allow definitive separation of the fusiform gyrus, middle occipital gyrus, and middle activityduringtheearlyandlateportionsofthetrial(e.g., temporal gyrus. Because the number of face pictures Zarahn, 2000). did not differ in the high- and low-arousal picture Inadditiontothewhole-brainanalysessummarizedin sets, the different levels of fusiform activity between Table1,wealsoconductedregion-of-interestanalysesof arousal conditions seen in Figure 4 cannot be attri- the hippocampus and amygdala because previous find- buted to differences in the number of face stimuli. ings indicate that the hippocampus is important for The differences in activity in the visual processing re- memory binding (Olson, Chatterjee, Page, & Verfaellie, gions shown in Figures 4 and 5 are consistent with 2005; Mitchell et al., 2000) and the amygdala modulates greater attention to the high-arousal items, contribut- hippocampal activity to enhance memory for emotional ing to their higher likelihood of later being recalled stimuli (McGaugh, 2002). There were no significant (although we cannot rule out other factors that might differences between arousal conditions in these areas be correlated with arousal level of the pictures, such in Experiment 2A. In Experiment 2B, there was greater as complexity). activation for emotional than neutral trials in both the Neutraltrials,ontheotherhand,showedmoreactivity right(p<.004)andleft(p<.06)hippocampus3andin thanemotionaltrialsinthe left superior precentralgyrus right amygdala (p < .09). Because the pattern did not (see Figure 6) and in an area at the intersect of inferior replicate across experiments, we do not discuss these 620 Journalof CognitiveNeuroscience Volume18, Number 4 term disadvantage in source memory, but a long-term advantage in item memory. Previous studies indicate that attending to emotional stimuli can disrupt attention to other information (MacKay et al., 2004; McKenna & Sharma, 2004). For example, the presence of an emotional word together with two neutral words in a briefly presented display makes it more difficult to immediately think back to (i.e., ‘‘refresh’’) either of the neutral words in the display (Johnson et al., 2005). Johnson et al. called this lingering reflective attention to a salient item that is no longer perceptually present ‘‘mental rubberneck- ing.’’ This rubbernecking has some benefits, such as improvedmemoryfortheitemlingeredupon,asshown in this and other studies demonstrating better memory for emotional than neutral items (e.g., Ochsner, 2000). However, the present results reveal a cost; namely, poorer source memory—in this case, for the location in which the item appeared. In all three experiments, short-term source memory was lowest for high-arousal trials and best for low-arousal trials. Thus, it seems that emotional content disrupted reflective processes by which the conjunction of item and location are bound in working memory (Mitchell et al., 2000). In addition, Figure4. Areasofthefusiformgyrus(GF)inExperiments2Aand Experiment 1 suggests that mildly depressed partici- 2BshowingsignificantArousal(cid:3)Timeinteractions,shownwiththe pants engage in mental rubbernecking for negative associatedaveragewithin-trialtimecourses.Inallfigures,forthe stimuli, in particular. timecourses,thex-axisrepresentsscanwithinatrial(TR=2000msec, Experiments2Aand2Bprovideinformationaboutthe eachtrial18sec),andthey-axisrepresentsmeanpercentsignal neuralcorrelatesofthearousal-inducedsourcememory changefromthefirstwithin-trialtimepoint.Abbreviationsofbrain areasfollowTalairachandTournoux(1988)(seefootnote,Table1), deficit. First, the suggestion that arousing pictures andforeachregionofactivation,areasarelistedindescendingorder evoked greater attention than neutral pictures is sup- ofapproximatesize,withapproximatelyequalareasofactivation ported by the finding that in both Experiments 2A and indicatedbyaslashandminorareasinparentheses.Slicesinall 2B there was more activity in higher-order visual areas figureswerechosentoshowrepresentativeactivations;Talairach during processing of emotional than neutral picture coordinatesaregiveninTable1. sets (Figures 4 and 5; see also Phan, Wager, Taylor, & Liberzon, 2002), and that the emotional pictures findingsfurther,althoughtheydosuggestanavenuefor were remembered better later. Visual attention tasks further investigation. produce activity in the fusiform gyrus (Mangun, Hop- finger,Kussmaul,Fletcher,&Heinze,1997;Heinzeetal., 1994) and BA 17, 18, and 19 (for a review see Cabeza & Nyberg, 2000). Second, participants in Experiments 2A GENERAL DISCUSSION and 2B showed activation in a superior area of the In the three experiments presented here, participants precentral gyrus that was greater for low- than for showed poorer short-term source memory for the loca- medium- or high-arousal pictures. That this area con- tion of highly arousing pictures than for pictures lower tributestomemorybindingissupportedbythefactthat in arousal. Such a pattern suggests that emotional Mitchell et al. (2000) found the same area (x = (cid:2)54, arousal disrupts encoding processes necessary for me- y=(cid:2)5,z=35)showinggreateractivityduringworking morial feature binding, at least in the short term. The memory for ‘‘combination’’ trials on which participants fMRI results of Experiments 2A and 2B are consistent had to remember where (neutral) items were located with the idea that emotionally arousing pictures recruit than on trials where they had to remember only indi- more attention, reflected in activation in visual process- vidual features (items or locations, see also Henke, ing areas, at the expense of activity in other areas (the Weber, Kneifel, Wieser, & Buck, 1999). intersect of precentral and superior temporal gyrus, We also found an area at the intersect of the inferior superior precentral gyrus) that likely contribute to fea- precentral gyrus and superior temporal gyrus that was ture maintenance and binding during working memory. greaterforlow-arousalsetsofpicturesthanformedium- This greater attention to item than relational informa- or high-arousal sets. Activity in these areas has been as- tion (in this case, item plus location) produces a short- sociated generally with working memory (Chein & Fiez, Mather etal. 621 Figure5. Visualprocessing areas,includingmostnotably themiddletemporalgyrus (GTm),middleoccipitalgyrus (GOm),lingualgyrus(GL), andcalcarinesulcus(Sca), inExperiments2Aand2B showingsignificantArousal(cid:3) Timeinteractions,shown withtheassociatedaverage within-trialtimecourses. 2001; Cornette, Dupont, Salmon, & Orban, 2001), and tern seen in the present experiments suggests that this extracellular recording in awake patients showed that area contributed to more effective short-term source activity in this area of the superior temporal gyrus memory for low-arousal pictures. This area is also near at encoding predicted correct working memory trials one reported by Wright, Pelphry, Allison, McKeown, (Ojemann,Schoenfield-McNeill,&Corina,2004).Thepat- and McCarthy (2003) in which activity was greater for the combination of auditory and visual stimuli than for either alone, consistent with the idea that the supe- rior temporal gyrus plays a role in feature integration (e.g., Calvert, Hansen, Iverson, & Brammer, 2001). The superior temporal gyrus may help integrate disparate features for a brief period in order to maintain a co- herent overall representation (see also Jung-Beeman et al., 2004). Our data suggest that when emotional features dominate encoding and/or rehearsal at the expense of other features, integration is less likely, as evidenced by poorer source memory (e.g., Johnson et al., 1996). As discussed in the Introduction, previous research suggests that the disruption caused by mental rubber- necking has deleterious effects on long-term source memory for complex emotional events (Schmidt, 2002; Johnson et al., 1996; Burke, Heuer, & Reisberg, 1992; Christianson & Loftus, 1991). However, there may be contexts in which mental rubbernecking is less of an issue. For example, when only one item is the focus of attention at a time the enhanced attention devoted toasingleemotionalitemmayimprovelong-termmem- ory for its context. Consistent with this possibility, sev- eral studies that presented one word at a time, and did not include a working memory task where several Figure6. Areaoftheprecentralgyrus(GPrC)inExperiments2Aand items had to be maintained simultaneously, found bet- 2B,andassociatedaveragewithin-trialtimecourses,withsignificant Arousal(cid:3)Timeinteractions. ter memory for the color of emotional than neutral 622 Journalof CognitiveNeuroscience Volume18, Number 4 Figure7. Bilateralareasat theintersectoftheinferior precentralgyrus(GPrC)and superiortemporalgyrus(GTs), inExperiments2Aand2B,and associatedaveragewithin-trial timecourses,withsignificant Arousal(cid:3)Timeinteractions. words (D’Argembeau & Van der Linden, 2004; MacKay area helps create associations between the source of et al., 2004; Kensinger & Corkin, 2003; Doerksen speechand what issaid(Woodruffetal.,1997; McGuire &Shimamura,2001). et al., 1995). Our findings that feature binding is asso- Finally,wenotethatourfindingsmayalsobearonthe ciated with activation in an area that includes the su- cognitivedeficitsassociatedwithschizophrenia.Patients perior temporal gyrus is consistent with the idea that with schizophrenia show deficits in memory for the schizophrenic patients’ reduced volume or dysfunction conjunction of neutral features even when they are (or both) of this area may contribute to their source- equatedwithcontrols formemoryofthefeaturesthem- monitoring deficits. selves(Burglenetal.,2004;Waters,Maybery,Badcock,& Insummary,emotionisimportantfordirectingatten- Michie, 2004; Rizzo et al., 1996). The dominant hypoth- tion,andemotionalstimuliarelikelytoberemembered esis is that these deficits are due to decreased hippo- later. Our study demonstrates that this attention to campal volume in schizophrenia (Shenton, Dickey, emotional stimuli, reflected in activity in visual process- Frumin, & McCarley, 2001). However, our findings pro- ing areas, sometimes has a cost. During a working vide converging evidence for another (not necessarily memory task, it can disrupt binding of features such as mutuallyexclusive)hypothesis.AreviewofMRIfindings location associated with the emotionally arousing infor- in studies of schizophrenia showed that all 12 studies mation,asreflectedinlessactivityintheprecentraland examining gray matter volume of the superior temporal superior temporal areas. gyrus found reductions in patients with schizophrenia (Shenton et al., 2001). Furthermore, the smaller the patients’ left superior temporal gyrus, the more se- Acknowledgments vere their hallucinations (Onitsuka et al., 2004), and a This research was supported by grants from the National small superior temporal gyrus seems to be a predis- ScienceFoundation(0112284)andNationalInstituteonAging posing factor for the disease rather than a result of it (AG025340)toM.M.andgrantsfromtheNationalInstituteon Aging (AG15793) and National Institute of Mental Health (Rajarethinam, Sahni, Rosenberg, & Keshavan, 2004). (MH62196)toM.K.J.WethankHedySarofin,KarenMartin,and The correlation between size of the superior temporal thetechnicalstaffattheMRRCforassistanceincollectingthe gyrus and degree of hallucination makes sense if this imaging data, Joe McGuire for help in creating figures, and area aids in the formation of associations among as- Caitlin Elen,Annie Giang, andKia Nesmith for coding data. pects of an event that are critical for later remember- Reprint requests should be sent to Mara Mather, Psychology ingitssource(e.g.,Johnsonetal.,1993).Consistentwith Department, University of California-Santa Cruz, Santa Cruz, this hypothesis, controls show greater superior tem- CA95064, orvia e-mail:[email protected]. poral activation than patients with schizophrenia when The data reported in this experiment have been deposited imagining sentences being spoken in someone else’s with the fMRI Data Center (www.fmridc.org). The accession voiceorlisteningtoexternalspeech,suggestingthatthis number is 2-2005-1209B. Mather etal. 623

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source-monitoring task—remembering the locations of four .. timecourse information for each subject. emotional events: The fate of detailed information.
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