Informatic parcellation of the network involved in the computation of subjective value

Abstract

Understanding how the brain computes value is a basic question in neuroscience. Although individual studies have driven this progress, meta-analyses provide an opportunity to test hypotheses that require large collections of data. We carry out a meta-analysis of a large set of functional magnetic resonance imaging studies of value computation to address several key questions. First, what is the full set of brain areas that reliably correlate with stimulus values when they need to be computed? Second, is this set of areas organized into dissociable functional networks? Third, is a distinct network of regions involved in the computation of stimulus values at decision and outcome? Finally, are different brain areas involved in the computation of stimulus values for different reward modalities? Our results demonstrate the centrality of ventromedial prefrontal cortex (VMPFC), ventral striatum and posterior cingulate cortex (PCC) in the computation of value across tasks, reward modalities and stages of the decision-making process. We also find evidence of distinct subnetworks of co-activation within VMPFC, one involving central VMPFC and dorsal PCC and another involving more anterior VMPFC, left angular gyrus and ventral PCC. Finally, we identify a posterior-to-anterior gradient of value representations corresponding to concrete-to-abstract rewards.

INTRODUCTION

Over the last few years, there has been a large effort to identify the computations made by the brain when executing different types of decisions, and when evaluating the outcomes generated by those decisions. There is a growing consensus that the assignment of values to stimuli is a critical part of both processes ( Rangel et al., 2008 ; Glimcher, 2011 ; Grabenhorst and Rolls, 2011 ; Rushworth et al. , 2011 , Wallis, 2012 ), and that the ventromedial prefrontal cortex (VMPFC) plays a critical role in the computation of value both at decision and outcome ( Rangel and Hare, 2010 ; Padoa-Schioppa, 2011 ; Levy and Glimcher, 2012 ).

One of the fundamental goals of this research program is to identify networks that are involved in the computation of value whenever that variable is needed. Measures of value can be computed for different types of rewards, for different purposes and at different stages, such as decision and outcome. Clearly, in order to answer these questions, it is necessary to collect and compare data in many different decision-making paradigms. This makes it challenging for single studies to adequately answer these questions, as the vast majority of studies address the computation of value in the context of a specific choice paradigm with a specific reward modality. Some insight can be gained by carrying out qualitative reviews of the literature ( Rangel et al., 2008 ; Glimcher, 2011 ; Grabenhorst and Rolls, 2011 ; Padoa-Schioppa, 2011 ; Rushworth et al., 2011 ), but the ideal methodology involves the use of meta-analyses ( Kober and Wager, 2010 ; Yarkoni et al., 2010 ).

We take an informatic approach to understanding value computation in the brain, by conducting several meta-analyses of over 80 functional magnetic resonance imaging (fMRI) papers related to the computation of value. Our goal is to address the following open questions. First, what is the full set of brain regions that reliably correlate with stimulus values when they need to be computed across tasks and reward modalities? Second, is this set of regions organized into dissociable functional networks across tasks and reward modalities? Third, is a distinct set of areas involved in the computation of stimulus values at decision and outcome? Fourth, are different regions involved in the computation of stimulus values for different reward modalities (e.g. food vs money)?

The study adds to previous uses of meta-analytic tools to understand the neurobiology of decision making, but differs in important ways. Several studies ( Peters and Buchel, 2010b ; Grabenhorst and Rolls, 2011 ; Levy and Glimcher, 2012 ; Liu et al. , 2011 ) also investigate the computation of value, but do not present a comprehensive analysis of the existing literature and focus primarily on the VMPFC. Another recent meta-analysis looks at fMRI studies of subjective pleasantness ( Kuhn and Gallinat, 2012 ), but their focus is exclusively on the time of reward receipt. Two other meta-analyses focus on specific decision environments, such as intertemporal choice ( Carter et al. , 2010 ) and risky choice ( Mohr et al. , 2010 ). In contrast, here we look at the entire body of published papers related to the computation of value, regardless of task, reward modality or stage of processing. In addition, we seek to delineate the properties of the valuation network beyond the VMPFC.

METHODS

Study selection for coordinate-based meta-analysis

Most of the analyses performed in the study involve coordinate-based meta-analysis (CBMA), a common methodology ( Salimi-Khorshidi et al. , 2009 ; Kober and Wager, 2010 ; Eickhoff et al. , 2012 ). The studies selected for analysis were identified as follows. We started with PubMed searches (6 July 2012) to construct an initial candidate set that required the following keywords to be found in the title or abstract of scientific articles: (‘reward*’ OR ‘*economic*’) AND (‘preference*’ OR ‘value*’ OR ‘utility’ OR ‘valuation*’) AND (‘functional’ AND ‘magnetic’ AND ‘resonance’ AND ‘imaging’) OR ‘fMRI’ OR ‘neuroimaging’ OR ‘neural’ OR ‘brain*’) AND (‘pay*’ OR ‘purchase*’ OR ‘buy*’ OR ‘decision*’ OR ‘decide*’ OR ‘choice*’ OR ‘choose*’). This initial query yielded 503 results, and was supplemented by fMRI papers cited by recent review articles ( Grabenhorst and Rolls, 2011 ; Padoa-Schioppa, 2011 ; Rushworth et al. , 2011 ), but not recovered by the search. All non-relevant results (e.g. rodent studies that passed all the term searches in PubMed) were first removed from the list. We then manually removed all papers that did not satisfy one or more of the following necessary criteria for inclusion: (i) fMRI study of healthy human individuals, (ii) whole-brain analyses reported, (iii) parametric contrasts of subjective value reported (e.g. not just simply ‘high’ vs ‘low’ value) and (iv) peak-activation coordinates reported. This lead to the final corpus of 81 fMRI studies ( Table 1 ). As the majority of the studies only reported positive (but not negative) correlations with value signals, we focus almost exclusively on the analysis of the positive contrasts.

Statistical inference for coordinate-based meta-analysis

For CBMA, we employed the widely used activation likelihood estimation (ALE) method ( Laird et al. , 2005 ; Eickhoff et al. , 2012 ; Fox and Friston, 2012 ; Turkeltaub et al., 2012 ). Intuitively, the goal is to test against the null hypothesis that the foci of activation reported in the corpus of studies are uniformly distributed across the brain, as opposed to concentrated in some regions ( Eickhoff et al., 2012 ). The method is based on the idea that peak locations of activation are observed with noise in each study, but that the distribution of true locations from which they are observed is fixed across studies.

A meta-analysis employing the ALE statistic is carried out in several steps. First, for each included study, a map of the activation likelihood (commonly referred to as a modeled activation map, or MA) is computed. In this step, the probability of activation at any voxel is assumed to be a function of: (i) the Euclidean distance between the reported peak coordinates and the voxel, (ii) the volume of the voxel (here, 8 mm^3) and (iii) the spatial uncertainty associated with the reported peak coordinates. So, the MA statistic for a contrast i at voxel v denotes the probability that at least one true peak of activation lies within the voxel v in that contrast. Second, the MA maps are aggregated across contrasts to compute the ALE score for each voxel v . This is done by taking the probabilistic union of the MA statistic across all contrasts for each voxel. The ALE statistic denotes the probability that at least one true peak of activation lies in the voxel across the population of all possible studies. Third, a permutation test (described below) is used to identify voxels in which the ALE statistic is higher than expected by mere chance. More details on how the ALE statistic is computed are outlined by its developers ( Laird et al., 2005 ; Eickhoff et al., 2009 , 2012 ; Turkeltaub et al., 2012 ).

Importantly, our analyses used a recent version of ALE that accounts for heterogeneity in spatial uncertainty across studies ( Eickhoff et al., 2009 , 2012; Fox and Friston, 2012 ; Turkeltaub et al., 2012 ) as well as for heterogeneity in authors’ tendency to report multiple or single peak coordinates per cluster of activation ( Turkeltaub et al., 2012 ). This allows random-effects estimates of ALE, meaning the results are generalizable beyond the studies in the corpus ( Eickhoff et al., 2009 ). Each of our ALE analyses was carried out using the GingerALE package ( http://brainmap.org/ale/ ), which incorporates these improvements.

First, we computed ALE maps for single contrasts of interest (e.g. to identify regions that correlate with a specific type of value across studies). Each of these ALE maps were thresholded with a voxel-level requirement of P < 0.001 and a cluster-level requirement of P < 0.05, depicted in the figures and summarized in the tables. The significance of the ALE values was determined as follows. The ALE statistics in each voxel were compared with a null distribution of ALE values generated from 10 000 permutations ( Eickhoff et al., 2009 , 2012 ). Each permutation involved constructing an ALE value for all voxels in the whole-brain gray-matter mask. For each voxel in the mask, a randomly and independently chosen voxel from each MA map was selected and the ALE value was computed for this selection. After 10 000 permutations, the estimated ALE values for the actual data were compared with this empirically generated null distribution (pooling all voxels in the whole-brain mask). This stringent threshold was applied to all ALE tests, regardless of the number of contrasts and foci used.

Second, we carried out several contrasts between two ALE maps, which provide a test against the null hypothesis that there is no difference in the spatial pattern of reported loci across studies for the two contrasts underlying those activation maps. For contrasts of ALE values, we used ALE images with voxel-level significance requirement of P < 0.001. This criterion constructs the set of voxels in which the statistical contrast is performed and was employed to focus inference on areas reliably identified in each initial ALE test ( Eickhoff et al., 2011 ). Differences between ALE maps were then subjected to 10 000 permutations and required a voxel-level significance of P < 0.005 (we also report P < 0.001). This procedure should effectively balance inference on reliable areas of activation without generating a bias toward false positives ( Laird et al., 2005 ; Eickhoff et al., 2011 ).

Third, we used the ALE statistic to look for co-activation across the brain with specific regions-of-interest (ROIs). This was done by: (i) identifying reported foci within the ROI, for the contrast of interest, in the corpus of studies, (ii) identifying all other foci reported from the same contrasts in studies that also reported activation within the ROI and (iii) computing ALE statistics for the set of identified foci. Note that this third procedure is similar to the first one, except for the fact that the set of foci included is restricted by co-activation with the ROI. Thus, significant clusters of activation outside the ROI can be interpreted as areas that reliably co-activate with the ROI across studies, for the contrast of interest. A similar logic has been previously employed to identify networks using meta-analyses in other domains ( Toro et al., 2008 ; Smith et al., 2009 ; Gilbert et al., 2010 ; Cauda et al., 2011 ). The ROIs used in the co-activation analysis were constructed using 9 mm radius spheres about peak coordinates of activation taken from the ALE analyses of interest.

We note that other methods have been proposed for carrying out these types of CBMA, such as kernel density analysis, or KDA ( Wager et al., 2003 , 2007 ; Kober and Wager, 2010 ). However, both ALE and KDA are based on aggregating foci reported for any given study into a single MA map, which are then combined across studies to identify spatial convergence. A full comparison of KDA and ALE is beyond the scope of this article, but has been discussed elsewhere ( Kober and Wager, 2010 ; Eickhoff et al. , 2012 ).

All analyses were performed in Montreal Neurological Institute (MNI) space. Coordinates from studies reported in Talairach space were converted to MNI using an algorithm available within GingerALE ( Lancaster et al., 2007 ). All coordinates reported here are in MNI space. All images of statistical brain maps were generated using MRICron ( Rorden et al., 2007 ) and the MNI-152 1 mm template.

Construction of dataset for image-based meta-analysis

When feasible, we also carried out a parallel image-based meta-analysis (IBMA). This was done using data from previously published fMRI studies including the last author of this article ( Table 2 ). Each of the included studies provided a group-level statistical parametric map (SPM, an unthresholded t -statistic image) for the corresponding parametric value contrasts reported in each study. All of these analyses were completed in SPM5 or SPM8 ( Friston, 2007 ). The remainder of the IBMA was completed using utilities from FMRIB Software Library (FSL) 4.1.8 ( Woolrich et al., 2009 ). Once provided with the t -statistic data and the degrees of freedom corresponding to those SPMs, we converted the images to z -statistics. To minimize interpolation, all of the images were resampled to a common space using a 3 × 3 × 3 MNI template, which was the voxel size in most of the included studies.

Statistical inference for image-based meta-analysis

We carried out two different tests using IBMA. The first one is based on Stouffer’s z -statistic, which allows for fixed-effects tests ( Lazar et al., 2002 ; Salimi-Khorshidi et al., 2009 ). If there are N studies and each study i has a z -statistic Z _i at a given voxel, the Stouffer’s Z for that voxel across the N studies is equal to: . Second, we carried out a random-effects version of the Z -maps on the corpus of studies using an ordinary least squares mixed-effects model, implemented in FSL. The statistics reported below are based on the random-effects analysis, although the same set of regions were identified in both cases.

We evaluated the significance of the IBMA using the standard familywise error correction implemented in FSL ( Woolrich et al., 2009 ). Significant voxels were required to have P < 0.001 (equivalent to ∼ z > 3.1) and a cluster forming threshold of P < 0.05 was then used across the whole brain. Importantly, as there were differences in brain coverage across studies, using a conservative ‘meta-analysis mask’ that requires a voxel to be present in all contrasts to be included, would eliminate many of the voxels found in many of the studies, particularly in the parietal lobes. So, we instead employed a more liberal threshold for inclusion in the inference (voxel present in N > 10 studies). Note that although this is a more liberal inclusion criterion, it ultimately leads to more conservative significance testing; it increases the number of voxels and thus effectively increases the threshold of the multiple comparisons correction.

As in the CBMA, all coordinates reported here are in MNI space. All images of statistical brain maps were generated using MRICron ( Rorden et al., 2007 ) and the MNI-152 1 mm template.

RESULTS

Regions that reliably correlate with the value of stimuli

We first carried out a CBMA to identify all of the areas that exhibit reliable correlation with behavioral measures of the value of stimuli, both at the time of decision or at the time of outcome, across all tasks and reward modalities. For this reason, the analysis included any foci that were reported to correlate with any parametric measure related to the value of the stimuli, such as decision values, outcome values or chosen values (contrasts = 104, foci = 811). However, it did not include foci in which activity was correlated with variables that are correlated with value, but are not value signals per se , such as reward prediction errors.

The CBMA found distinct clusters of VMPFC, ventral striatum (VSTR) and posterior cingulate cortex (PCC) were significantly correlated with this broad measure of subjective value across studies ( Figure 1 and Table 3 ). The VMPFC cluster extends into medial orbitofrontal cortex (OFC) as well as to more anterior parts of PFC, such as frontopolar cortex and anterior MPFC. It includes both regions of subgenual and subcallosal anterior cingulate cortex (ACC) ( Beckmann et al., 2009 ) and lies within networks commonly referred to as the orbital-prefrontal and medial-prefrontal networks ( Price and Drevets, 2010 ). For PCC, there were two distinct clusters, ventral (vPCC) and dorsal (dPCC). An additional cluster was also found in the thalamus, centered on a subregion of the thalamus previously shown to have strong projections to prefrontal cortex ( Behrens et al., 2003 ). The cluster containing the global maximum ALE statistic was found in left VSTR (ALE = 68.89 × 10 ⁻³ ).

The CBMA results in Table 3 and Figure 1 suggest that there might be a left–right asymmetry for the probability that ventral prefrontal cortex reflects the computation of subjective value. Given the importance of this region in the decision-making literature, we carried out an additional post hoc test: we used four anatomical ROIs from the Automatic Anatomical Labeling (AAL) atlas to test whether higher ALE values were more likely in the left as opposed to right ventral prefrontal cortex. We also selected two coordinates from the Harvard-Oxford atlas [(x,y,z) = (±22,24,−22) and (x,y,z) = (±32,36,−14)]. The probabilistic atlas assigns >90% to OFC for the first set of coordinates and approximately splits OFC and frontal polar cortex with the second set of coordinates. We drew 6 mm radius spheres about these coordinates in each hemisphere. After generating a null distribution from 10 000 permutations of ALE values across the two hemispheres for each ROI, we compared the difference in average ALE values for several subregions of ventral prefrontal cortex ( Table 4 ). Looking at the four different AAL structures, the left mask exhibited a significantly greater average ALE ( P < 0.001) in three of the four masks, with only the orbital part of the inferior frontal gyrus in the opposite direction). The average ALE statistic was also larger on the left when the four masks were combined ( P < 0.001). The same was also true for the spherical OFC region (±22,24,−22). We also looked at the total number of voxels in the left hemisphere that were greater than the maximum ALE value in the right hemisphere (right-most column in Table 4 ). This measure also supports a trend for greater ALE statistics in the left hemisphere. So, at least for our corpus of studies, there appears to be an increased likelihood for peak coordinates associated with the computation of subjective values to be reported in left ventral prefrontal cortex.

The amygdala, an additional area often associated with the computation of value ( Rolls, 2000 ; Seymour and Dolan, 2008 ), did not survive our statistical threshold. However, a small cluster in left amygdala did pass a voxel-level threshold of P < 0.005 (without cluster correction).

Distinct subnetworks co-activate with the VMPFC stimulus value regions

We next investigated how the set of areas that exhibit reliable correlation with stimulus value signals is organized into distinct subnetworks that co-activate together. In particular, as our meta-analysis of all possible stimulus value measures identified three local clusters in VMPFC ( Figure 1 and Table 3 ), we hypothesized that those subregions of VMPFC might be part of distinct subnetworks involved in the computation of various value-related signals. To test this hypothesis, we constructed three spherical 9 mm ROIs around the coordinates exhibiting local maxima in the previous ALE analysis ( Figure 2 a). We refer to these ROIs as central VMPFC [cVMPFC, red; (x,y,z) = (−2,40,−4)], ventral VMPFC [vVMPFC, blue; (x,y,z) = (−2,28,−18)] and anterior VMPFC [aVMPFC, green; (x,y,z) = (−4,58,−8)]. Then, we looked for areas that exhibited reliable co-activation across the corpus of studies. Of these three ROIs, cVMPFC was the one for which the most significant correlation with stimulus values was reported in the previous literature (contrasts = 19, foci = 200), followed by vVMPFC (contrasts = 17, foci = 120) and aVMPFC (contrasts = 9, foci = 105).

The analysis revealed common and distinct areas of co-activation with the three VMPFC ROIs. All of the significant common regions of co-activation were constrained to the subgenual portion of the cingulate cortex and generally within the cVMPFC seed ( Figure 2 b). Two of the three ROIs also exhibited co-activation with distinct cortical networks ( Figure 2 c). The first seed region, cVMPFC, significantly co-activated with dPCC (ALE = 26.32 × 10 ⁻³ ), left VSTR (ALE = 21.86 × 10 ⁻³ ), lateral OFC (lOFC, ALE = 15.10 × 10 ⁻³ ) and SFG (ALE = 14.71 × 10 ⁻³ ). In contrast, aVMPFC reliably co-activated with left angular gyrus (ANG) near the temporal parietal junction (ALE = 13.38 × 10 ⁻³ ) and vPCC (ALE = 13.57 × 10 ⁻³ ). Although the ANG result for aVMPFC does survive in a direct contrast of ALE maps with cVMPFC ( P < 0.005), the other pairwise comparisons do not survive a direct contrast, even at lower thresholds. A potential reason is that these other pairwise comparisons of ALE maps are relatively underpowered (e.g. 9 and 17 contrasts), a limitation that should be addressed in future meta-analyses that can rely on a larger sample of studies. Interestingly, the regions co-activating with the cVMPFC and aVMPFC seeds are remarkably similar to some of the subnetworks of the canonical default mode network, a result found across a wide variety of tasks ( Smith et al., 2009 ; Andrews-Hanna et al., 2010 ).

Comparison of decision and outcome value signals

We next tested if distinct sets of areas are involved in the computation of stimulus values at the time of decision and at the time of outcome ( Rangel and Hare, 2010 ; Rushworth et al., 2011 ). To look for reliable commonalities or differences in decision and outcome value computations, the test was carried out in several steps.

First, we completed a CBMA to look for areas that exhibit reliable correlations with stimulus value at the time of decision. So, this analysis was constrained to the subset of studies and contrasts that looked at parametric measures of subjective value during the decision phase (contrasts = 69, foci = 571). This analysis identified a network of regions that included a large cluster in VMPFC extending to frontal polar cortex and MPFC and smaller clusters in bilateral VSTR and dPCC ( Figure 3 and Table 5 ). The global maximum ALE statistic was found in the paracingulate gyrus, part of the VMPFC cluster (ALE = 63.29 × 10 ⁻³ ).

Second, we were able to carry out a parallel IBMA of decision value, which is the gold standard test for reliability in fMRI meta-analysis studies ( Salimi-Khorshidi et al., 2009 ; Kober and Wager, 2010 ). The IBMA identified a similar set of regions demonstrating a positive correlation with value ( Figure 4 and Table 6 ), including VMPFC, which was the global maximum [(x,y,z) = (0, 39,−3), maximum z = 6.88]. The IBMA also found distinct clusters of activation in dPCC and vPCC, paralleling the results found in the CBMA ( Figure 1 ) for the pooled value signals. An additional cluster was also identified in the superior frontal gyrus (SFG).

Our IBMA also afforded us the opportunity to inspect the data for negative correlates of decision value, an option that was not possible in the CBMA as most studies do not report negative correlations with subjective value. We found no voxels that survived the threshold employed for the main IBMA result. However, two loci survived a lower threshold of P < 0.005 (no cluster-level correction) and we report them for completeness: precentral gyrus [(x,y,z) = (−60,9,12), z = 3.29, 4 voxels) and SFG [(x,y,z) = (18,0,72), z = 2.89, 2 voxels].

Two differences between the IBMA and CBMA results regarding the computation of value at the time of decision are noteworthy: the cluster of significant activity in VSTR appears more robust in the CBMA than in the IBMA and the SFG exhibiting reliable correlation with stimulus values at the time of decision in the IBMA, but not in the CBMA. The difference in SFG significance is perhaps attributable to the influences of subthreshold results that are only obtainable in IBMA ( Salimi-Khorshidi et al., 2009 ). With respect to the differences in VSTR, as all of the IBMA studies come from the same laboratory, one natural explanation would be that the fMRI data acquisition used by this group has a limited ability to identify signal in the VSTR. However, several of the included papers have reliably found activity in this area related to value and prediction errors ( Hare et al., 2008 ; Lim et al., 2011 ; Litt et al., 2011 ). As many of the IBMA studies used food as the reward modality, another potential explanation is that somehow food has a differential ability to activate the VSTR in response to value. Again, this seems unlikely, as several of the studies cited above reliably exhibit value activity in this area in tasks involving foods. Understanding why the VSTR correlates with subjective values in some paradigms but not in others is a critical question for future research.

Third, we carried out a CBMA to look for areas that exhibit reliable correlations with stimulus value at the time of outcome across studies. Note that a value measure at the time of reward receipt (e.g. delivery of reward such as juice or a visual image) is computationally distinct from a stimulus value computed for the purpose of guiding decisions. For this analysis we only included the subset of studies and contrasts that looked at parametric measures of subjective value during the outcome or reward consumption phase (contrasts = 32, foci = 200). The analysis identified two distinct clusters ( Figure 5 and Table 7 ): one in VMPFC/OFC (ALE = 20.20 × 10 ⁻³ ) and one in bilateral VSTR (ALE = 21.98 × 10 ⁻³ ).

Finally, we carried out a direct contrast of the ALE maps associated with the computation of stimulus values at decision and outcome, in order to identify regions that are more reliably associated with one of these phases across studies ( Figure 6 and Table 8 ). The results in both directions of the contrast were very focal. Both dPCC and a specific subregion of VMPFC were more reliably correlated with decision values than with outcome values ( Figure 6 a). In contrast, a more anterior part of MPFC (near the frontal pole) and a portion of subcallosal cortex (very near VSTR) were more reliably correlated with outcome values ( Figure 6 b). We also performed a conjunction analysis of the ALE maps for decision value and outcome value ( Figure 6 c). This analysis revealed that VSTR and a region of VMPFC (more medial than the one depicted in Figure 6 b) were reliably associated with both value computations.

Value signals for different reward modalities

Finally, we carried out a CBMA to investigate if there is evidence for regional specialization in the computations of stimulus values for different reward modalities (e.g. food vs money). To investigate this question, we took the corpus of reported results and partitioned it by reward modality, while making no distinction between the timing of the value signal (i.e. decision vs outcome). Of the possible categories, the most common reward modality was money (contrasts = 50, foci = 432). We also had a large number of studies using various types of foods (e.g. snack foods or juices; contrasts = 24 contrasts, foci = 163). Finally, we had a remaining set of studies with other rewards (e.g. rewarding visual images such as human faces, or donations to charities; contrasts = 24 contrasts, foci = 143). The handful of studies that employed multiple reward modalities on a single trial was excluded from this analysis.

Each of the three sets of studies revealed several reliable clusters of activation ( Figure 7 ). The global maximum for money (ALE = 43.57 × 10 ⁻³ ) was in VMPFC, but there were also distinct clusters in VSTR, dPCC and SFG ( Figure 7 a). For food, the global maximum (ALE = 26.21 × 10 ⁻³ ) was also in VMPFC, but with a more posterior peak ( Figure 7 b). For the other category, the maximum (ALE = 32.88 × 10 ⁻³ ) was located in VSTR, but there was also a separate cluster in VMPFC ( Figure 7 c). Note that for money, the larger extent of the ALE maps is due, most likely, to the fact that there is more data reported for that modality and thus our analyses have more statistical power in that case. Additional cluster information for each reward modality is listed in Table 9 .

To identify areas that were significant with value across all the reward modalities, we took the intersection of money, food and other maps ( Figure 7 d, left). Only a portion of VMPFC was significant in all three. We also inspected the ALE maximum in VMPFC for each of the reward categories ( Figure 7 d, right), using coordinates surrounded by 5 mm radius spheres for display purposes. The most ventral and posterior maximum clearly belongs to studies of food. Although one of the money local maxima (green) overlaps with the other category (blue), we note that the reward modality with the most anterior cluster was money. This result also holds if the other category is split into rewards that are immediately consumable (e.g. visual images) and the remaining unclassified reward types (cyan for ‘consumable’ and magenta for ‘miscellaneous’, Figure 7 d, far right). This gradient suggests a posterior-to-anterior gradient of value representations for reward modalities, with posterior corresponding to more concrete rewards and anterior to more abstract rewards. Importantly, we also performed a direct test across these reward modalities. Although the contrasts have limited statistical power, a direct contrast of money and food found a significantly greater likelihood for food in posterior VMPFC [ P < 0.005, maximum z located at (x,y,z) = (−8,27,−13)] and for money in anterior VMPFC [ P < 0.005, (x,y,z) = (−5,60,−9)]. Similarly, a contrast of other relative to money found a significantly greater activation likelihood near the peak for other in Figure 7 d [ P < 0.005, (x,y,z) = (−12,46,11)] and a more dorsal anterior part of MPFC [ P < 0.005, (x,y,z) = (−1, 56,10)] for money relative to other. The third pair of comparisons, between food and other, had the least power, but again found a posterior portion of VMPFC for food relative to other ( P < 0.005, (x,y,z) = (−4,28,−20)]. The opposite contrast, however, did not find any significant differences, even at the more liberal threshold of P < 0.01.

One important concern with this last set of analyses is that, across studies, there might be a substantial correlation between the type of reward and the time of the value signal. For example, while studies of value coding at the time of consumption frequently use liquids and foods (e.g. receiving a squirt of juice in the scanner), studies using trinkets or money as rewards can effectively only look at value coding at the time of decision (e.g. choosing between two gambles). To address this concern, we carried out one additional post hoc test in which we fixed the reward modality to foods, and computed separate ALE values at the time of decision and at the time of outcome ( Figure 8 ). Unfortunately, due to the smaller number of studies available (12 for each decision and outcome), the tests are comparatively underpowered. For that reason, we report all results at P < 0.001, without a cluster-level correction. As can be seen in Figure 8 , the results are similar to those for the comparison between decision and outcome value signals, including the robust posterior VMPFC result for food.

DISCUSSION

We have carried out a comprehensive meta-analysis of fMRI studies that use computational methods to study value-based choice. The large number of studies included allowed us to investigate four basic questions that cannot easily be addressed within a single fMRI study. We organize our discussion around the key findings relating to these questions.

First, we characterized the full set of areas that reliably correlate with stimulus values when they need to be computed (i.e. either at the time of decision or at the time of outcome) across tasks and reward modalities. We found that neural responses in VMPFC and VSTR are correlated with various measures of stimulus values across a wide range of decision tasks, reward modalities and stages of the decision-making process. This result is consistent with recent reviews of the literature ( Rangel et al. , 2008 ; Wallis and Kennerley, 2010 ; Glimcher, 2011 ; Grabenhorst and Rolls 2011 ; Padoa-Schioppa, 2011 ; Rushworth et al., 2011 ), although the meta-analysis used here provides a more rigorous test of the reliability of these findings across studies.

Unlike VMPFC and VSTR, however, PCC is an area that has received much less attention in the value-based choice literature. Yet, our results establish the reliability of activity correlated with stimulus values in two distinct loci in PCC, a ventral region and a more dorsal region. Indeed, distinct clusters are apparent in both the CBMA ( Figure 1 ) and IBMA ( Figure 4 ) results. These two regions of PCC have been implicated in various functions that might be useful in guiding the computation of values, such as attending to internal vs external influences ( Nakao et al., 2012 ), remembering past events or envisioning future ones ( Schacter et al., 2007 ) and monitoring local environment changes ( Pearson et al., 2011 ). PCC is also a central node of the default mode network ( Buckner et al., 2008 ), and recent work has made distinctions between ventral and dorsal PCC that may correspond to some of the aforementioned functions ( Leech et al., 2011 ). Understanding the precise role of the PCC in the network of regions that contribute to value-based decisions remains an important and open question.

Another area that deserves further consideration is the superior frontal sulcus (SFS), which demonstrated a significant and reliable correlation with decision value in our IBMA. Although the precise contribution of SFS to value-based choice is unknown, it is worth noting that the reported cluster in our IBMA closely neighbors the coordinates reported to correspond to sensory evidence in a perceptual decision-making task ( Heekeren et al., 2004 ) and includes the SFS coordinates reported for the comparisons of cost and benefit in a value-based choice task ( Basten et al., 2010 ).

Second, we asked if the set of areas associated with valuation are organized into dissociable functional networks across tasks and reward modalities. We found that a broad region of VMPFC contains a reliable value signal, a fact that has been previously noted ( Grabenhorst and Rolls, 2011 ; Wallis, 2012 ). However, our co-activation results ( Figure 2 ) suggest that this region of VMPFC is divided into subregions that co-activate with different networks: one that involves central VMPFC, dorsal dPCC and VSTR, and another that involves more anterior VMPFC, left ANG and vPCC. These results corroborate a recent functional parcellation of OFC ( Kahnt et al., 2012 ), which found evidence for the existence of an interaction between distinct functional networks within OFC. Furthermore, these two networks involving VMPFC are remarkably similar to some of the subnetworks of the default mode network found across a wide variety of tasks ( Smith et al., 2009 ; Andrews-Hanna et al., 2010 ). An intriguing hypothesis is that different value computations require different levels of episodic memory and mental simulations and are thus likely to recruit regions associated with the default mode network ( Pearson et al., 2011 ; Mars et al., 2012 ). The centrality of VMPFC for integrating this relevant information from a variety of networks has been argued elsewhere ( Roy et al., 2012 ).

Third, we tested for commonalities and dissociations in the set of areas involved in the computation of stimulus values at decision and outcome. Our results suggest a dissociation with respect to the comparison of stimulus value signals at decision and outcome. We found that dorsal PCC and a specific subregion of central VMPFC were more reliably correlated with decision values than with outcome values, whereas a more anterior part of MPFC (near the frontal pole) and a portion of subcallosal cortex (near VSTR) were more reliably correlated with outcome values ( Figure 6 ). However, the most striking pattern was the existence of reliable stimulus value-related activity in regions of VMPFC and VSTR at both decision and outcome. This commonality suggests the interesting possibility that these areas are involved in computing stimulus value whenever such variables are needed, regardless of the phase of the decision task.

Fourth, we investigated for commonalities and dissociations in the set of areas involved in the computation of stimulus values for different reward modalities (e.g. food vs money). We found that reward modality may also affect the precise location of VMPFC in which value is encoded. Our results include suggestive evidence of a posterior-to-anterior gradient of value representations ( Figure 7 ), corresponding to concrete-to-abstract rewards. This finding is consistent with previous hypotheses and results ( Kringelbach and Rolls, 2004 ; Sescousse et al., 2010 ; Grabenhorst and Rolls, 2011 ), although those primarily discuss OFC. Anatomical studies of OFC connectivity, such as those looking at sensory inputs to OFC, suggest that it might be organized in a graded fashion ( Carmichael and Price, 1995 ). A more recent report, looking specifically at decision value computations ( McNamee et al., 2013 ), also finds evidence for such a gradient. A comprehensive understanding of the extent of such a hierarchy of value representation in OFC and VMPFC, however, will likely require both more cross-species work ( Wallis, 2012 ) and careful analysis of how different fMRI acquisition sequences may affect results in more orbital parts of prefrontal cortex ( Roy et al., 2012 ). Furthermore, our results employ a fairly coarse classification of reward modality. Even within food rewards, it would be a valuable exercise to consider the different sensory contributions to food evaluation ( Rolls and Grabenhorst, 2008 ). An exciting avenue for further work would be to generate cleaner taxonomies of reward modalities and their complexity as well as if and how those might have similar or distinct neural representations along a VMPFC gradient.

Notably, our analyses did not identify several regions commonly associated with decision-making computations. First is the more dorsal region of the ACC and the neighboring dorsal medial prefrontal cortex (DMPFC). This area has had several wide classes of computations attributed to it, including decision and strategic control ( Venkatraman et al., 2009 ), environment volatility ( Behrens et al., 2007 ) and multiplexing of decision parameters ( Kennerley et al., 2009 ; Hayden and Platt, 2010 ; Hare et al., 2011b ). Similarly, action value signals—which take into account the action costs associated with the choice of a particular option—are also commonly attributed to ACC ( Rangel and Hare, 2010 ; O'Doherty, 2011 ). These distinct computational roles for ACC and DMPFC, coupled with those areas appearing in comparatively few contrasts of interest in fMRI studies of simple choice, are likely reasons for their absence in our results. Second, the amygdala is also commonly discussed in various aspects of reward processing ( Rolls, 2000 ; Gottfried et al., 2003 , Seymour and Dolan, 2008 ). Although a correspondence between subjective value and amygdala was identified at a lower threshold in our CBMA, the precise computations that amygdala contributes to subjective value may not be sufficiently represented in our corpus of studies. Finally, various parts of dorsal lateral prefrontal cortex (DLPFC), which have been found in some studies to correlate with representations of stimulus values ( Plassmann et al., 2007 ; Hare et al., 2009 ; Plassmann et al., 2010 ; Baumgartner et al., 2011 ; Hutcherson et al., 2012 ), were also not identified in the meta-analyses. One potential explanation for this negative result is that DLPFC might only be involved in tasks involving the evaluation of sufficiently abstract stimuli or self-regulation ( Hutcherson et al., 2012 ), which are relatively uncommon in the existing literature.

There are also some important limitations of the study. First, we were unable to consider contrasts from paradigms that involve the comparison of options from distinctly different reward modalities (e.g. choosing movie tickets vs ice cream). Although some fMRI studies do take various approaches to address this issue ( FitzGerald et al., 2009 ; Grabenhorst et al., 2010 ; Smith et al., 2010 ; Levy and Glimcher, 2011 ), there are relatively few of these, so our meta-analyses did not directly assess the reliability of such value computations. As more studies attempt to identify common scales of valuation and comparison of different reward domains, it will be intriguing to test the spatial reliability of areas that demonstrate this property ( Grabenhorst et al., 2010 , Levy and Glimcher 2011 , McNamee et al., 2013 ). Second, we did not formally test the coding of value for appetitive and aversive stimuli, although clearly a full understanding of value computation is incomplete in their absence ( Tom et al., 2007 ; Plassmann et al., 2010 ). Similarly, our methods did not allow us to dissociate the coding of value and salience signals ( Seeley et al., 2007 ; Bressler and Menon, 2010 ), which are difficult to tease apart in many decision experiments. However, one study in our corpus dissociates these two signals ( Litt et al., 2011 ), finding that the regions of VMPFC and PCC identified in our meta-analyses are associated with value but not saliency coding, and that VSTR is associated with both types of computations. There is also evidence for non-linear (e.g. quadratic) responses to subjective measures of value in a handful of fMRI studies ( O'Doherty et al., 2006 ; Todorov et al., 2011 ). Finally, our methods do not facilitate the delineation of regions that compute stimulus values from regions that compute reward prediction errors. This is an important limitation because these signals are highly correlated in many studies, a phenomenon that may also account for our common finding of reliable VMPFC and VSTR value signals at both decision and outcome. The few studies that have directly looked at separating these computations have found that VMPFC reflects values, whereas VSTR reflects prediction errors ( Hare et al., 2008 ; Rohe et al., 2012 ).

Despite these limitations, the analyses presented here offer a clear set of brain regions that are reliably recruited to compute subjective value. Many of the regions in our results mirror components of established functional networks ( Smith et al., 2009 ; Andrews-Hanna et al., 2010 ; Bressler and Menon, 2010 ). An important step in constructing a biologically plausible model of value computation in the brain ( Clithero et al., 2008 ; Fehr and Rangel, 2011 ; Glimcher, 2011 ) requires identifying accurate constraints on computations, and networks in the brain are one of those key constraints. Thus, the network of areas identified in our meta-analyses point to important open questions about the computation of subjective value that should be addressed in future fMRI studies. In this way, informatics can be employed to guide future studies of decision-making systems in the brain ( Poldrack, 2010 ; Yarkoni et al., 2010 , 2011 ).

Conflict of interest

None declared.

We acknowledge funding from the National Science Foundation , the Lipper Foundation and the Gordon and Betty Moore Foundation .

REFERENCES