Connectivity Strength of Dissociable Striatal Tracts Predict Individual Differences in Temporal Discounting

Delay discounting task.

Participants completed a total of 130 intertemporal choices inside and outside of the scanner (Fig. 1). The 60 trials outside of the scanner were determined by a staircase procedure. For this, the sooner smaller (SS) reward was fixed to $10 received today. The delay period (D) for the larger later (LL) reward was randomly chosen from a uniform distribution between 15 and 60 d in the future. The size of the LL reward was adjusted to converge toward the same subjective value as the SS outcome (V, in this task $10). We assumed that delay discounting is captured by a hyperbolic function: where A is the amount in dollars of the LL reward. The initial discount factor k was set to 0.02 and was increased or decreased when the participant chose the SS or LL option, respectively. For the first 20 rounds, the step size for changes is k was set to 0.01 and after that the step size decreased by 5% for each following step. After the participants completed 60 choices, we used the multivariate constrained minimization function (fmincon) of the optimization toolbox implemented in MATLAB for model fitting. To model trial-by-trial choices, we used a softmax function to compute the probability (P_SS) of choosing the SS option on trial t as a function of the difference in V_SS and V_LL: where m is the decision slope and estimates response noise. Individual discount factors were determined as the value of k that maximized the likelihood of the observed choices.

The individual discount factors that resulted from this procedure were used to generate a subset of the choices in the delay discounting task that was presented to participants in the scanner (see below). The SS delays in the fMRI task included 0 (today) and 14 d and the LL delays included 14, 28, and 42 d. The different delays were equally divided over a total of 70 trials, resulting in 35 trials in which the SS was today and 35 trials in which the SS option was in the future (14 d). The SS rewards were randomly selected from a uniform distribution between $10 and $75. Following earlier studies (McClure et al., 2004, 2007; Figner et al., 2010), we determined LL reward size by adding a fixed percentage to the SS amount (.5%, 1%, 5%, 10%, 15%, 20%, 25%, 30%, 50%, or 75%) for 48 of the 70 trials. Next, for 22 of the 70 choices, we set the reward size of the LL exactly at the individually estimated indifference point using the estimated discount factors (cf. Rodriguez et al., 2014). These LL choices were randomly distributed over the task. At the end of the experiment, one trial was randomly chosen from the total of set of 130 choices and paid to the participant in the form of a (postdated) check. Note that there was a high correlation between estimated discount rates (k) when estimated separately for the prescanner and scanner tasks (r = 0.88, p < 0.001).

To get an individual difference measure of delay discounting behavior, we fit the hyperbolic discounting function (Equation 1) to each individual's aggregate behavior of the two discounting tasks using the fitting procedure described above. Next we log-transformed the discount factors given that the k estimates were not normally distributed.

Zimbardo Time Perspective Inventory.

There is accumulating evidence that differences in time perspectives are one of the important psychological constructs underlying individual differences in delay discounting (Bickel et al., 2006; Erbert and Prelec, 2007; Wittmann and Paulus, 2008; Zauberman et al., 2009; Radu et al., 2011). For example, opioid-dependent participants, who showed dramatically larger discount rates than a matched control group, also scored significantly lower on the future orientation (FO) scale and significantly higher on the present hedonism (PH) scale of the Zimbardo Time Perception Inventory (ZTPI) (Petry et al., 1998; Zimbardo and Boyd, 1999). Furthermore, individual differences in future thinking modulate the effect of temporal priming (Peters and Büchel, 2010) and predict developmental changes in discounting (Steinberg et al., 2009). Based on these findings, we assayed time perspective using the FO and PH subscales of the ZTPI.

The ZTPI was administered as an online questionnaire several days before the MRI experiment. Participants indicated on a 1–5 scale how applicable each of the 56 items was to him/herself. Items that comprised the FO scale included: “I believe that a person's day should be planned ahead each morning,” and “Thinking about the future is pleasant to me.” Example of items on the PH scale are as follows: “I feel that it's more important to enjoy what you are doing than to get the work done on time” and “I try to live my life as fully as possible, one day at a time.”

MRI data.

MR data were collected on a 3T GE Discovery MR750 scanner located at Stanford Center for Cognitive and Neurobiological Imaging. High-resolution T1-weighted images were first acquired (0.47 × 0.47 × 0.9 mm³, TR = 8.67 ms, TE = 3.47 ms, flip angle = 12°).

Diffusion-weighted imaging data.

Diffusion-weighted imaging (DWI) was performed at a resolution of 0.85 × 0.85 × 2 mm³, with 3 repeats of the b0 (no diffusion weighting image) and 2 repeats of each of 30 gradient directions at b1000 (TR = 9 s, TE = 89 ms). The FMRIB Diffusion Toolbox (FDT, http://www.fmrib.ox.ac.uk/fsl/fdt) was used to correct the DTI data for head movement and eddy currents, tensor model fitting, and generating fractional anisotropy (FA) maps. Data from the two acquisitions of each diffusion direction were averaged to improve the signal-to-noise ratio.

fMRI data.

Whole-brain, BOLD-weighted echoplanar (TR = 2000 ms, TE = 30 ms, flip angle = 77°, 44 total slices with 2 mm slice gap, 64 × 64 matrix) images were then acquired ∼30 degrees off the anterior commissure–posterior commissure plane to maximize signal in the ventral prefrontal cortex and ventral striatum. fMRI data were analyzed using SPM8 (http://www.fil.ion.ucl.ac.uk/spm/). The first five volumes were not analyzed to accommodate T1 equilibration. Given the known problems of motion for connectivity analyses (Power et al., 2012), we used ArtRepair software to correct for excessive movement (Mazaika, 2007). Images were realigned in ArtRepair to correct for movement, smoothed with a 4 mm full-width half-maximum Gaussian kernel, and motion adjusted. Deviant volumes resulting from sharp movement or spikes in the global signal were then interpolated using the two adjacent scans. No >8 (median = 0, mean = 0.9) of the volumes were interpolated within any subject. We then applied slice-timing correction to all images. Next, motion correction to the first functional scan was performed using a six-parameter rigid-body transformation. The motion-corrected images was coregistered to each individual's structural MRI using a 12-parameter affine transformation. Images were then resampled into 3 × 3 × 3 mm³ voxels and spatially normalized to the Montreal Neurological Institute (MNI) template by applying a 12-parameter affine transformation. Images were finally smoothed with a 4 mm isotropic Gaussian kernel and adjusted for global signal variation using a voxel-level linear model of the global signal.

Tractography.

All diffusion image preprocessing and analyses were conducted using a combination of FSL tools and Nipy code (http://nipy.sourceforge.net/nipype/). Earlier studies have shown that the overall structural integrity of striatal fiber tracts is related to individual differences in impulsive behavior (Peper et al., 2013). Other studies have demonstrated that specific subsets of striatal tracts may be related to subcomponents of behavior (Behrens et al., 2003; Cohen et al., 2009; Draganski et al., 2008; Tziortzi et al., 2014). For example, the study by Cohen et al. (2008) used connectivity-based segmentation to show that novelty seeking was associated with connectivity strength of the subcorticostriatal tracts, but not with the corticostriatal tracts. Interestingly, their self-report measure of novelty-seeking relates (conceptually) to behavioral measures of impulsive behavior. The goal of our structural connectivity analyses was to identify specific corticostriatal and subcorticostriatal tracts. Next, we aimed to relate measures of structural connectivity strength with both functional connectivity and individual differences in discount rates.

FA is a measure commonly used in DTI studies to relate anatomical differences in white matter to behavior. Analyses of FA values are performed across the whole brain to identify regions of white matter related to behavior independent of particular axonal/fascicle tracts. In studies such as this one, in which we have particular interest in white matter pathways, seeded tractography is a superior approach because it allows analyses to target particular tracts in their entirety. Values derived from seeded tractography estimate the strength of pathways as a whole (Behrens et al., 2003; Cohen et al., 2009; Draganski et al., 2008; Tziortzi et al., 2014) and therefore provide a more direct test of hypotheses than is possible from voxel-level FA values.

Tractography analyses were performed in the subjects' native anatomical space and the results were output in MNI space by providing transformation parameters estimated via a 2-step procedure. First, the FA image was registered to each subject's high-resolution T1-weighted image with six degrees of freedom and a mutual information cost function. Next, the T1-weighted image was registered to the 1 × 1 × 1 mm³ MNI template using a nonlinear warping algorithm. The transformation parameters obtained from these two steps were concatenated to yield the mapping from the DWI to MNI space. The FDT toolbox was used to perform probabilistic tractography with a partial volume model (Behrens et al., 2003), allowing for up to two fiber directions in each voxel (Behrens et al., 2007). Dual-fiber models account for crossing fibers and thus yield more reliable results compared with single-fiber models. Five thousand sample tracts were generated from each voxel in the seed mask (striatum). Visual inspection ensured that tractography maps were successful and acceptable for further analysis. Tractography was performed separately for the left and right striatum and possible tracts were restricted to the hemisphere of origin using an exclusion mask of the contralateral hemisphere. The tractography results were used to identify anatomically distinct striatal segments in the segmentation step, next.

Segmentation.

To assess connectivity with extrastriatal regions, we used a set of 10 a priori masks defined as in Cohen et al., 2009 (Fig. 2A). These regions were based on single or a combination of the standard automated anatomical labeling (AAL) maps (AAL map number within parentheses): medial orbitofrontal cortex (mOFC: 28, 6, 26), vlPFC (10, 16), inferior frontal gyrus (pars triangularis, IFG: 14), dlPFC (4, 8), posterior cingulate cortex (68), ACC (32), dorsal ACC (dACC: 34), hippocampus (38), amygdala (42), and supplementary motor area (SMA: 20). These AAL numbers all correspond to the left hemisphere (subtract 1 for right hemisphere values). The striatum mask was obtained from the subcortical segmentation derived with freesurfer, to better account for anatomical hetereogeneity across subjects. Seed-based classification was done by first thresholding the images such that only voxels with at least 10 tracts terminating in one of the target regions were kept (Cohen et al., 2009; Forstmann et al., 2012). Finally, to tailor the cortical ROIs to the participants' individual anatomy, individually segmented gray matter (GM) and FA images were used to mask the ROIs. Following Tziortzi et al. (2013), the lower threshold for the GM mask was set at 0.25 and the FA mask upper threshold was set at 0.40. For the estimation of tract strength between the striatum and the target areas, MNI-space masks were normalized to each participant's native space using the inverse of the normalization parameters.

Following standard procedures, voxel values were converted into proportions; the value at each voxel was calculated as the number of tracts reaching the target mask for that voxel, divided by the number of tracts generated from the voxel (maximum 5000). This resulted in 10 value maps (for examples, see Fig. 2B), one for each target region, per participant. Finally, the striatum was segmented by assigning each voxel to the region with which it had the highest connection probability (Fig. 3, middle) using FSL utilities (Behrens et al., 2003; Johansen-Berg et al., 2004; Cohen et al., 2009; Tziortzi et al., 2014).

Note that the resulting segments are based on relative comparisons in connection strengths. Therefore, assigning a voxel to one target area does not exclude the possibility that tracts were found connecting to other target areas (for discussion, see Tziortzi et al., 2014). However, there are several reasons to believe the subdivision derived from one-to-one assignment is meaningful and helpful for better understanding of the functional subdivisions of the striatum and the related tracts. First, the ventromedial-to-dorsolateral connectivity profile resulting from the connectivity based segmentation procedure is consistent with the corticostriatal circuits previously identified in primates and other human diffusion MRI studies (Alexander et al., 1986; Behrens et al., 2003, Draganski et al., 2008 Cohen et al., 2009). Furthermore, a recent study using the same segmentation procedure showed that the homogeneity of dopamine release was significantly higher within the connectivity based segments compared with the classical structural subdivisions of the striatum (Tziortzi et al., 2014), supporting the hypothesis that the segmentation resulted in a meaningful functional subdivision of the striatum.

DICE coefficients.

To assess the intersubject spatial consistency of the striatal segments arithmetically, we calculated the DICE coefficient, which measures the volume overlap of striatal subdivisions across subjects. The DICE coefficient was estimated across subjects as the average overlap between a subject's striatal segment with striatal segments from all other subjects to determine whether the method and estimated connections were reproducible across subjects (individual subjects' scans were nonlinearly registered to the MNI template). The DICE coefficient was calculated as follows: where ∩ is the intersection of the ROI volumes and the norm (||) measures the number of voxels in the ROIs. The indices s and i refer to region number i in subject s. Note that the DICE value is calculate for each subject-region contrasted with the average from the group (i.e., ROI_group,i) The DICE coefficient ranges from 0% for ROIs with no overlap up to 100% for identical ROIs. DICE values obtained for all striatal segments were high and satisfactory (between 0.36 and 0.65), except for regions connected to SMA and pPC (<0.05, see Table 1). Furthermore, for 4 and 5 participants (respectively), there were zero striatal voxels that had the highest probability of connection to the SMA and pPC. For this reason, these two target areas were excluded from further analyses.

Tract strength correlations with discounting.

To determine whether individual differences in discounting were related to the strength of white matter fiber tracts, we calculated the mean value of the tract probability within each individually determined striatal segment (8 per hemisphere, 16 in total). Although the voxels of each segment were determined based on relative comparisons of probability maps, the connection strength is not relative, but is the proportion of all generated tracts (5000 per voxel) that terminated in the corresponding target region. The resulting tract strength measure was correlated across subjects with log(k) using Spearman's rank-order correlation (tract strength values are non-normally distributed, so nonparametric correlations are most appropriate) with the following covariates: age, IQ, total intracranial volume, and size (number of voxels) of the individually defined striatal segment. To account for possible effects driven by outliers, we also performed robust regression analyses with the Huber weighting function (using the robustfit algorithm in MATLAB) after log transforming tract probability values, which yielded the same pattern of results. Effects were considered significant at an α of 3.125 × 10⁻³, based on Bonferroni correction for multiple comparisons (i.e., p = 0.05/16 striatal segments).