Measures and Stimuli

Emotional Faces Paradigm

Participants viewed standardized gray-scale face stimuli consisting of female and male individuals depicting affective expressions (Ekman and Friesen, 1976), using six happy (H), six fear (F), six neutral (N) stimuli. All faces were matched for overall luminosity and size, and were equally aligned on a black background template. Each face was presented for 200 ms, with a 300-ms interstimulus interval in a pseudorandom order such that facial expressions of a single identity are never presented in succession. Each block of faces was 16 s in duration (e.g., 32 fearful faces were presented in each fear block). Interspersed eye fixation blocks (+) between faces stimuli blocks were jittered lasting approximately 10–17 s each. There were two runs. The first run consisted of the following series of blocks: +N+H+F+H+F+N+F+H+N+ and the second run was +N+F+H+F+H+N+H+F+N+ (see Figure ​Figure11). This paradigm was modeled after those used in previous studies to evoke fear circuitry (Shin et al., 2005). The facial stimuli were displayed using standardized software (MacStim 3.0; WhiteAnt Occasional Publishing, West Melbourne, Australia). Each run was approximately 5; 10 min for the entire evoked paradigm. Immediately after each scanning session, participants were asked to rate the facial expressions on scales of valence (negative to positive, –3 to +3) and arousal (low to high, 0–6).

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FIGURE 1

Facial expression paradigm. All neutral, happy, and fearful blocks are 16 s in duration with interspersed eye fixation blocks jittered lasting approximately 10–17 s each. Male and female faces in each block were presented in a pseudorandom order such that facial expressions of a single identity are never presented in succession for a total of 32 faces presented in each block. There were two runs. The first run consisted of the following series: +N+H+F+H+F+N+F+H+N+ (as depicted above) and the second run was +N+F+H+F+H+N+H+F+N+. +, eye fixation; N, neutral faces; H, happy faces; F, fearful faces.

MRI Acquisition

Subjects underwent MRI on a 3 T (Siemens Medical Solutions, Erlangen, Germany) scanner using a 12-channel head coil. For each participant, we collected a 3D T1-weighted anatomical scan using a magnetization-prepared rapid acquisition gradient echo (MPRAGE) sequence (128 slices; TR = 2100 ms; TE = 2.74 ms; TI = 1100 ms; 256 × 256 matrix; FOV = 200 mm; 1.33 mm × 1.0 mm × 1.0 mm voxels). Two 5-min evoked fMRI scans were acquired using a T2-weighted echo-planar pulse imaging (EPI) sequence (41 interleaved slices; TR = 2500 ms; TE = 30 ms; 64 × 64 matrix; FOV = 1680 mm; 3 mm × 3 mm × 3 mm voxels; 120 volumes). Subjects were instructed to look carefully at the pictures and were told that they would be asked questions about them after the MRI.

Pain and PRF

Among the 16 patients, 81.3% of patients self-reported moderate to severe average pain levels (average pain intensity ± SE = 6.17 ± 0.61). Median duration of pain was 7 months (average pain duration = 13.25 ± 3.87). For PRF, 50% (n = 8) reported high PRF (average PRF = 48.06 ± 3.77). PRF and pain intensity were not statistically significantly associated with one another (r = –0.20; p = 0.45).

Facial Expression Ratings

Ratings of valence and arousal were submitted to separate 2×3 (group [patient vs. healthy control] × expression [neutral, happy, fear]) analyses of variance. For valence, there was a significant main effect for expression (F_2,102 = 189.7, p < 0.01), but not for group (see Figure ​Figure22). Post hoc testing showed significant valence rating differences among all three types of facial expressions; fearful (-1.34 ± 0.16) vs. happy (2.31 ± 0.12), t(33) = –16.7, p < 0.01; fearful vs. neutral (–0.47 ± 0.12), t(33) = –6.00, p < 0.01, and neutral vs. happy, t(33) = –15.3, p < 0.01. Analysis of the arousal ratings revealed a significant main effect for expression (F_2,102 = 8.69, p < 0.01), but not for group. Post hoc testing showed significantly lower arousal ratings for neutral faces (1.70 ± 1.27) vs. fearful (2.90 ± 1.33), t(33) = –5.76, p < 0.01, and happy (2.87 ± 1.29), t(33) = –5.72, p < 0.01. Arousal ratings between happy and fearful did not significantly differ.

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FIGURE 2

Valence and arousal ratings across facial expressions. Patients and healthy peers did not differ on valence or arousal ratings for neutral, happy, and fearful faces. As expected, there were significant differences across emotions for valence, with fearful faces rated more negatively and happy faces rated more positively. For arousal, both fearful and happy faces were rated as significantly more arousing than neutral faces.

CNS Processing of Fear in CRPS

Previous studies have demonstrated an increased response in limbic areas during fear processing in patients with PTSD (Shin et al., 2005), social anxiety (Demenescu et al., 2013), and specific phobia (Etkin and Wager, 2007), with decreased response observed in panic (Pielech et al., 2014), thus we anticipated an altered evoked response in the amygdala among chronic pain patients compared to healthy peers, with this result amplified among high-fear patients compared to patients with non-elevated fear. We found that high PRF patients had a reduced response in the amygdala, potentially suggesting that as a result of ongoing aversive sensory processes, fear-related emotional circuits in chronic pain patients may be altered. Several processes may account for these results. First, other factors that contribute to pain such as the aversive nature of pain itself, as well as salience and reward processes, and stress may elicit alterations in multiple brain circuits. Additionally, patients may be so distressed by their own pain state that they are limited in their ability to empathize or connect with another’s emotional state due to the self-focused state driven by persistent pain signaling (Ochsner et al., 2006), therefore potentially resulting in a blunted response in fear-related emotional circuits.

Among the specific findings, we observed significant differences between patients and controls in the centromedial amygdala. This area has been implicated in generating behavioral responses to fearful stimuli through projections to the brainstem, as well as cortical and striatal regions, like the Cd (LeDoux, 2007). The amygdala has an important role and is significantly altered morphologically and structurally in chronic pain (Rodriguez-Raecke et al., 2009). Amygdala volume has been observed to be decreased in chronic pain (Rodriguez-Raecke et al., 2009), with our prior work in CRPS patients showing increased amygdala volume following treatment with reversal of pain symptoms (Erpelding et al., 2014), suggesting a role in both aversive behaviors (chronic pain) and rewarding effects (pain relief; Janak and Tye, 2015). As a key brain region for fear circuitry (Herry and Johansen, 2014), the amygdala may contribute to functional changes through connections that are altered in chronic pain including pediatric patients (Becerra et al., 2014; Erpelding et al., 2014; Simons et al., 2014b) and in the context of ongoing stress (Ressler, 2010). Dampened activity in the amygdala in patients compared to healthy matched controls may arise from emotional processing deficits, as having an evoked response to fearful stimuli in this region is adaptive. Additionally, persistent pain may hinder proper functioning activity in the centromedial amygdala and may modulate pain behavior through signals sent to descending pain control centers in the brain (Neugebauer et al., 2009).

Furthermore, prominent differences between patients and healthy controls were observed in the striatum and anterior Ins. Striatal regions are significantly involved in pain processing (Borsook et al., 2010; Maleki et al., 2011), and specifically, thought to integrate sensory, emotional, and cognitive processing. The Cd is also known to participate in learning and memory (Chase et al., 2015) and goal-directed behavior (Yanike and Ferrera, 2014). For example, fibromyalgia patients exhibit reduced activation in the Cd and hippocampus in response to the Stroop task (Martinsen et al., 2014). A recent study examined learning PRF and found that successful aversive learning was associated with activation in the Pt, Ins, and secondary somatosensory cortex (S2) (Gramsch et al., 2014). Additionally, less activation to pain in the Cd and Pt has been observed in high-frequency migraine compared to low-frequency migraine patients (Maleki et al., 2011). Our finding of differences in the bilateral anterior Ins, a region involved in the salience network (Uddin, 2015) and autonomic function, is tied to multiple fear-related adaptations. It is conceivable that altered salience in chronic pain reflects diminished awareness and responses to external stimuli unrelated to pain, which may be due to a perceived alteration in the body’s integrity (e.g., hemi-inattention; Forderreuther et al., 2004). A number of observations suggest that chronic pain patients exhibit abnormal salience processing (Seeley et al., 2007; Cauda et al., 2010; De Ridder et al., 2011; Weissman-Fogel et al., 2011). Beyond differences in key subcortical regions and the Ins, less response in the dlPFC was observed among patients compared to healthy controls. The dlPFC has a prominent role in top-down cognitive control in the context of emotion (Buhle et al., 2014) and pain (Erpelding and Davis, 2013) modulation. In addition to the well-established link between the amygdala and the dlPFC, it is structurally and functionally connected to the striatum (Jarbo and Verstynen, 2015). Taken together, the blunted response observed in patients appears to be present across learning and reward circuits.

When examining these findings in relation to imaging work conducted among adults with CRPS, the majority of brain imaging research among adults with CRPS has focused on somatosensory and motor cortex alterations (e.g., Di Pietro et al., 2013), although one recent study did find altered gray matter structure in the dlPFC (Pleger et al., 2014). Research comparing pediatric and adult patients with CRPS is needed.

Influence of Age in Response to Fearful Faces

Age and its interaction with brain activity has not been previously examined in pediatric pain, but given that fear-related neural activity has been observed in the PFC (Yurgelun-Todd and Killgore, 2006), we conducted a covariate interaction analysis by age. We found that the functional response in the ACC was greater with increased patient age, and was partially explained by pain duration. The ACC has an instrumental role in pain unpleasantness and PRF memory (Tang et al., 2005). It appears that a persistent pain state does relate to an increased evoked ACC response to fearful affective stimuli in contrast to healthy controls who demonstrate a general decrease in response across age. Importantly, no other brain regions emerged as differing between patients and controls by age, suggesting that the primary findings are not influenced by the child’s age. Accordingly, our findings suggest that altered fear circuits observed among pediatric CRPS can be attributed to disease state versus development.

The authors would like to thank Melissa Pielech, MA for contributing to the data collection.