Alexithymic features and automatic amygdala reactivity to facial emotion

Alexithymic individuals have difficulties in identifying and verbalizing their emotions. The amygdala is known to play a central role in processing emotion stimuli and in generating emotional experience. In the present study automatic amygdala reactivity to facial emotion was investigated as a function of alexithymia (as assessed by the 20-Item Toronto Alexithymia Scale). The Beck-Depression Inventory (BDI) and the State-Trait-Anxiety Inventory (STAI) were administered to measure participants' depressivity and trait anxiety. During 3T fMRI scanning, pictures of faces bearing sad, happy, and neutral expressions masked by neutral faces were presented to 21 healthy volunteers. The amygdala was selected as the region of interest (ROI) and voxel values of the ROI were extracted, summarized by mean and tested among the different conditions. A detection task was applied to assess participants' awareness of the masked emotional faces shown in the fMRI experiment. Masked sad and happy facial emotions led to greater right amygdala activation than masked neutral faces. The alexithymia feature difficulties identifying feelings was negatively correlated with the neural response of the right amygdala to masked sad faces, even when controlling for depressivity and anxiety. Reduced automatic amygdala responsivity may contribute to problems in identifying one's emotions in everyday life. Low spontaneous reactivity of the amygdala to sad faces could implicate less engagement in the encoding of negative emotional stimuli.     

Facial Reactions to Facial Expressions

Previous research has demonstrated that different patterns of facial muscle activity are correlated with different emotional states. In the present study subjects were exposed to pictures of happy and angry facial expressions, in response to which their facial electromyographic (EMG) activities, heart rate (HR), and palmar skin conductance responses (SCRs) were recorded. It was found that happy and angry faces evoked different facial EMG response patterns, with increased zygomatic region activity to happy stimuli and increased corrugator region activity to angry stimuli. Furthermore, both happy and angry faces evoked HR decelerations and similar SCR magnitudes. The results are interpreted as suggesting that facial EMG recordings provide a method for distinguishing between response patterns to “positive” and “negative” emotional visual stimuli.     

Recognition of dynamic facial expressions in peripheral and central vision

The present study investigated the effects of dynamic information on the recognition of emotional facial expressions across the visual field (i.e., central or peripheral vision). Facial stimuli with three pleasant expressions (excited, happy, and relaxed) and three unpleasant expressions (fearful, angry, and sad) were selected on the basis of valence and activation. The facial stimuli were presented dynamically or statically at either the central or peripheral visual field. Participants evaluated the emotional state of the target facial expression using a forced-choice task (N=34) and an Affect Grid (Russell, Weiss, & Mendelsohn, 1989) (N =39) requiring categorical and dimensional judgments about facial expressions. The results of the forced-choice task showed that only dynamic angry faces in peripheral vision had better recognition than the equivalent faces in the static condition. The results of the Affect Grid indicated that only the pleasant expressions presented in the peripheral field were significantly rated as more strongly pleasant. These findings suggest that an effect of dynamic information is more salient in peripheral vision than in central vision for recognizing certain facial expressions.     

Do not prime too much: Prime frequency effects of masked affective stimuli on effort-related cardiovascular response

This experiment investigated the prime frequency effect of masked affective stimuli on effort-related cardiovascular response. Cardiovascular reactivity was recorded during a baseline period and an attention task in which either 1/3, 2/3, or 3/3 of the trials included the presentation of masked emotional facial expressions (sad vs. happy). In the resting trials participants were exposed to masked neutral expressions. As expected, and replicating previous findings (Gendolla and Silvestrini, in press), participants in the 1/3 priming condition showed stronger systolic blood pressure reactivity - indicating more effort - when they were exposed to masked sad faces than when they were exposed to masked happy faces. This effect disappeared in the 2/3 and 3/3 conditions. Findings are interpreted as demonstrating habituation effects of masked affective stimuli on effort mobilization.     

Electromyographic responses to emotional facial expressions in 6-7year olds: A feasibility study

Preliminary studies have demonstrated that school-aged children (average age 9-10years) show mimicry responses to happy and angry facial expressions. The aim of the present study was to assess the feasibility of using facial electromyography (EMG) as a method to study facial mimicry responses in younger children aged 6-7years to emotional facial expressions of other children. Facial EMG activity to the presentation of dynamic emotional faces was recorded from the corrugator, zygomaticus, frontalis and depressor muscle in sixty-one healthy participants aged 6-7years. Results showed that the presentation of angry faces was associated with corrugator activation and zygomaticus relaxation, happy faces with an increase in zygomaticus and a decrease in corrugator activation, fearful faces with frontalis activation, and sad faces with a combination of corrugator and frontalis activation. This study demonstrates the feasibility of measuring facial EMG response to emotional facial expressions in 6-7year old children.     

Startle modulation by affective faces

Startle reflex modulation by affective pictures is a well-established effect in human emotion research. However, much less is known about startle modulation by affective faces, despite the growing evidence that facial expressions robustly activate emotion-related brain circuits. In this study, acoustic startle probes were administered to 37 young adult participants (20 women) during the viewing of slides from the Pictures of Facial Affect set including neutral, happy, angry, and fearful faces. The effect of expression valence (happy, neutral, and negative) on startle magnitude was highly significant (p < .001). Startle reflex was strongly potentiated by negative expressions (fearful and angry), however, no attenuation by happy faces was observed. A significant valence by gender interaction suggests stronger startle potentiation effects in females. These results demonstrate that affective facial expressions can produce significant modulation of the startle reflex.     

Neural systems of threat processing in adolescents: role of pubertal maturation and relation to measures of negative affect

Adolescence ushers in dramatic social and affective changes and increased vulnerability for affective disorders. Yet, little is known about the effects of pubertal maturation on neural systems of social threat processing. We examined adolescents' brain function to social stimuli in relation to pubertal maturation, depressive symptoms, and real-world subjective negative affect. Compared with pre/early adolescents, mid/late adolescents exhibited less amygdala reactivity to emotionally neutral faces relative to non-face stimuli; less ventrolateral prefrontal cortex (VLPFC) reactivity to fearful faces relative to non-face stimuli, neutral faces, or angry faces; and more VLPFC reactivity to angry relative to neutral faces. Amygdala and VLPFC reactivity were correlated with negative affect and depressive symptoms. Threat-processing changes during puberty may facilitate changes in social behavior and negative affect.     

Automatic brain response to facial emotion as a function of implicitly and explicitly measured extraversion

Extraversion/introversion is a basic dimension of personality that describes individual differences in social behavior and sensory sensitivity. Previous neuroimaging research exclusively relied on self reports for assessing personality traits. In recent years, implicit measures of personality have been developed that aim at assessing the implicit self-concept of personality and complement self report instruments which are thought to measure aspects of the explicit self-concept of personality. In the present study functional magnetic resonance imaging was used to examine automatic brain reactivity to facial expression as a function of both implicitly and explicitly measured extraversion in 30 healthy women. Sad, happy, and neutral faces were presented for 33 ms masked by neutral faces beside a no face control condition. Subjects evaluated the briefly shown neutral mask faces. The Implicit Association Test (IAT) and the NEO Five-Factor Inventory (NEO-FFI) were applied as measures of extraversion which were not correlated in our sample. IAT extraversion was negatively correlated with automatic reactivity of the caudate head, thalamus, and inferior frontal cortex to sad faces. NEO-FFI extraversion was negatively correlated with response of the inferior frontal cortex and putamen to sad faces. For masked happy faces, an inverse correlation of the IAT effect for extraversion with activation of the caudate head and superior parietal lobule was observed. NEO-FFI extraversion was inversely correlated with the response of the thalamus to happy faces. Neither NEO-FFI extraversion nor IAT effect were significantly related to brain response to masked neutral faces (compared to the no face condition). Taken together, a specific heightened responsivity of the fronto-striatal-thalamic circuit to facial emotions which are arousing stimuli might underlie introverts' preference for avoiding social interactions. Research on the neurobiology of extraversion could benefit from the application of implicit in addition to explicit measurement instruments when automatic neural responses are investigated.     

Neural evidence for the threat detection advantage: differential attention allocation to angry and happy faces

Threat stimuli are considered to be processed with higher priority due to an automatic threat detection system that enables rapid shifts of attention. However, direct evidence is still missing. The present study used the face-in-the-crowd task and event-related potentials to find evidence for the functionality of attention shifts in threat detection. The threat detection advantage was replicated in the behavioral results. An N2pc was observed that was more pronounced and earlier for angry compared to happy faces, suggesting differential attention allocation underlying the threat detection advantage. A larger sustained posterior contralateral negativity indicated that angry faces also gained more enhanced subsequent processing. An early posterior negativity observed 160 ms after stimulus onset revealed early emotion-specific processing that may have caused differences in attention allocation toward threatening stimuli.     

Emotion in motion: Facial dynamics affect infants' neural processing of emotions

Research investigating the early development of emotional processing has focused mainly on infants' perception of static facial emotional expressions, likely restricting the amount and type of information available to infants. In particular, the question of whether dynamic information in emotional facial expressions modulates infants' neural responses has been rarely investigated. The present study aimed to fill this gap by recording 7-month-olds' event-related potentials to static (Study 1) and dynamic (Study 2) happy, angry, and neutral faces. In Study 1, happy faces evoked a faster right-lateralized negative central (Nc) component compared to angry faces. In Study 2, both happy and angry faces elicited a larger right-lateralized Nc compared to neutral faces. Irrespective of stimulus dynamicity, a larger P400 to angry faces was associated with higher scores on the Negative Affect temperamental dimension. Overall, results suggest that 7-month-olds are sensitive to facial dynamics, which might play a role in shaping the neural processing of facial emotional expressions. Results also suggest that the amount of attentional resources infants allocate to angry expressions is associated to their temperamental traits. These findings represent a promising avenue for future studies exploring the neurobiological processes involved in perceiving emotional expressions using dynamic stimuli.     

Nonconscious associative learning: Pavlovian conditioning of skin conductance responses to masked fear-relevant facial stimuli

We examined the possibility of nonconscious associative learning in a context of skin conductance conditioning, using emotional facial expressions as stimuli. In the first experiment, subjects were conditioned to a backwardly masked angry face that was followed by electric shock, with a masked happy face as the nonreinforced stimulus. In spite of the effectively masked conditioned stimuli, differential conditioned skin conductance responses were observed in a subsequent nonmasked extinction phase. This effect could not be attributed to differential sensitization or pseudo-conditioning. In the second experiment, the differential responding during extinction was replicated with angry but not with happy faces as conditioned stimuli. It was concluded that with fear-relevant facial expressions as the conditioned stimulus, associative learning was possible even in conditions where the subjects remained unaware of the conditioned stimulus and its relationship to the unconditioned stimulus.     

Social anxiety predicts unconsciously provoked emotional responses to facial expression

Previous psychometric studies using a visual search task suggested that interpersonal fear in individuals with social anxiety disorder (SAD) may be processed by unconscious preattentive mechanisms. However, little is known about relationships between social anxiety and preattentive emotional responses. We explored whether social anxiety is associated with preattentive emotional responses to facial expression. Groups with high and low social anxiety were selected from 125 healthy volunteers according to scores on the Social Phobia Inventory. Fearful and happy faces were presented subliminally using backward masking, with skin conductance responses (SCRs) being measured as an autonomic index of emotional responses. SCRs to these two facial expressions were compared between groups. The group with high social anxiety showed significantly greater differences in SCRs between masked fearful and happy faces than the group with low social anxiety. Social anxiety was associated with unconscious autonomic responses to fearful faces. A preattentive interpersonal threat evaluation system may be an important factor in SAD.     

孤独症幼儿对面部情绪表情认知特征的初步研究

目的探究孤独症患儿对面部情绪表情的认知特征。方法选取2007年3月至2008年9月在中山大学附属第三医院发育行为中心诊断为孤独症的18～36个月患儿作为孤独症组,同期行健康查体的年龄、性别与孤独症组匹配的正常儿童作为对照组,被动观看电脑屏幕显示的高兴、悲伤、惊讶、愤怒和恐惧5种面部基本情绪表情图,观察比较两组幼儿对各种面部表情的视觉注意行为和自身情绪反应。结果研究期间孤独症组和对照组均纳入45例,两组幼儿对各种面部表情的初次注视时间组间效应不明显,而表情效应明显,两组幼儿初次注视高兴和愤怒表情的时间长于注视恐惧表情的时间。但孤独症组对各种面部表情图的回看次数明显少于对照组,总注视时间也明显短于对照组。对照组对不同的面部表情自身情绪反应评分明显不同,对高兴表情的积极情绪评分明显高于其他表情,对高兴表情的消极情绪评分明显低于愤怒和恐惧表情,对悲伤和惊讶表情的消极情绪评分也明显低于恐惧表情。而孤独症组对各种情绪表情的自身情绪反应评分差异无统计学意义。结论孤独症患儿早期不仅对面部情绪表情的视觉注意减少,对面部情绪表情的感知也存在缺陷,尤其对各种负性情绪表情理解困难。     

Differential modulations of reward expectation on implicit facial emotion processing: ERP evidence

Implicit emotional processing refers to the preferential processing of emotional content even if it is task irrelevant. Given that motivation enhances executive control by biasing attentional resources toward target stimuli, here we investigated the effects of reward expectation on implicit facial emotional processing in two experiments using ERPs. A precue signaling additional monetary reward for fast and accurate response for the upcoming trial (incentive condition; relative to a cue indicating no such additional reward, i.e., nonincentive condition) was followed by the presentation of a happy, angry, or neutral face. Participants had to determine the gender of the face in Experiment 1 and decide whether a number superimposed on the face was even or odd in Experiment 2. In both experiments, incentive cues elicited larger P3 and contingent negative variation responses, and the targets following incentive cues elicited more positive‐going ERPs (200–700 ms), compared with the nonincentive condition. Importantly, the N2 responses (200–280 ms) to the target exhibited differential patterns of Reward × Emotion interaction: relative to the nonincentive condition, the N2 amplitude differences between emotional (i.e., happy and/or angry) and neutral faces increased in the incentive condition in Experiment 1, but diminished in Experiment 2. These results indicate that reward expectation can differentially modulate implicit processing of facial expressions, with increased sensitivity to emotions when the processing of whole faces is required, but with reduced sensitivity when the processing of faces is distractive. This study enriches the evidence for interactions between reward‐related executive control and implicit emotional processing.     

In the face of fear: anxiety sensitizes defensive responses to fearful faces

Fearful faces readily activate the amygdala. Yet, whether fearful faces evoke fear is unclear. Startle studies show no potentiation of startle by fearful faces, suggesting that such stimuli do not activate defense mechanisms. However, the response to biologically relevant stimuli may be sensitized by anxiety. The present study tested the hypothesis that startle would not be potentiated by fearful faces in a safe context, but that startle would be larger during fearful faces compared to neutral faces in a threat-of-shock context. Subjects viewed fearful and neutral faces in alternating periods of safety and threat of shock. Acoustic startle stimuli were presented in the presence and absence of the faces. Startle was transiently potentiated by fearful faces compared to neutral faces in the threat periods. This suggests that although fearful faces do not prompt behavioral mobilization in an innocuous context, they can do so in an anxiogenic one.     

The time line of threat processing and vagal withdrawal in response to a self‐threatening stressor in cognitive avoidant copers: Evidence for vigilance‐avoidance theory

Using a spatial cueing paradigm with emotional and neutral facial expressions as cues, we examined early and late patterns of information processing in cognitive avoidant coping (CAV). Participants were required to detect a target that appeared either in the same location as the cue (valid) or in a different location (invalid). Cue–target onset asynchrony (CTOA) was manipulated to be short (250 ms) or long (750 ms). CAV was associated with early facilitation and faster disengagement from angry faces. No effects were found for happy or neutral faces. After completing the spatial cueing task, participants prepared and delivered a public speech and heart rate variability (HRV) was recorded. Disengagement from angry faces was related to a decrease in HRV in response to this task. Together, these data suggest that CAV is related to early engagement followed by disengagement from threat‐related cues that might impact physiological stress responses.     

Test‐retest reliability of amygdala response to emotional faces

In the current study, we evaluated the test‐retest reliability of amygdala response using an emotional face‐matching task that has been widely used to examine pathophysiology and treatment mechanisms in psychiatric populations. Activation within the fusiform face area (FFA) was also examined. Twenty‐seven healthy volunteers completed a variation of the face‐matching paradigm developed by Hariri et al. (2000) at two time points approximately 90 days apart. Estimates of test‐retest reliability of amygdala response to fearful faces were moderate, whereas angry and happy faces showed poor reliability. Test‐retest reliability of the FFA was moderate to strong, regardless of facial affect. Collectively, these findings indicate that the reliability of the BOLD MR signal in the amygdala varies substantially by facial affect. Efforts to improve measurement precision, enlarge sample sizes, or increase the number of assessment occasions seem warranted.     

Selective attention to threatening faces in delusion‐prone individuals

Introduction. Selective attention to threat‐related information has been associated with clinical delusions in schizophrenia and nonclinical delusional ideation in healthy individuals. However, it is unclear whether biased attention for threat reflects early engagement effects on selective attention, or later difficulties in disengaging attention from perceived threat. The present study examined which of these processes operate in nonclinical delusion‐prone individuals.

Methods. A total of 100 psychologically healthy participants completed the Peters et al. () Delusions Inventory (PDI). Twenty‐two scoring in the upper quartile (high‐PDI group) and 22 scoring in the lower quartile (low‐PDI group) completed a modified dot‐probe task. Participants detected dot‐probes appearing 200, 500, or 1250 ms after an angry‐neutral face pair or a happy‐neutral face pair.

Results. High‐PDI individuals responded faster to dot‐probes presented in the same location as angry compared to happy faces at the short 200 ms stimulus onset asynchrony (SOA), but only when the emotional faces were presented to the left visual field. At the two longer SOAs (500 ms, 1250 ms), the high‐PDI group were also faster to respond to dot‐probes presented in the same location as angry compared to happy faces and slower to respond to dot‐probes presented in different spatial locations to angry (vs. happy) faces. The latter effects were seen whether emotional faces were presented to the left or the right visual field.

Conclusions. Results support the operation of emotion‐selective engagement and defective disengagement for threat‐related facial expressions (i.e., anger) in delusion‐prone individuals.     

Current status of the anger superiority hypothesis: A meta‐analytic review of N2pc studies

Numerous investigators have tested contentions that angry faces capture early attention more completely than happy faces do in the context of other faces. However, syntheses of studies on early event‐related potentials related to the anger superiority hypothesis have yet to be conducted, particularly in relation to the N200 posterior‐contralateral (N2pc) component which provides a reliable electrophysiological index related to orienting of attention suitable for testing this hypothesis. Fifteen samples (N = 534) from 13 studies featuring the assessment of N2pc amplitudes during exposure to angry‐neutral and/or happy‐neutral facial expression arrays were included for meta‐analysis. Moderating effects of study design features and sample characteristics on effect size variability were also assessed. N2pc amplitudes elicited by affectively valenced expressions (angry and happy) were significantly more pronounced than those elicited by neutral expressions. However, the mean effect size difference between angry and happy expressions was ns. N2pc effect sizes were moderated by sample age, number of trials, and nature of facial images used (schematic vs. real) with larger effect sizes observed when samples were comparatively younger, more task trials were presented and schematic face arrays were used. N2pc results did not support anger superiority hypothesis. Instead, attentional resources allocated to angry versus happy facial expressions were similar in early stages of processing. As such, possible adaptive advantages of biases in orienting toward both anger and happy expressions warrant consideration in revisions of related theory.     

Gender differences in facial reactions to facial expressions

This study explored whether males and females differ in facial muscle reactivity when exposed to facial expressions. The study also examined whether the sex of the stimulus faces differentially influences the response patterns to facial stimuli. Thus, the sex was manipulated in a 2 x 2 factorial design by exposing males and females to slides of angry and happy faces displayed by both sexes. Facial electromyographic (EMG) activity was measured from the corrugator and zygomatic muscle regions. The subjects were also required to rate the stimuli on different dimensions. The results showed that angry faces evoked increased corrugator activity whereas happy faces evoked increased zygomatic activity. As predicted, these effects were more pronounced for females, particularly for the response to happy faces. Interestingly, there were no facial EMG effects for gender of stimulus. It was further found that males and females perceived the stimuli similarly. The results are consistent with previous findings indicating that females are more facially reactive than are males.