1. Introduction
Empathy is the phenomenon of being aware of and understanding how another person feels, without conflating one’s feelings with those of the other [
1]. Cognitive, emotional, motivational, and behavioral processes interact and play a role in the multifaceted construct known as empathy. Many studies have been conducted on the cognitive and affective components of empathy [
2]. The “cognitive component” of empathy is evaluating another person’s emotions, which relates to theory of the mind [
3,
4]. Perspective-taking and reading facial expressions are both cognitive evaluative aspects of empathy [
5]. The term “emotional empathy” is used to describe the vicarious sharing of emotion; the emotional components engage a partial affective sharing of others’ affective states [
6]. For instance, individuals vicariously experience the unpleasantness associated with the pain someone else is feeling. These two types of empathy should be considered simultaneously.
As facial emotional expressions are essential for human interaction, various studies have investigated their role in the comprehension of emotions [
7]. The facial feedback theory of emotional efference was introduced in 1884; William James hypothesized that the expressive muscles contraction or relaxation may have a causal role in our experience of emotions [
8,
9]. According to this idea, emotional experience and facial feedback are related, and the facial efference modifies physiological and psychological responses to facial expressions [
10]. In a previous study that compared valence ratings for pictures and text during smiling (contraction of the zygomaticus major muscles) and frowning (contraction of the corrugator supercilii muscles), participants had a more positive opinion of the text when smiling compared to when frowning [
11]. Botulinum toxin treatment of the muscles in the upper face prevents facial expressions such as frowning, and reduces perceptions of negative emotions [
7].
Facial feedback may also modify autonomic reactions to emotional stimuli. Facial feedback of arousing emotions such as fear, anger, and happiness, affects autonomic responses by increasing the sympathetic activation associated with emotion, as well as the intensity of the induced emotions. For example, the expression of facial efference generally increases the skin conductance response (SCR), an indicator of sympathetic arousal, while the deliberate blocking of facial expressions reduces the SCR [
12,
13]. A previous study evaluated the SCR, pupil size, and facial electromyogram (EMG) of the corrugator supercilii muscle as participants were imitating or passively observing angry facial expressions on a screen [
14]. Actively imitating another’s facial expression of anger produced considerably greater responses for all three measures (SCR, pupil size, and EMG) than passive observation, suggesting that facial feedback enhances autonomic responses during an emotional experience. Empathic pain can be produced by considering another’s painful experience. However, as of yet no study has investigated whether facial feedback enhances the ability to empathetically evaluate and share another’s pain. Therefore, in this study, we tested whether actively frowning and, thus, contracting the corrugator supercilii muscles influences empathy for another person’s pain.
The aim of this study was to investigate if enhancing negative feeling by stimulating a face muscle (corrugator supercilii) increases the intensity of cognitive and emotional components of empathic pain, based on the facial feedback hypothesis. We hypothesized that the enhancement of negative affect by activating the corrugator supercilii would increase the intensity of cognitive and emotional components of empathic pain. We also investigated whether or not muscle contraction changes pupil size, which would indicate a higher level of autonomic arousal.
2. Methods
2.1. Participants
In total, 48 participants (26 females and 22 males) were recruited to this study. All participants were neurologically and physically healthy and had no major diseases. The participants were recruited through print and online advertisements. None of the participants wore glasses during the experiment. They all had normal or corrected vision. All subjects provided informed consent before the study, which was conducted according to the guidelines of the Human Subjects Committee and approved by the Institutional Review Board of Kyung Hee University, Seoul, Republic of Korea (approval number: KHSIRB-21-243).
2.2. Experimental Design and Procedures
In total, 20 images from the Delaware Pain Database [
15] were used: 10 experimental images of a male (
n = 5) or a female (
n = 5) with painful facial expressions, and 10 control images of the same models with neutral facial expressions. With a focus on painful and neutral expressions, the Delaware Pain Database is a fully defined, varied collection of images that is accessible to the public and contains 240 distinct subjects’ specific painful expressions. All stimuli and associated norming data can be found online “
https://osf.io/2x8r5 (accessed on 10 July 2021)”. Inadequacies in the size, homogeneity, characterization, and stimulus variability of facial expressions of pain were reduced by the database. To reduce racial ingroup bias or the other race effect, we solely used images of Asian people from the database in this study [
16,
17].
The facial images were centered on the screen, with the ears and neck removed. The experimental stimuli were displayed on a 51 cm monitor located approximately 80 cm from the participant’s eyes (maximum size of 23 × 29 cm). The participants were told to relax while seated in front of the monitor, and to keep their bodies still. Electromyographic electrodes were placed on the medial end of the corrugator supercilii and mastoid bone, and we calibrated the eye-tracking system to track pupil size and gaze.
To compare autonomic responses between facial expression stimuli, we recorded autonomic responses while the participants viewed neutral and painful facial expressions on the screen. A fixation cross was shown for 1 s in the middle of the screen at the start of each trial. Then, two non-facial cues were displayed for 3 s, in a random order. The participants were instructed to contract their corrugator muscles in response to cues with two yellow arrows (contraction cue), but not to cues with two yellow dots (relaxation cue). This process was falsely described to the participants as “a way to calibrate the movement of the eyebrows”. Facial expression images were displayed for 2 s after a 1s rest period.
The participants rated their unpleasant feelings and pain at the end of the trial (cognitive evaluative aspect of empathic pain, on a 6-point Likert scale: “Please rate the intensity of the pain of the person in the image” [0 = no pain at all, 5 = greatest possible pain]; affect sharing aspect of empathic pain: “Please rate the intensity of your unpleasant feelings while watching the person in the image” [0 = no unpleasant feelings at all, 5 = strongest possible unpleasant feelings]). The 40 trials all lasted more than 8 s (including the rating period, which was displayed without time limit) (
Figure 1).
2.3. Facial Electromyogram and Pupil Size Measurements
EMG signals were recorded from the corrugator supercilii muscle using a ground electrode placed below the mastoid bone, and electrodes on the medial end of the muscle, according to standard facial EMG guidelines [
18]. The PowerLab 8/30 instrument (ML870; AD Instruments, Bella Vista, Australia) was used. The EMG data were bandpass-filtered (1 kHz–0.3 Hz; 10 mV). Phasic facial EMG activity was defined as a change from the baseline activity, which was calculated for 1 s before the stimulus onset. The EMG data from each trial were retrieved every 0.2 s over a total of 4 s (1-s fixation cue and 3 s of non-facial cues).
The pupil size was measured during the test using a computerized eye-tracking system (iView XTM RED; SensoMotoric Instruments, Teltow, Germany). The pupil size of each participant was calculated when the gaze fixated on each neutral or painful face for 2 s during the contraction or relaxation condition. The pupil size of each participant was measured by averaging the pupil size during neutral or painful face (2 s) between the contraction and relaxation condition. The BeGaze (SensoMotoric Instruments) eye-tracking program was used to analyze the data.
2.4. Data Analysis
Values are expressed as mean ± standard error. The EMG and pupil size responses were averaged within the same trials and stimuli. For the subjective ratings and pupil size, we conducted a 2 × 2 analysis of variance (ANOVA) of the pain and unpleasantness ratings with two within-subjects factors: facial expression (neutral or painful face) and facial feedback (contraction or relaxation). Statistical analyses were performed using the R statistical software package (ver.3.6.0;
http://r-project.org) and Jamovi software (ver. 0.9;
http://www.jamovi.org). A
p-value < 0.05 was considered significant.
4. Discussion
We investigated the role of facial feedback in the cognitive and affective components of empathic pain. Based on the facial feedback theory, we assessed how people perceive others’ facial expressions. As expected, the participants experienced more unpleasant feelings and perceived another’s painful face as more painful when the corrugator supercilii muscle was contracted than when their face was in a neutral state. Pupil size was significantly greater under the contraction than relaxation condition in response to the painful and neutral faces.
In the current study, facial feedback had a significant effect on empathy for another person with a painful face. These results are similar to a previous study in which imitation of another person’s facial expressions induced a similar emotion in the observer, leading to emotional contagion and empathic reactions [
19]. The effect of facial feedback on empathy for others in pain was reported in a study that explored whether individual differences in empathy modulated the sensitivity of facial feedback. Participants in the high emotional empathy group were more likely to rate a film as funny when they were asked to produce a happy expression compared to the low emotional empathy group [
20]. We suggest that the facial feedback hypothesis can help explain empathy for others in pain through cognitive and affective mechanisms.
Among the various facial muscles involved in facial expressions, we analyzed the activity of the corrugator supercilii muscle. In studies based on the Facial Action Coding System, “narrowed eyes with furrowed brows and wrinkled nose” were identified as major characteristics of painful faces [
21,
22]. In a previous study, the activity of the corrugator supercilii muscle was positively correlated with the empathic concern score, which is a measure of the empathic response. The correlation between the level of empathic concern and EMG activity of the corrugator supercilii muscle suggests that the latter reflects the empathic response induced by emotional mimicry [
23]. Thus, we expected enhanced corrugator supercilii contraction to promote empathy for another’s painful experiences and emotional responses (effect of facial feedback on empathic pain).
We also recorded pupil size while testing the effects of facial feedback on empathic pain. Pupil size is regulated exclusively by the autonomic nervous system and reflects the level of arousal [
24]. The pupil size is significantly greater in response to emotional than neutral stimuli, regardless of valence [
25]. In this study, regardless of the facial expressions of others, pupil size increased when viewing faces after corrugator supercilii contraction compared to the neutral condition, indicating that the muscle contraction itself may have significantly increased sympathetic activity and arousal. Further investigations should evaluate how increased sympathetic activity and arousal influence cognitive and affective components of empathic pain.
Empathic pain is particularly important in the clinical setting given that most patients visit the hospital to alleviate pain, and that empathy can be beneficial during the treatment process. A meta-analysis revealed a modest benefit of empathy and the provision of positive messages to patients in terms of pain management [
26]. Another study reported a positive correlation between patient-rated physician empathy levels and patient satisfaction with pain consultations, which underscores the importance of empathy in the clinical setting [
27]. Future research is necessary to determine how active or passive mimicry of a patient’s facial expressions by clinicians affects doctor-patient interactions, as well as the clinical outcomes of pain and other medical conditions.
To our knowledge, this is the first study to investigate the effect of facial feedback (frowning) on perceptions of painful and neutral faces of others. It has been suggested that pupil dilation is a broad measure of a person’s level of arousal and alertness. In this study, the observed rise in sympathetic activity, reflected in changes in pupil size, could be potentially associated with the heightened experience of empathic pain triggered by facial feedback. Our results may provide preliminary ideas of the underlying behavioral and autonomic mechanisms of facial feedback and empathic pain.
This study had some limitations. First, simply viewing the painful and neutral faces may not have evoked significant empathic pain in some participants. Future studies should present stimuli depicting pain in others in greater detail, such as videos and both facial and bodily expressions of pain. Second, the direct effect of facial feedback on empathic pain merits further investigation given that empathy can be affected by many factors, and that muscle contraction itself may alter emotional and arousal states.