Abstract
Playing video games is associated with cognitive changes and possibly psychosocial difficulties. Problematic gaming occurs upon the loss of control over videogame playing; gaming disorder is considered a behavioral addiction in the 11th version of the International Classification of Diseases. Models used to understand behavioral addictions include cognition as an essential factor in the development, maintenance, and relapse of addiction. Nevertheless, some aspects of cognition, such as social cognition, remain underexplored, despite evidence of alterations in cognitive and social function among patients with problematic gaming. This review aimed to describe the current understanding of social cognition in individuals exposed to videogames. We included all studies assessing social cognition in participants of any age with a wide range of exposure to video games (from simple use of video games (such as at least two exposures) to problematic gaming, defined according to the included study). This wide range of exposure allowed us to explore the whole process from repeated exposure to addiction. We included only studies that used neuropsychological tasks to assess social cognition. Patient-reported outcomes that could be biased by subjective self-report data were not included. The search was conducted from inception to January 2022 in three databases (PubMed, PsycINFO, and Web of Science). The systematic search identified 39 studies that assessed facial emotion processing, empathy, theory of mind, social decision-making, aggressive behavior, and moral competence. In general, results have been mixed, and a number of questions remain unanswered. Nevertheless, several studies showed cerebral changes when processing facial emotion that were linked with problematic gaming, while no link was obtained between nonproblematic gaming and empathy alterations. The influences of cooperation patterns, theory of mind, moral competence, and gaming frequency were highlighted. Finally, there was substantial heterogeneity in the population assessed and the methods used.
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Introduction
Video Gaming
Video gaming is a modern leisure activity that refers to the use of video games (VGs), such as massively multiplayer online role-playing games (MMORPGs), multiplayer online battle arenas (MOBAs), first-person shooters (FPSs), or even sandbox games (games without planned scenarios) (Leouzon et al., 2019). Gamers can play for entertainment but also to deal with anxiety, depression, or other psychological difficulties. Nevertheless, the causality of the relationship between motives/psychological difficulties and gaming is poorly understood (Sunil et al., 2021). Playing VGs has been found to increase the activity of the sympathetic nervous system (Krarup & Krarup, 2020). Gaming also leads to brain changes (Brilliant et al. 2019) and enhances aspects of cognition, such as top-down attention processes and spatial cognition (Bediou et al., 2018). Regarding social function, time spent playing VGs is negatively associated with the quality of social relationships (Lo et al., 2005). In contrast, psychological well-being and social functioning were positively linked with VG use in a population of heavy gamers (van den Eijnden et al., 2018). Gamers also have high online social capital (i.e., networking and its resulting benefits (Williams, 2006; Collins & Freeman, 2013).
Problematic Gaming and Gaming Disorder
The 11th version of the International Classification of Diseases (ICD-11) (World Health Organization, 2018) defines gaming disorder (GD) as “impaired control over gaming, increased priority given to gaming over other activities to the extent that gaming takes precedence over other interests and daily activities, and continuation or escalation of gaming despite the occurrence of negative consequences.” Another clinical definition was provided for Internet gaming disorder (IGD) in the Diagnostic and Statistical Manual of Mental Disorders, 5th edition (DSM-5), within the section outlining disorders requiring further investigation (American Psychiatry Association, 2013). Both IGD (in the DSM-5) and GD (in the ICD-11) refer to similar disorders characterized by a loss of control over video gaming leading to negative consequences but have slight differences in operationalization for diagnosis.
In the present review, we use the umbrella term “problematic gaming” (PG) to encompass the variety of clinical definitions used in the studies reviewed. PG includes the clinical definitions provided in the international classifications (IGD in the DSM-5 and GD in the ICD-11) as well as other definitions used before the development of the ICD-11 or DSM-5 or within other conceptual frameworks used to characterize excessive and harmful use of VGs (Schettler et al., 2022). In the present review, the term PG is contrasted with nonproblematic gaming (NPG) which is defined as leisure activity without a loss of control or harmful consequences.
The prevalence of PG is estimated to be between 0.7 and 27.5% in the general or gamer population, depending on the clinical definition used, with more men affected (Mihara & Higuchi, 2017).
Models of the underlying processes of addictions are multifactorial, and these processes include cognitive functioning, among other factors (Brand et al., 2016, 2019; Noel et al., 2013). Indeed, alterations in inhibitory control (Argyriou et al., 2017) and in frontostriatal and frontocingulate networks (Yao et al., 2017) have been highlighted in people with PG. Moreover, improvements in PG symptoms have been linked to improvements in cognitive functioning (Lim et al., 2016). In contrast, NPG has been linked with improvements in cerebral structures and connectivity and optimization of neuronal recruitment, especially for attention and visuospatial skills (Palaus et al., 2017).
Regarding social functioning, PG was found to negatively impact social relationships (Ryu et al., 2018). More specifically, individuals with PG have high online social capital, as do gamers without PG, but low offline social capital (Collins & Freeman, 2013). Additionally, psychological well-being and social functioning were negatively linked with the presence of PG (van den Eijnden et al., 2018) and were even a predictor of it (Lemmens et al., 2011). The presence of PG has also been linked to familial (Hyun et al., 2015), emotional, and behavioral problems (Frölich et al., 2016). Taken together, these findings suggest an alteration in social functioning in people with PG.
Definition of Social Cognition
The literature suggests the presence of altered social functioning among individuals with PG. Nevertheless, gamers’ social functioning is less understood for those without PG. On the borderline between cognition and social functioning, there is social cognition (SC). This concept includes all cognitive processes underlying social interactions, from the ability to detect and identify social cues, to interpret social cues, to the generation of socially appropriate responses (Adolphs, 2001; Frith, 2008; Saxe, 2006). SC also allows people to construct social norms that will serve as standards for future social interactions (Beer & Ochsner, 2006; Bertoux, 2016; Greifeneder et al., 2017). Indeed, given these social abilities, the “social brain” theory postulates that the human brain is larger than that of other species because of the complexity of our social world and, specifically, our ability to bond with others (Adolphs, 2009). The crucial role of SC in daily functioning has been demonstrated in several psychiatric clinical populations, such as patients who suffer from schizophrenia (Brunet et al., 2003; Couture et al., 2006).
Components of Social Cognition
SC covers a wide spectrum of cognitive functions. SC tasks can range from the simplest tasks (e.g., recognizing an emotion on a face) to the most complex (e.g., understanding irony or social decision-making). Several models have been constructed to determine the number of SC components (Fiske & Taylor, 2016; Green et al., 2015; Happé & Conway, 2016). For example, it is debated whether the self should be included in this concept (Happé & Conway, 2016). Similarly, the inclusion of alexithymia (which reflects the inability to identify and describe emotions experienced by oneself or others (Etchepare & Prouteau 2017; Taylor et al., 1985) within the spectrum of SC is controversial. Several authors have also proposed differentiating SC components based on more general characteristics. For example, the level of processing (e.g., high, low or dual processing (Adolphs, 2009, 2010; Etchepare & Prouteau, 2017; Frith & Frith, 2008) or the nature of the stimuli involved (affective versus cognitive stimuli) may be used (Adolphs, 2010; Etchepare & Prouteau, 2017; McDonald, 2013; Shamay-Tsoory & Aharon-Peretz, 2007).
In the following paragraphs, only SC components identified in the literature and described with systematic research are presented for the sake of clarity.
Social Information/Emotion Processing, Emotion Attribution, and Affective Cognition
The study of social or emotional processing can occur at two levels. The conscious level is assessed by asking the subject to identify an emotion or rate its intensity, for example. The unconscious level can be measured when the participant attends to another task while faces are presented. Facial emotion processing seems to be supported by two networks. The ventral network deals with static stimuli and associated stimuli with information such as the identity of the face. The dorsal network deals with dynamic stimuli (Duchaine & Yovel, 2015). The ability to process emotions and make assumptions about them is also called affective cognition (Ong et al., 2015).
Empathy
Empathy is the ability to feel what another person is feeling and understand him or her (Lockwood, 2016). Several models of empathy have been proposed. For example, one model postulates that empathy has two components. The first component involves the ability to understand motives and thoughts from another person (i.e., cognitive empathy). The second component involves the ability to experience the feelings of another person (i.e., emotional empathy) (S. Shamay-Tsoory et al., 2009). Another model separates empathy into two different components. The first component, personal distress, is self-oriented and reflects the tendency to try to alleviate one’s pain. The second component, compassion (or empathic concern), involves the ability to feel sympathy for others (Singer & Klimecki, 2014). The function of empathy, also called vicarious experience, seems to be supported by the anterior cingulate cortex and the anterior insula (Lockwood, 2016; Singer & Klimecki, 2014).
Theory of Mind, Attribution Style/Bias, and Intention Attribution
Another component that is sometimes considered similar to affective empathy (Decety & Lamm, 2006; Lockwood, 2016) is theory of mind (ToM). ToM is also called mentalizing, mind reading, or cognitive perspective (Singer & Klimecki, 2014). It reflects the ability to infer mental states (cognitive ToM) or emotional states (affective ToM) of another person (Shamay-Tsoory & Aharon-Peretz, 2007). It allows individuals to understand and predict the behavior of others (Premack & Woodruff, 1978). ToM seems to be supported by a network including at least the medial prefrontal cortex (mPFC) and bilateral temporoparietal junctions (Happé & Conway, 2016; Schurz et al., 2014). Attribution style is defined as “how people deduce causal relationships and characteristics of other persons in the environment” (Fiske & Taylor, 2016). Attribution style is linked to the concept of ToM and allows the observation of hostile attribution bias, as found in individuals with schizophrenia (Buck et al., 2020).
Social Decision-Making
On another level of reasoning, social decision-making is the ability to make a decision that will affect oneself and another person, with the outcome depending on the behavior of oneself and another person. This function seems to be supported by the prefrontal cortex but also by the amygdala and insula, which handle affective biases that impact decision-making (Rilling & Sanfey, 2011).
Aggressive Behavior
Aggressive behavior involves the administration of an unpleasant stimulus to another person (Taylor, 1967). Cognitive activity associated with this behavior seems to be linked with the dorsal part of the mPFC. The affective component (i.e., compassion during punishment) seems to be supported by the ventral part of the mPFC (Lotze et al., 2007).
Moral Decision-Making
Another component of SC is moral decision-making. This ability has 3 aspects: a particular predilection toward a moral orientation (affective component), the ability to make decisions regarding moral dilemmas based on those moral aspects (cognitive component, also called moral competence), and the fact that decision-making is not dependent on the issues in the particular situation (Jung et al., 2016; Lind, 2008). This ability is underpinned by emotional and cognitive processes that come into play in decision-making. For example, a higher level of moral competence has been linked to stronger functional connectivity between the amygdala and the ventral mPFC and weaker connectivity between the amygdala and frontoparietal control network (Jung et al., 2016).
Social Knowledge
Social knowledge refers to all the information stored in memory that can be used to infer mental states. This information can be general, such as norms about how to behave in certain situations or places. Information may also be specific to the person with whom the interaction takes place such as history with that person (Achim et al., 2013; Langdon et al., 2014).
Social Cognition and Gaming
The aim of this review is to describe the current understanding of the relationship between SC and gaming. Indeed, it seems that NPG, and, to a greater extent, PG, can impact both cognitive and social functioning (e.g., building relationships); thus, they may also impact SC (e.g., identification of facial emotions). Furthermore poor cognitive functioning, specifically poor SC, may lead to increased time spent gaming and even PG. As SC involves both cognition and social functioning, it is logical to explore the literature on SC in gamers to elucidate the sociocognitive profiles of gamers with or without PG. This review will also allow us to identify the SC competencies involved.
Methods
Search Strategy
The search strategy was developed in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-analyses (PRISMA) recommendations (Moher et al., 2009). The search was conducted from database inception through January 2022. No registration was made, and no protocol was prepared. We initially planned to register the protocol of this literature review ahead of time with the PROSPERO registry. However, the registration was not accepted because the data explored were not considered related to a health condition (Moher et al., 2014). The search was performed in three databases (PubMed, PsycINFO, and Web of Science). Key words regarding SC and VGs were crossed (see Table 1), resulting in the following search: (“video game” OR “video games” OR “videogame” OR “videogames” OR “game” OR “games” OR “gaming” OR “gamer”) AND (“mentalization” OR “mentalizing” OR “mentalising” OR “mind reading” OR “social cogniti*” OR “social interaction” OR “social function*” OR “social brain” OR “social decision” OR “social perception” OR “affective cognition” OR “social knowledge” OR “social information processing” OR “emotion attribution” OR “attributional style” OR “theory of mind” OR “emotion processing” OR “attribution bias” OR “intention attribution” OR “empathy”). The SC-related keywords were determined based on the current literature on SC, regardless of the theoretical model, to scan a wide variety of SC components. The search focused on articles published in French or English.
Inclusion and Exclusion Criteria
This systematic review focused on both NPG and PG. As SC in VGs is a recent research area, we chose not to restrict our review to any specific pattern of gaming exposure (e.g., early exposure during childhood, training people with no VG experience, or controlled studies of people with and without VG experience) or any level of exposure (e.g., frequency of VG playing). However, we did not include studies that did not assess the frequency of VG exposure or did not expose participants to VGs more than once. Indeed, a single exposure to VGs is insufficient to induce changes in cognitive functioning, as the repetition of an action (harmful or therapeutic) is necessary. This strategy allowed us to explore the whole process from repeated exposure to addiction and to identify the areas in which the literature was the most developed and, conversely, the areas in which additional research is needed.
Moreover, only assessments of SC based on neuropsychological performance (i.e., performance-based tasks objectively linking behavior and the brain (Casaletto & Heaton, 2017) were included in this review. Studies using self-reported outcomes, which are subjective assessments made by the participant (Rothman et al., 2007), were not included. Indeed, self-reported data are subjective, and they do not allow an evaluation of the quality of cognition.
Articles were included if they (i) evaluated participants’ frequency of gaming OR the effect of playing VGs more than once OR patients with PG AND explored its impact and (ii) included a neuropsychological task to assess SC.
Study Selection
After the exclusion of duplicates, each title was screened by the first author and excluded if it was clearly not within the scope of the review (i.e., articles not considering VG as a leisure activity or not assessing cognition). This selection process resulted in a large sample of abstracts that were screened twice. The first reading by the first author excluded abstracts that were clearly off-topic. The second selection of abstracts was performed using Abstrackr software (Wallace et al., 2012) by the first and fifth authors. This software can be used to save time by screening titles and abstracts based on machine learning that classifies titles as relevant or not (Rathbone et al., 2015). We used it only as a collaborative tool that was accessible online.
Because of the lack of information in abstracts, a large number of articles were retained during this abstract screening step. The methods of these articles were screened by the first and fifth authors to ensure that we did not miss any study that could have included neuropsychological SC tasks. Therefore, we read the methods of all articles dealing with cognition in gaming, even without apparent SC assessments and/or apparent exclusive use of self-rated questionnaires. Finally, the full texts of studies were read, and studies were included in accordance with the inclusion criteria. To complete the database search, the first author performed a manual search and screening of the bibliographic references of the studies included and from a recently published meta-analysis regarding gaming and social outcomes (Greitemeyer & Mügge, 2014).
Data Extraction
Each full text that was considered eligible was read by the first author. Information about the study population, measures of VG use or PG, cognitive assessment of SC, and main results exploring the effect of VGS are presented in Table 3. Table 3 also provides information on the power of the studies reviewed, by categorizing studies according to their methodology (comparative or correlational studies). A summary is provided at the beginning of the “Results” section to describe demographic information, SC outcomes, and VG information. In the interpretation of the results, we were careful to differentiate the results from samples of gamers with and without PG. Indeed, this may provide information on the links of SC with NPG versus PG.
Results
Research included in the previously published meta-analysis (Greitemeyer & Mügge, 2014) led to the screening of 52 additional records. From these 52 studies, 34 were screened based on their abstract, 15 were then screened based on their full text, and 3 were finally included. All numbers and reasons for exclusion at each step are included in Table 2 and Fig. 1. Moreover, all references from articles included in the systematic review and previously published relevant meta-analyses (n = 23) were also screened, and four articles were included from these lists. In total, the systematic search resulted in the selection of 39 studies.
Results Summary
In these 39 studies, the average sample size was approximately 230 (min = 28, max = 3,034, median = 99, average sample size of comparative studies = 73, average sample size of correlational studies = 342).
The mean age of participants included in these studies was 20.13 years (min = 5.06, max = 32.04, 3 studies with missing data, mean age of comparative studies = 22.12, mean age of correlational studies = 18.78). Participants were mostly male (59.64%) (2 studies with missing data).
Within the 39 studies, 23 different SC outcome measures were used to assess 6 components of SC (facial emotion processing, empathy, ToM, social decision-making, aggressive behavior, and moral competence). Of the 39 studies, 27 found significant results regarding SC outcome measures (11 on facial emotion processing, 1 on empathy, 6 on ToM, 2 on social decision-making, 5 on aggressive behavior, and 2 on moral competency).
Regarding VG information, only 13 experiments of 43 provided information regarding the type of VG played by gamers (8 assessing facial emotion processing, 2 assessing empathy, 2 assessing ToM, and 1 assessing social decision-making). Moreover, a large number of experiments (32 of 43) focused on exposure to violent VGs. Among them, 19 found significant results (8/11 on facial emotion processing, 1/5 on empathy, 4/7 on ToM, 2/2 on social decision-making, and 4/7 on aggressive behavior). Additionally, 11 studies included frequent video gamers, 4 included addicted video gamers, and 27 included individuals from the general population (23 assessed the frequency of gaming, 3 exposed to VGs, and 1 assessed the severity of addiction). Among the 15 studies assessing at least regular gamers, 12/15 (80%) reported significant results in the domains of facial and social emotion processing (n = 7), social decision-making (n = 2), aggressive behavior (n = 2), and moral competence (n = 1). Among the studies conducted in the general population, 16/28 (57%) found significant results (5 assessing facial emotion processing, 1 assessing ToM, 6 assessing empathy, 3 assessing aggressive behavior, and 1 assessing moral competency). Finally, 19 studies included a control group. Among them, 13 (68%) found significant results, while 15/24 (63%) studies without a control group showed significant results.
Regarding the assessment of addicted gamers, three studies used the Internet Addiction Test (IAT (Young, 2016)), and one of them used the DSM-5 criteria to classify participants. All three reported significant results.
Detailed Results on Each SC Domain
To facilitate understanding, the articles are presented according to the various components of SC assessed and ranked from the most recent to the oldest in Table 3.
Facial/Social Emotion Processing
Thirteen articles explored the link between exposure to VGs and social emotion processing. Cerebral processing was assessed in some of these studies. For example, the articles compared the performance of two groups of players of violent VGs (frequent or infrequent players) on the stop signal task (SST) and recorded event-related potentials (ERPs). The unconscious processing of emotional facial stimuli was different for happy faces, with smaller amplitudes observed in frequent players (Stockdale et al., 2017). Regarding the detection of emotional stimuli, research has shown that after 10 h of training on VGs (action or nonaction), differences in reaction times are observed between the nonaction VG group and control group, and the type of VG played had influences the impact on cerebral processing (Bailey & West, 2013). Finally, seven studies assessed the ability to process and discriminate facial emotions in gamers without PG. Studies have shown that years of experience with VGs could improve emotion identification and that the number of hours played may negatively impact joy identification (Miguel et al., 2017). Exposure to VGs may also be linked with worse ability to identify negative emotions (Miedzobrodzka et al., 2021a). Moreover, VG players seemed better at recognizing fear but worse at recognizing disgust than controls (Diaz et al., 2015). Additionally, a study found that professional e-sport players and controls displayed similar abilities in identifying identical emotions; both were lower than the capacity of professional baseball players. In the same study, the authors showed that elite e-sport players displayed faster reaction times than the rest of the group (Kang et al., 2020). Finally, no difference appeared between VG players and non-VG players in the identification of morphing emotions (Pichon et al., 2021). Using the reading the mind in the eyes task (RMET), no link between violent VGs and RMET scores was found in participants after 8 weeks of VG practice (Kühn et al., 2019). With the same task, a positive link between the ability to infer correct mental states and better VG (MOBA) performance was observed (Bonny et al., 2020).
In comparisons of participants with PG and controls on tasks assessing unconscious processing of faces (Peng et al., 2017) and cartoons and faces (He et al., 2019), studies have shown differences in ERPs. For example, one study showed a reduction in the N170 component, which reflects the detection of a face (Schweinberger & Neumann, 2016), in the PG group when processing neutral faces compared to happy faces. There was no reduction in the control group. Another study showed a larger peak in response to cartoons faces than in response to human faces in only the right hemisphere in the PG group, while this difference was present in both hemispheres in the control group. These results suggest specific alterations in the processing of facial stimuli in PG (see Table 3 for details). Moreover, when comparing PG patients to controls or to patients with methamphetamine use disorder on a task of social perception, both patient groups displayed lower scores than the control group (Jiang et al., 2020). Finally, a higher number of symptoms of PG were linked with worse scores on the RMET (Aydın et al., 2020).
Empathy
Five studies assessed empathy in a population of gamers. No differences were found regarding empathy between frequent and nonfrequent gamers, using an empathy-for-pain task with emotional stimuli (photography or drawings) and functional magnetic resonance imaging (fMRI) (Gao et al., 2017; Szycik et al., 2017). No significant changes were observed, after an 8-week period of exposure to VGs (Kühn et al., 2018). However, comparisons of individuals with low exposure to violent VGs with individuals with a high level of exposure revealed a desensitization to painful stimuli (i.e., similar EEG results for painful and nonpainful stimuli) in only the high-exposure group (Miedzobrodzka et al., 2021b). Finally, no link between violent VG exposure and a scale measuring empathy for a rape victim was found (Ferguson & Colwell, 2020).
No study was identified that assessed empathy in PG.
Theory of Mind/Bias of Attribution
Nine studies explored ToM in relation to VG exposure. Among them, eight studies explored ToM by means of stories. Studies with young children showed no link between the rate of aggressive intent in ambiguous stories and exposure to VGs (Ferguson & Wang, 2019). Nevertheless, when using vignettes in which participants had to tell what was going on next but also how they would have reacted in stories that were designed to induce empathy, a significant link between higher exposure to violent VGs and lower scores was reported (Funk et al., 2003). Studies with adolescents showed a negative correlation between exposure to prosocial VGs and hostile attribution bias as well as a positive correlation between hostile attribution bias and exposure to violent VGs (Gentile et al., 2009). Moreover, one study did not find a relationship between exposure to VGs and attribution bias (Krahé & Möller, 2004). Finally, attribution bias was identified to mediate the relationship between exposure to VGs and behavior (Möller & Krahé, 2009; Zhen et al., 2011). Studies with adults showed a positive correlation between exposure to VGs and levels of aggressive thoughts, feelings, and behaviors attributed to characters in ambiguous stories (Eastin & Griffiths, 2009). However, no link between attribution bias and frequent exposure to FPSs was reported (Hopp et al., 2018). Finally, in a study of children that used six different tasks to assess ToM, gaming time negatively predicted boys’ scores on the ToM task after a year (MacGowan & Schmidt, 2021).
Social Decision-Making
One study assessed social decision-making in undergraduates relative to their experience with VGs. This study showed that experienced gamers tended to be less cooperative than nonexperienced gamers (Jin & Li, 2017).
One study assessed social decision-making in PG using the chicken game paradigm. The chicken game is an economic game in which two players have to simultaneously make a decision. In this paradigm, not cooperating is the riskiest option but has the highest gain. PG patients tended to take riskier options and cooperate less than controls (Su et al., 2018). Moreover, PG patients displayed comparable levels of cooperative behavior when playing either with a friend or a game mate who they just met in the chicken game task. In contrast, controls were more cooperative with only their friend.
Aggressive Behavior
Nine studies explored the link between the frequency of playing VGs and the competitive reaction task (CRT) which is designed to explore aggressive behavior. In this task, participants are instructed to react as fast as possible to a noise stimulus. The loser (i.e., the slowest individual) is punished by a blast of noise, with the duration and intensity of noise are decided by the winner. In most experiments, tasks are programmed to provide half of the victories to the participant, and the intensity and duration of the blast of noise are measures of aggressive behavior (Chester & Lasko, 2019; Taylor, 1967). These studies have shown mixed results. A higher level of exposure to violent VGs has been linked to a more aggressive response pattern (Bartholow et al., 2005, 2006) and specific EEG responses in reaction to violent pictures (Bartholow et al., 2006). Interestingly, in this last study, the authors separated the effect of content (violent or not) from the frequency of play, and the link with aggressive behavior was significant only in relation to the content. Furthermore, action VG players displayed a higher level of aggression than nonplayers (Pichon et al., 2021). Moreover, a tendency to display greater aggression in the CRT after playing a violent VG was found, regardless of previous gaming experience (Engelhardt et al., 2011). Nevertheless, among a population of regular gamers, this link was found only in the group that played a violent VG and not in the group that played a neutral game (Arriaga et al., 2011). Finally, no links were found in four other studies (Devilly et al., 2021; Ferguson & Rueda, 2010; Ferguson et al., 2008; MacGowan & Schmidt, 2021).
Another type of measure was used in the last study: participants were asked to rate the profile of an applicant for a paid position in the laboratory in terms of competence, courtesy, merit of financial support, and merit of employment. Lower ratings were considered a measure of aggressive behavior. No link was found between exposure to VGs and the level of aggressive behavior (Tamborini et al., 2004).
No study was identified that assessed aggressive behavior in PG.
Moral Competence
Two studies assessed moral competence in a population of students and showed a positive link between the exposure to VGs and moral reasoning during VG play (Krcmar & Cingel, 2016). Moreover, exposure to VGs was also correlated with moral competence (Sofia & Klimenko, 2019).
No study was found on moral competence and PG.
Discussion
This article aimed to review all studies assessing SC with neuropsychological tasks NPG and PG. Thirty-nine articles that examined several aspects of SC were identified. Regarding facial emotion processing, the results of conscious facial emotion processing were mixed, but the results of unconscious and cerebral processing suggested that a change in processing emotions can in participants with PG. However, the variety of methods and populations assessed did not allow us to conclude that better or worse abilities were linked to VG use or PG. The results involving empathy mostly showed no differences linked to the use of VGs. Attribution bias studies had mixed results and assessed multiple populations (children, adolescents, and adults). Social decision-making studies reported a change in the processing of social distance (assessed when playing with friends or strangers just met in the game) in the PG population. Studies also showed less cooperative behavior in the adult population linked to NPG and PG. Regarding aggressive behavior, the results were mixed, and further research is needed. Nevertheless, half of the studies did not find a link between exposure to VG and CRT scores. Studies with PG are lacking. Finally, two studies showed that higher moral competence when presented with a moral dilemma was linked to higher VG exposure.
Gaming and Face Processing
Numerous studies were reviewed in this article, which shows the interest in and the importance of understanding the link between facial emotion processing and gaming. Nevertheless, the neuropsychological data did not clearly indicate deficits or improvements in identifying facial emotions but rather suggested cerebral changes in facial emotion processing. PG patients exhibit deficits in EEG studies and more precisely in the P300 component, which reflects attention allocation (Kuss, 2018). Moreover, it has been shown that excessive Internet users also display altered early processing of faces in terms of ERPs (He et al., 2011). Thus, studies have suggested changes in the cognitive processing of faces. These changes need to be confirmed. The preservation of emotion identification also needs to be confirmed with other studies in regular NPG and PG.
Three studies used the RMET to assess the ability to identify complex facial emotions based on pictures of eyes (Kittel et al., 2022). One study showed no effect of VG exposure (Kühn et al., 2019). Another study identified a link between negative emotion recognition and PG (Aydın et al., 2020). Finally, one study demonstrated a positive association between improved emotion recognition and MOBA competencies (Bonny et al., 2020). Nevertheless, these results should be interpreted with caution because the psychometric properties of the RMET appear to be fragile (Higgins et al., 2022; Pavlova & Sokolov, 2022). Indeed, one limitation of studying SC is that cognitive tasks are mainly experimental and statistically weak. There is no consensus regarding the assessment of SC in the general population. Nevertheless, this limitation has been overcome in the framework of schizophrenia. Indeed, researchers have studied several components of SC and identified tools to assess them, proposing a gold standard of SC assessment in schizophrenia. The social cognition psychometric evaluation (SCOPE) study concluded that the hinting task (hint understanding), the Penn Emotion Recognition Test (ER40, facial emotion recognition) and the Bell Lysaker Emotion Recognition Task (BLERT, facial/vocal/body emotional identification) were the tools with the strongest psychometric properties and should be used in clinical trials (Pinkham et al., 2018). Replicating such work in other pathologies or for the general population may improve assessments of SC and understanding of the SC in gamers.
Gaming and Empathy
Regarding empathy, no effects of VGs were found in studies using fMRI and diverse cognitive tasks. The interpersonal reactivity index (IRI (Davis, 1983)) is a self-report questionnaire that comprises fantasy and perspective-taking subscales (two measures of cognitive empathy) and empathic concern and personal distress subscales (two measures of affective empathy). A study that used to IRI to assess problematic Internet users found no stable associations (Melchers et al., 2015). However, when another questionnaire, the empathy quotient (Baron-Cohen & Wheelwright, 2004), was used, a link was found between lower levels of empathy and higher problematic Internet use (Melchers et al., 2015). Furthermore, no differences were found when comparing PG and NPG players (Collins & Freeman, 2013). These data suggest that PG is not associated with a diminution of empathy. Nevertheless, more studies are needed to reach conclusions regarding the profile of empathy among gamers and specifically those with PG. For example, no study has explored the affective and cognitive components of empathy, such as those proposed in the substance use disorders population with the Condensed and Revised Multifaceted Empathy Test (MET-CORE) (Grynberg et al., 2017). This study showed an alteration in the cognitive ability to decode complex emotions but preservation of sharing abilities (affective component, as assessed by self-reports cited herein). Thus, further studies are needed to explore whether PG is associated with the same patterns of alterations as those observed with substance use disorders. If this is the case, it would suggest that alterations in cognitive empathy are linked to addiction per se and not to the ingestion of neurotoxic substances.
Finally, in the general population, it has been shown that asking participants to feel empathy while in the fMRI scanner during an empathy-for-pain task created a bias for painful faces, with an overestimation of the intensity on faces (Naor et al., 2020). This study showed that SC components such as empathy and facial emotion processing are not discrete functions and that they have to be measured together to evaluate their reciprocal impacts.
Gaming, Theory of Mind, and Aggressive Behavior in the General Aggression Model (GAM)
Studies assessing ToM and VGs mainly focused on attribution bias and showed mixed results, while aggressive behavior was mainly assessed with the CRT and yileded mixed results. For those two SC components, correlational methods have mainly been used, making interpretation more complex and less powerful. Two studies suggested that immediately after having played violent VGs, there is an increase in aggressive behavior, but only for frequent gamers (Bartholow et al., 2005, 2006). This aspect has not been explored in the PG population. This field of research was developed in relation to the general aggression model (GAM) (DeWall et al., 2011). This model postulates that repeated exposure to violent VGs impacts cognition by increasing aggressiveness and then increasing aggressive behavior (Greitemeyer & Mügge, 2014). In our review, 18 out of 31 studies found significant results when assessing the impact of exposure to violent VGs. Moreover, several meta-analyses explored the impact of violent VGs on aggression showing that violent VGs seem to be linked to aggression (Anderson et al., 2010; Bushman & Huesmann, 2006; Prescott et al., 2018). Other meta-analyses have shown no effect of VGs on aggressive behavior (Elson & Ferguson, 2014; Ferguson and Kilburn, 2010; Sherry, 2001). Another meta-analysis reported nuanced these results and as VGs impacted social outcomes (behavioral, cognitive, affective and arousal measures, all mixed in the analysis) by increasing aggressive cognitions and decreasing prosocial outcomes (violent VGs) and increasing prosocial outcomes and decreasing aggressive cognitions (prosocial VGs) (Greitemeyer & Mügge, 2014). The variety of the methods used in the reviewed studies prevents firm conclusions, highlighting the complexity of the relationships between violent VGs and aggressive behavior. More research is needed, and future studies should consider using a thorough assessment of VG habits together with a wide ranging assessment of aggressive behavior (using both cognitive tasks and self-report measures).
Studies on aggressive behavior are absent from the PG literature, and this topic needs further research.
Additionally, aggression is rarely cited in theoretical models of SC, as it may be considered a biased behavior rather than a cognitive ability. Nevertheless, aggression can also be conceptualized as a non-prosocial behavior that falls under the spectrum of SC.
Gaming and Social Decision-Making
Studies assessing VG experience with and without addiction showed a tendency for reduced cooperation by experienced players. In PG, the study by Su et al. (2018) showed less overall cooperation during the chicken game, suggesting a preference for risky situations or less cooperative behavior. Specific patterns of responses were also found in nonsocial decision-making tasks in this population, with the same level of preference for risky decision-making (Dong & Potenza, 2016). Moreover, PG subjects tended to prefer short-term rewards (Dong & Potenza, 2014). Therefore, it is not clear whether these subjects choose riskier situations or display less cooperation per se.
Finally, during the chicken game (Su et al., 2018), PG players tended to cooperate with game mates as much as they did with friends and cooperated less often with occasional players. These results suggest that game mates were viewed as friends. PG participants, therefore, seem to present a specific pattern of relationships that may be altered in real life but not online.
Social decision-making has been explored in relation to PG and NPG, and research has shown that players’ decision-making seems to be marked by decreased cooperation. Nevertheless, the pattern of decision-making in individuals with PG is a tendency to choose the riskiest options (Schiebener & Brand, 2017), explaining this lack of cooperation. More research is needed to determine whether the tendency to cooperate is altered or impacted by the tendency to make riskier decisions.
Gaming and Moral Competency
Regarding moral competence, both studies described in this review suggested an improvement in moral competence associated with VG frequency, highlighting a positive impact of VGs (Krcmar & Cingel, 2016; Sofia & Klimenko, 2019). The authors linked these results to the fact that players used to violent VGs tended to more easily emotionally connect with the character presented in the moral dilemma (Sofia & Klimenko, 2019).
More research is needed to determine whether VG players show higher moral competence than nongamers and to explore this aspect in the PG population.
Impact of SC as a Whole
Only four studies of 39 used more than one task to assess SC, thus preventing conclusions regarding on an overall SC profile among video gamers. Such an overall profile can only be investigated by using a combination of measures, which may facilitate investigation of links between several components of SC. Thus, there is a need for studies to assess SC in video gamers using a combination of measures to assess a combination of SC components. Such multimodal assessment may also provide useful insight into the management of PG, by enabling therapists to focus treatment on the specific functions that are altered.
Additionally, SC may be linked with social functioning in gamers or with the motive to play. Indeed, the profile of SC may be different depending on what is looking for in VG by gamers. Complementary studies including levels of loveliness and motivation to play may allow us to examine the bigger picture of SC in gamers.
Problematic Gaming and SC
Interestingly, all studies including PG participants found significant results when assessing SC abilities. Indeed, when presented with facial emotions, PG subjects displayed unique cerebral functioning in two studies (He et al., 2019; Peng et al., 2017). Compared to controls, PG patients displayed a deficit in social perception similar to that of patients with methamphetamine use disorder (Jiang et al., 2020). Additionally, lower scores on the RMET were linked to Internet PG symptoms (Aydın et al., 2020). Finally, PG patients displayed lower cooperation than control participants who played a VG (Su et al., 2018). These deficits were be linked with alterations at the on a cerebral level in adolescents (Schettler et al., 2022) and adults (Yan et al., 2021) with PG. Specifically, hyperconnectivity of networks supporting affective processes (limbic structures and cortex networks) and hypoconnectivity of structures supporting cognitive control (such as frontoparietal areas) have been highlighted (Yan et al., 2021). Finally, studies assessing children and adolescents must be considered carefully because the brain and other cognitive functions are still under development and must be considered in transition (Kilford et al., 2016).
On the other hand, no massive effect of exposure to VGs appeared in the experimental literature. It would be interesting to assess addictive symptoms as a function of VG frequency or exposure to determine if the differences observed in this literature search, specifically those that show alterations in SC, are linked with an addictive profile. Indeed, as explained in Bandura’s model, psychosocial functioning can be explained as individual factors, such as cognitive functioning, reciprocally interacting with the environment and behavior (Bandura, 1986). In the context of VG use (behavior), the presence of alterations in SC (individual factor) may be a vulnerability factor that leads to addictive disorders. Reciprocally, the repetition of behavior and time spent playing VGs may lead to alterations in SC. In the same way, social capital or relationships (the environment) reciprocally interact with VG use and alterations in SC. More longitudinal studies are needed to answer these questions.
Limitations
Limitations of the Included Studies
Most included studies had a small sample size and assessed students from universities, which is a recruitment bias. Moreover, most research assessing the effects of long-term exposure to VGs has not assessed addictive symptoms, yet the presence of addictive symptoms can bias the results. Additionally, all included articles assessed only one component of SC and therefore did not permit the generation of SC profiles of participants, which could allow us to examine the links among SC components. Finally, most studies used correlation methods or group comparisons, but no longitudinal study was included, which does not allow us to make conclusions about the causality of identified links.
Limitations of the Review
Several limitations arose from the articles reviewed in this article. In particular, heterogeneity was the main characteristic of the research included. Indeed, variations in participants included age groups, definitions of PG (based on either international classifications — GD/IGD — or not), and gaming intensity; methods used and components assessed did not allow comparison between studies or generalization of results. Given this heterogeneity, this review did not include a meta-analysis, and therefore, we could not draw conclusions regarding specific alterations or preservations of cognitive functioning. Moreover, SC is a wide concept that could benefit from a consensus about which components should be included and how to assess them. Regarding the information collected about PG, the main limitation was the lack of homogeneity in the methods used, which highlights the necessity to conduct new research examining PG and SC.
Future Directions
This review showed that VGs have been investigated through the prism of SC but with many different methods and populations, leading to mixed results. Nevertheless, studies examining PG and SC remain scarce. Understanding SC abilities in VG players with or without addiction is essential to (i) better understand mechanisms of addiction and (ii) better inform the treatment of patients with PG by developing specific cognitive remediation programs that focus on specific alterations in SC. Questions that remain unexplored are as follows: (i) whether offline relationships are impaired and whether this impairments is explained by deficits in SC or withdrawal from offline relationships because of an overinvestment in online relationships; (ii) whether the difficulties related to offline relationships are present before the development of PG, leading these individuals to play and socialize online (i.e., an adaptive strategy), or conversely, are triggered by the high amount of VG use, which cuts these individuals off from real-life relationships and provokes online investment as compensation; and (iii) whether levels of SC deficits relate to levels of alterations observed in the PG population (specifically in social spheres such as school/work, family or friends). The recent recognition of PG can facilitate the development of research and therapies.
Availability of Data and Materials
Data and code sharing is not applicable to this article as no datasets were generated or analyzed during the current study.
References
Achim, A. M., Guitton, M., Jackson, P. L., Boutin, A., & Monetta, L. (2013). On what ground do we mentalize? Characteristics of current tasks and sources of information that contribute to mentalizing judgments. Psychological Assessment, 25(1), 117–126. https://doi.org/10.1037/a0029137
Adolphs, R. (2001). The neurobiology of social cognition. Current Opinion in Neurobiology, 11(2), 231–239. https://doi.org/10.1016/S0959-4388(00)00202-6
Adolphs, R. (2009). The social brain: Neural basis of social knowledge, 27.
Adolphs, R. (2010). Conceptual challenges and directions for social neuroscience. Neuron, 65(6), 752–767. https://doi.org/10.1016/j.neuron.2010.03.006
American Psychiatry Association. (2013). DSM-5: Diagnostic and statistical manual of mental disorders. American Psychiatric Publishing.
Anderson, C. A., Shibuya, A., Ihori, N., Swing, E. L., Bushman, B. J., Sakamoto, A., et al. (2010). Violent video game effects on aggression, empathy, and prosocial behavior in eastern and western countries: A meta-analytic review. Psychological Bulletin, 136(2), 151–173. https://doi.org/10.1037/a0018251
Argyriou, E., Davison, C. B., & Lee, T. T. C. (2017). Response inhibition and Internet gaming disorder: A meta-analysis. Addictive Behaviors, 7.
Arriaga, P., Monteiro, M. B., & Esteves, F. (2011). Effects of playing violent computer games on emotional desensitization and aggressive behavior1. Journal of Applied Social Psychology, 41(8), 1900–1925. https://doi.org/10.1111/j.1559-1816.2011.00791.x
Aydın, O., Güçlü, M., Ünal-Aydın, P., & Spada, M. M. (2020). Metacognitions and emotion recognition in Internet gaming disorder among adolescents. Addictive Behaviors Reports, 12, 100296. https://doi.org/10.1016/j.abrep.2020.100296
Bailey, K., & West, R. (2013). The effects of an action video game on visual and affective information processing. Brain Research, 1504, 35–46. https://doi.org/10.1016/j.brainres.2013.02.019
Bandura, A. (1986). Social foundations of thought and action: A social cognitive theory (pp. xiii, 617). Englewood Cliffs, NJ, US: Prentice-Hall, Inc.
Baron-Cohen, S., & Wheelwright, S. (2004). The empathy quotient: An investigation of adults with Asperger syndrome or high functioning autism, and normal sex differences. Journal of Autism and Developmental Disorders, 34(2), 163–175.
Bartholow, B. D., Bushman, B. J., & Sestir, M. A. (2006). Chronic violent video game exposure and desensitization to violence: Behavioral and event-related brain potential data. Journal of Experimental Social Psychology, 42(4), 532–539. https://doi.org/10.1016/j.jesp.2005.08.006
Bartholow, B. D., Sestir, M. A., & Davis, E. B. (2005). Correlates and consequences of exposure to video game violence: Hostile personality, empathy, and aggressive behavior. Personality & Social Psychology Bulletin, 31(11), 1573–1586. https://doi.org/10.1177/0146167205277205
Bediou, B., Adams, D. M., Mayer, R. E., Tipton, E., Green, C. S., & Bavelier, D. (2018). Meta-analysis of action video game impact on perceptual, attentional, and cognitive skills. Psychological Bulletin, 144(1), 77–110. https://doi.org/10.1037/bul0000130
Beer, J. S., & Ochsner, K. N. (2006). Social cognition: A multi level analysis. Brain Research, 1079(1), 98–105. https://doi.org/10.1016/j.brainres.2006.01.002
Bertoux, M. (2016). Cognition sociale. http://www.em-premium.com/data/traites/ne/17-65655/. https://www-em-premium-com.budistant.univ-nantes.fr/article/1055941/resultatrecherche/1. Accessed 20 January 2021
Bonny, J. W., Scanlon, M., & Castaneda, L. M. (2020). Variations in psychological factors and experience-dependent changes in team-based video game performance. Intelligence, 80. https://doi.org/10.1016/j.intell.2020.101450
Brand, M., Snagowski, J., Laier, C., & Maderwald, S. (2016). Ventral striatum activity when watching preferred pornographic pictures is correlated with symptoms of Internet pornography addiction. NeuroImage, 129, 224–232. https://doi.org/10.1016/j.neuroimage.2016.01.033
Brand, M., Wegmann, E., Stark, R., Müller, A., Wölfling, K., Robbins, T. W., & Potenza, M. N. (2019). The Interaction of Person-Affect-Cognition-Execution (I-PACE) model for addictive behaviors: Update, generalization to addictive behaviors beyond Internet-use disorders, and specification of the process character of addictive behaviors. Neuroscience & Biobehavioral Reviews, 104, 1–10. https://doi.org/10.1016/j.neubiorev.2019.06.032
Brilliant T, D., Nouchi, R., & Kawashima, R. (2019). Does video gaming have impacts on the brain: Evidence from a systematic review. Brain Sciences, 9(10). https://doi.org/10.3390/brainsci9100251
Brunet, E., Sarfati, Y., & Hardy-Baylé, M.-C. (2003). Reasoning about physical causality and other’s intentions in schizophrenia. Cognitive Neuropsychiatry, 8(2), 129–139. https://doi.org/10.1080/13546800244000256
Buck, B., Browne, J., Gagen, E. C., & Penn, D. L. (2020). Hostile attribution bias in schizophrenia-spectrum disorders: Narrative review of the literature and persisting questions. Journal of Mental Health, 0(0), 1–18. https://doi.org/10.1080/09638237.2020.1739240
Bushman, B. J., & Huesmann, L. R. (2006). Short-term and long-term effects of violent media on aggression in children and adults. Archives of Pediatrics & Adolescent Medicine, 160(4), 348–352. https://doi.org/10.1001/archpedi.160.4.348
Casaletto, K. B., & Heaton, R. K. (2017). Neuropsychological assessment: Past and future. Journal of the International Neuropsychological Society : JINS, 23(9–10), 778–790. https://doi.org/10.1017/S1355617717001060
Chester, D. S., & Lasko, E. N. (2019). Validating a standardized approach to the Taylor aggression paradigm. Social Psychological and Personality Science, 10(5), 620–631. https://doi.org/10.1177/1948550618775408
Collins, E., & Freeman, J. (2013). Do problematic and non-problematic video game players differ in extraversion, trait empathy, social capital and prosocial tendencies? Computers in Human Behavior, 29, 8. https://doi.org/10.1016/j.chb.2013.03.002
Couture, S. M., Penn, D. L., & Roberts, D. L. (2006). The functional significance of social cognition in schizophrenia: A review. Schizophrenia Bulletin, 32, 20. https://doi.org/10.1093/schbul/sbl029
Cui, I. J. (2006). Standard setting issues of Internet addiction scale and Internet game addiction scale. Chin J Appl Psychol, 12(2), 42–47.
Davis, M. H. (1983). The effects of dispositional empathy on emotional reactions and helping: A multidimensional approach. Journal of Personality, 51(2), 167–184. https://doi.org/10.1111/j.1467-6494.1983.tb00860.x
Decety, J., & Lamm, C. (2006, Sep 20). Human empathy through the lens of social neuroscience. The Scientific World Journal, 6, 1146–1163. https://doi.org/10.1100/tsw.2006.221. PMID: 16998603; PMCID: PMC5917291.
Devilly, G., O’Donohue, R., & Brown, K. (2021). Personality and frustration predict aggression and anger following violent media. Psychology Crime & Law. https://doi.org/10.1080/1068316X.2021.1999949
DeWall, C. N., Anderson, C. A., & Bushman, B. J. (2011). The general aggression model: Theoretical extensions to violence. Psychology of Violence, 1(3), 245–258. https://doi.org/10.1037/a0023842
Diaz, R. L., Wong, U., Hodgins, D. C., Chiu, C. G., & Goghari, V. M. (2015). Violent video game players and non-players differ on facial emotion recognition. Aggressive Behavior, 42(1), 16–28. https://doi.org/10.1002/ab.21602
Dong, G., & Potenza, M. N. (2014). A cognitive-behavioral model of Internet gaming disorder: Theoretical underpinnings and clinical implications. Journal of Psychiatric Research, 58, 7–11. https://doi.org/10.1016/j.jpsychires.2014.07.005
Dong, G., & Potenza, M. N. (2016). Risk-taking and risky decision-making in Internet gaming disorder: Implications regarding online gaming in the setting of negative consequences. Journal of Psychiatric Research, 73, 1–8. https://doi.org/10.1016/j.jpsychires.2015.11.011
Duchaine, B., & Yovel, G. (2015). A revised neural framework for face processing. Annual Review of Vision Science, 1, 393–416. https://doi.org/10.1146/annurev-vision-082114-035518
Eastin, M. S., & Griffiths, R. P. (2009). Unreal: Hostile expectations from social gameplay. New Media & Society, 11(4), 509–531. https://doi.org/10.1177/1461444809102958
Elson, M., & Ferguson, C. J. (2014). Twenty-five years of research on violence in digital games and aggression. European Psychologist, 19(1), 33–46. https://doi.org/10.1027/1016-9040/a000147
Engelhardt, C. R., Bartholow, B. D., Kerr, G. T., & Bushman, B. J. (2011). This is your brain on violent video games: Neural desensitization to violence predicts increased aggression following violent video game exposure. Journal of Experimental Social Psychology, 47(5), 1033–1036. https://doi.org/10.1016/j.jesp.2011.03.027
Etchepare, A., & Prouteau, A. (2017). Toward a two-dimensional model of social cognition in clinical neuropsychology: A systematic review of factor structure studies. Journal of the International Neuropsychological Society, 24(4), 391–404. https://doi.org/10.1017/S1355617717001163
Ferguson, C. J., & Colwell, J. (2020). Sexualised video games, sexist attitudes and empathy towards victims of rape: Correlational evidence for a relationship is minimal in an online study. Criminal Behaviour and Mental Health : CBMH, 30(1), 16–27. https://doi.org/10.1002/cbm.2138
Ferguson, C. J., & Kilburn, J. (2010). Much ado about nothing: The misestimation and overinterpretation of violent video game effects in eastern and western nations: Comment on Anderson et al. (2010). Psychological Bulletin, 136(2), 174–178; discussion 182–187. https://doi.org/10.1037/a0018566
Ferguson, C. J., & Rueda, S. M. (2010). The Hitman study: Violent video game exposure effects on aggressive behavior, hostile feelings, and depression. European Psychologist, 15(2), 99–108. https://doi.org/10.1027/1016-9040/a000010
Ferguson, C. J., Rueda, S. M., Cruz, A. M., Ferguson, D. E., Fritz, S., & Smith, S. M. (2008). Violent video games and aggression: Causal relationship or byproduct of family violence and intrinsic violence motivation? Criminal Justice and Behavior, 35(3), 311–332. https://doi.org/10.1177/0093854807311719
Ferguson, C. J., & Wang, J. C. K. (2019). Aggressive video games are not a risk factor for future aggression in youth: A longitudinal study. Journal of Youth and Adolescence, 48(8), 1439–1451. https://doi.org/10.1007/s10964-019-01069-0
Fiske, S. T., & Taylor, S. E. (2016). Social cognition: From brains to culture. SAGE Publications.
Frith, C. D. (2008). Social cognition. Philosophical Transactions of the Royal Society b: Biological Sciences, 363(1499), 2033–2039. https://doi.org/10.1098/rstb.2008.0005
Frith, C. D., & Frith, U. (2008). Implicit and explicit processes in social cognition. Neuron, 60(3), 503–510. https://doi.org/10.1016/j.neuron.2008.10.032
Frölich, J., Lehmkuhl, G., Orawa, H., Bromba, M., Wolf, K., & Görtz-Dorten, A. (2016). Computer game misuse and addiction of adolescents in a clinically referred study sample. Computers in Human Behavior, 55, 9–15. https://doi.org/10.1016/j.chb.2015.08.043
Funk, J. B., Buchman, D. D., Jenks, J., & Bechtoldt, H. (2003). Playing violent video games, desensitization, and moral evaluation in children. Journal of Applied Developmental Psychology, 24(4), 413–436. https://doi.org/10.1016/S0193-3973(03)00073-X
Gabbiadini, A., Riva, P., Andrighetto, L., Volpato, C., & Bushman, B. J. (2016). Acting like a tough guy: Violent-sexist video games, identification with game characters, masculine beliefs, & empathy for female violence victims. PLoS One, 11(4), e0152121.
Gao, X., Pan, W., Li, C., Weng, L., Yao, M., & Chen, A. (2017). Long-time exposure to violent video games does not show desensitization on empathy for pain: An fMRI study. Frontiers in Psychology, 8, 650–650. https://doi.org/10.3389/fpsyg.2017.00650
Gentile, D. A., Anderson, C. A., Yukawa, S., Ihori, N., Saleem, M., Ming, L. K., et al. (2009). The effects of prosocial video games on prosocial behaviors: International evidence from correlational, longitudinal, and experimental studies. Personality & Social Psychology Bulletin, 35(6), 752–763. https://doi.org/10.1177/0146167209333045
Green, M. F., Horan, W. P., & Lee, J. (2015). Social cognition in schizophrenia. Nature Reviews Neuroscience, 16(10), 620–631. https://doi.org/10.1038/nrn4005
Greifeneder, R., Bless, H., & Fiedler, K. (2017). Social cognition: How individuals construct social reality. Psychology Press.
Greitemeyer, T., & Mügge, D. O. (2014). Video games do affect social outcomes: A meta-analytic review of the effects of violent and prosocial video game play. Personality and Social Psychology Bulletin, 40(5), 578–589. https://doi.org/10.1177/0146167213520459
Grynberg, D., Maurage, P., & Nandrino, J.-L. (2017). Preserved affective sharing but impaired decoding of contextual complex emotions in alcohol dependence. Alcoholism: Clinical and Experimental Research, 41(4), 779–785. https://doi.org/10.1111/acer.13330
Happé, F., & Conway, J. R. (2016). Recent progress in understanding skills and impairments in social cognition. Current Opinion in Pediatrics, 28(6), 736–742. https://doi.org/10.1097/MOP.0000000000000417
He, J., Liu, C., Guo, Y., & Zhao, L. (2011). Deficits in early-stage face perception in excessive Internet users. Cyberpsychology, Behavior, and Social Networking, 14(5), 303–308. https://doi.org/10.1089/cyber.2009.0333
He, J., Zheng, Y., Fan, L., Pan, T., & Nie, Y. (2019). Automatic processing advantage of cartoon face in Internet gaming disorder: Evidence from P100, N170, P200, and MMN. Frontiers in Psychiatry, 10, 824. https://doi.org/10.3389/fpsyt.2019.00824
Higgins, W. C., Ross, R. M., Langdon, R., & Polito, V. (2022). The “reading the mind in the eyes” test shows poor psychometric properties in a large, demographically representative U.S. sample. Assessment, 10731911221124342. https://doi.org/10.1177/10731911221124342
Hopp, T., Parrott, S., & Wang, Y. (2018). Use of military-themed first-person shooter games and militarism: An investigation of two potential facilitating mechanisms. Computers in Human Behavior, 78, 192–199. https://doi.org/10.1016/j.chb.2017.09.035
Hyun, G. J., Han, D. H., Lee, Y. S., Kang, K. D., Yoo, S. K., Chung, U.-S., & Renshaw, P. F. (2015). Risk factors associated with online game addiction: A hierarchical model. Computers in Human Behavior, 48, 706–713. https://doi.org/10.1016/j.chb.2015.02.008
Jiang, C., Li, C., Zhou, H., & Zhou, Z. (2020). Individuals with Internet gaming disorder have similar neurocognitive impairments and social cognitive dysfunctions as methamphetamine-dependent patients. Adicciones, 0(0), 1342. https://doi.org/10.20882/adicciones.1342
Jin, Y., & Li, J. (2017). When newbies and veterans play together: The effect of video game content, context and experience on cooperation. Computers in Human Behavior, 68, 556–563. https://doi.org/10.1016/j.chb.2016.11.059
Jung, W. H., Prehn, K., Fang, Z., Korczykowski, M., Kable, J. W., Rao, H., & Robertson, D. C. (2016). Moral competence and brain connectivity: A resting-state fMRI study. NeuroImage, 141, 408–415. https://doi.org/10.1016/j.neuroimage.2016.07.045
Kang, J. O., Kang, K. D., Lee, J. W., Nam, J. J., & Han, D. H. (2020). Comparison of psychological and cognitive characteristics between professional Internet game players and professional baseball players. International journal of environmental research and public health, 17(13). https://doi.org/10.3390/ijerph17134797
Kilford, E. J., Garrett, E., & Blakemore, S.-J. (2016). The development of social cognition in adolescence: An integrated perspective. Neuroscience & Biobehavioral Reviews, 70, 106–120. https://doi.org/10.1016/j.neubiorev.2016.08.016
Kittel, A. F. D., Olderbak, S., & Wilhelm, O. (2022). Sty in the mind’s eye: A meta-analytic investigation of the nomological network and internal consistency of the “reading the mind in the eyes” test. Assessment, 29(5), 872–895. https://doi.org/10.1177/1073191121996469
Krahé, B., & Möller, I. (2004). Playing violent electronic games, hostile attributional style, and aggression-related norms in German adolescents. Journal of Adolescence, 27(1), 53–69. https://doi.org/10.1016/j.adolescence.2003.10.006
Krarup, K. B., & Krarup, H. B. (2020). The physiological and biochemical effects of gaming: A review. Environmental Research, 184, 109344. https://doi.org/10.1016/j.envres.2020.109344
Krcmar, M., & Cingel, D. P. (2016). Moral foundations theory and moral reasoning in video game play: Using real-life morality in a game context. Journal of Broadcasting & Electronic Media, 60(1), 87–103. https://doi.org/10.1080/08838151.2015.1127246
Kühn, S., Kugler, D., Schmalen, K., Weichenberger, M., Witt, C., & Gallinat, J. (2018). The myth of blunted gamers: No evidence for desensitization in empathy for pain after a violent video game intervention in a longitudinal fMRI study on non-gamers. Neuro-Signals, 26(1), 22–30. https://doi.org/10.1159/000487217
Kühn, S., Kugler, D. T., Schmalen, K., Weichenberger, M., Witt, C., & Gallinat, J. (2019). Does playing violent video games cause aggression? A Longitudinal Intervention Study. Molecular Psychiatry, 24(8), 1220–1234. https://doi.org/10.1038/s41380-018-0031-7
Kuss, D. J. (2018). Neurobiological correlates in Internet gaming disorder: A systematic literature review. Frontiers in Psychiatry, 9, 12.
Langdon, R., Connors, M. H., & Connaughton, E. (2014). Social cognition and social judgment in schizophrenia. Schizophrenia Research: Cognition, 1(4), 171–174. https://doi.org/10.1016/j.scog.2014.10.001
Lemmens, J. S., Valkenburg, P. M., & Peter, J. (2011). The effects of pathological gaming on aggressive behavior. Journal of Youth and Adolescence, 40(1), 38–47. https://doi.org/10.1007/s10964-010-9558-x
Leouzon, H., Alexandre, J.-M., Fatséas, M., & Auriacombe, M. (2019). L’addiction aux jeux vidéo dans le DSM-5, controverses et réponses relatives à son diagnostic et sa définition. Annales Médico-Psychologiques, Revue Psychiatrique, 177(7), 610–623. https://doi.org/10.1016/j.amp.2019.03.013
Lim, J.-A., Lee, J.-Y., Jung, H. Y., Sohn, B. K., Choi, S.-W., Kim, Y. J., et al. (2016). Changes of quality of life and cognitive function in individuals with Internet gaming disorder: A 6-month follow-up. Medicine, 95(50), e5695. https://doi.org/10.1097/MD.0000000000005695
Lind, G. (2008). The meaning and measurement of moral judgment competence. A dual-aspect model. In Contemporary philosophical and psychological perspectives on moral development and education (Hampton Press., pp. 185–220). Creskill.
Lo, S.-K., Wang, C.-C., & Fang, W. (2005). Physical interpersonal relationships and social anxiety among online game players. Cyberpsychology & Behavior: THe Impact of the Internet, Multimedia and Virtual Reality on Behavior and Society, 8(1), 15–20. https://doi.org/10.1089/cpb.2005.8.15
Lockwood, P. L. (2016). The anatomy of empathy: Vicarious experience and disorders of social cognition. Behavioural Brain Research, 311, 255–266. https://doi.org/10.1016/j.bbr.2016.05.048
Lotze, M., Veit, R., Anders, S., & Birbaumer, N. (2007). Evidence for a different role of the ventral and dorsal medial prefrontal cortex for social reactive aggression: An interactive fMRI study. NeuroImage, 34(1), 470–478. https://doi.org/10.1016/j.neuroimage.2006.09.028
MacGowan, T. L., & Schmidt, L. A. (2021). Preschoolers’ social cognitive development in the age of screen time ubiquity. Cyberpsychology, Behavior and Social Networking, 24(2), 141–144. https://doi.org/10.1089/cyber.2020.0093
McDonald, S. (2013). Impairments in social cognition following severe traumatic brain injury. Journal of the International Neuropsychological Society: JINS, 19(3), 231–246. https://doi.org/10.1017/S1355617712001506
Melchers, M., Li, M., Chen, Y., Zhang, W., & Montag, C. (2015, Oct). Low empathy is associated with problematic use of the Internet: Empirical evidence from China and Germany. Asian Journal of Psychiatry, 17, 56–60. https://doi.org/10.1016/j.ajp.2015.06.019. Epub 2015 Jul 6. PMID: 26233696.
Miedzobrodzka, E., Buczny, J., Konijn, E. A., & Krabbendam, L. C. (2021a). Insensitive players? A relationship between violent video game exposure and recognition of negative emotions. Frontiers in psychology, 12, 651759. https://doi.org/10.3389/fpsyg.2021.651759
Miedzobrodzka, E., van Hooff, J. C., Konijn, E. A., & Krabbendam, L. (2021b). Is it painful? Playing violent video games affects brain responses to painful pictures: An event-related potential study. Psychology of Popular Media. https://doi.org/10.1037/ppm0000290
Miguel, F. K., Carvalho, L. de F., & Dionísio, T. E. S. (2017). Psychological assessment of videogame, board and live players: Personality, reasoning, and emotional perception. Psicologia: Teoria e Prática, 19(3), 209–225.
Mihara, S., & Higuchi, S. (2017). Cross-sectional and longitudinal epidemiological studies of Internet gaming disorder: A systematic review of the literature. Psychiatry and Clinical Neurosciences, 20.
Moher, D., Booth, A., & Stewart, L. (2014). How to reduce unnecessary duplication: use PROSPERO. BJOG: An international journal of obstetrics and gynaecology, 121(7), 784–786. https://doi.org/10.1111/1471-0528.12657
Moher, D., Liberati, A., Tetzlaff, J., Altman, D. G., & for the PRISMA Group. (2009). Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. BMJ, 339(jul21 1), b2535–b2535. https://doi.org/10.1136/bmj.b2535
Möller, I., & Krahé, B. (2009). Exposure to violent video games and aggression in German adolescents: A longitudinal analysis. Aggressive Behavior, 35(1), 75–89. https://doi.org/10.1002/ab.20290
Naor, N., Rohr, C., Schaare, L. H., Limbachia, C., Shamay-Tsoory, S., & Okon-Singer, H. (2020). The neural networks underlying reappraisal of empathy for pain. Social Cognitive and Affective Neuroscience, 15(7), 733–744. https://doi.org/10.1093/scan/nsaa094
Noel, X., Brevers, D., & Bechara, A. (2013). A neurocognitive approach to understanding the neurobiology of addiction. Current Opinion in Neurobiology, 23(4), 632–638. https://doi.org/10.1016/j.conb.2013.01.018
Ong, D. C., Zaki, J., & Goodman, N. D. (2015). Affective cognition: Exploring lay theories of emotion. Cognition, 143, 141–162. https://doi.org/10.1016/j.cognition.2015.06.010
Palaus, M., Marron, E. M., Viejo-Sobera, R., & Redolar-Ripoll, D. (2017). Neural basis of video gaming: A systematic review. Frontiers in Human Neuroscience, 11. https://doi.org/10.3389/fnhum.2017.00248
Pavlova, M. A., & Sokolov, A. A. (2022). Reading language of the eyes. Neuroscience and Biobehavioral Reviews, 140, 104755. https://doi.org/10.1016/j.neubiorev.2022.104755
Peng, X., Cui, F., Wang, T., & Jiao, C. (2017). Unconscious processing of facial expressions in individuals with Internet gaming disorder. Frontiers in Psychology, 8, 1059.
Pichon, S., Bediou, B., Antico, L., Jack, R., Garrod, O., Sims, C., et al. (2021). Emotion perception in habitual players of action video games. Emotion (Washington, D.C.), 21(6), 1324–1339. https://doi.org/10.1037/emo0000740
Pinkham, A. E., Harvey, P. D., & Penn, D. L. (2018). Social cognition psychometric evaluation: Results of the final validation study. Schizophrenia Bulletin, 44(4), 737–748. https://doi.org/10.1093/schbul/sbx117
Premack, D., & Woodruff, G. (1978). Does the chimpanzee have a theory of mind? Behavioral and Brain Sciences, 1(4), 515–526. https://doi.org/10.1017/S0140525X00076512
Prescott, A. T., Sargent, J. D., & Hull, J. G. (2018). Metaanalysis of the relationship between violent video game play and physical aggression over time. Proceedings of the National Academy of Sciences, 115(40), 9882–9888. https://doi.org/10.1073/pnas.1611617114
Rathbone, J., Hoffmann, T., & Glasziou, P. (2015). Faster title and abstract screening? Evaluating Abstrackr, a semi-automated online screening program for systematic reviewers. Systematic Reviews, 4, 80. https://doi.org/10.1186/s13643-015-0067-6
Rilling, J. K., & Sanfey, A. G. (2011). The Neuroscience of social decision-making. Annual Review of Psychology, 62(1), 23–48. https://doi.org/10.1146/annurev.psych.121208.131647
Rothman, M. L., Beltran, P., Cappelleri, J. C., Lipscomb, J., & Teschendorf, B. (2007). Patient-reported outcomes: Conceptual issues. Value in Health, 10, S66–S75. https://doi.org/10.1111/j.1524-4733.2007.00269.x
Ryu, H., Lee, J.-Y., Choi, A., Park, S., Kim, D.-J., & Choi, J.-S. (2018). The relationship between impulsivity and Internet gaming disorder in young adults: Mediating effects of interpersonal relationships and depression. International Journal of Environmental Research and Public Health, 15(3). https://doi.org/10.3390/ijerph15030458
Saxe, R. (2006). Uniquely human social cognition. Current Opinion in Neurobiology, 16(2), 235–239. https://doi.org/10.1016/j.conb.2006.03.001
Schettler, L., Thomasius, R., & Paschke, K. (2022). Neural correlates of problematic gaming in adolescents: A systematic review of structural and functional magnetic resonance imaging studies. Addiction Biology, 27(1), e13093. https://doi.org/10.1111/adb.13093
Schiebener, J., & Brand, M. (2017). Decision-making and related processes in Internet gaming disorder and other types of Internet-use disorders. Current Addiction Reports, 4. https://doi.org/10.1007/s40429-017-0156-9
Schurz, M., Radua, J., Aichhorn, M., Richlan, F., & Perner, J. (2014). Fractionating theory of mind: A meta-analysis of functional brain imaging studies. Neuroscience & Biobehavioral Reviews, 42, 9–34. https://doi.org/10.1016/j.neubiorev.2014.01.009
Schweinberger, S. R., & Neumann, M. F. (2016). Repetition effects in human ERPs to faces. Cortex, 80, 141–153. https://doi.org/10.1016/j.cortex.2015.11.001
Shamay-Tsoory, S., Harari, H., Szepsenwol, O., & Levkovitz, Y. (2009). Neuropsychological evidence of impaired cognitive empathy in euthymic bipolar disorder. The Journal of Neuropsychiatry and Clinical Neurosciences, 21(1), 59–67. https://doi.org/10.1176/jnp.2009.21.1.59
Shamay-Tsoory, S. G., & Aharon-Peretz, J. (2007). Dissociable prefrontal networks for cognitive and affective theory of mind: A lesion study. Neuropsychologia, 45(13), 3054–3067. https://doi.org/10.1016/j.neuropsychologia.2007.05.021
Sherry, J. L. (2001). The effects of violent video games on aggression. Human Communication Research, 27(3), 409–431. https://doi.org/10.1111/j.1468-2958.2001.tb00787.x
Singer, T., & Klimecki, O. M. (2014). Empathy and compassion. Current Biology, 24(18), R875–R878. https://doi.org/10.1016/j.cub.2014.06.054
Sofia, F. M., & Klimenko, M. A. (2019). Hey! Listen! Just because it’s violent doesn’t mean it’s immoral. Psychology of Popular Media Culture, 8(3), 251–258. https://doi.org/10.1037/ppm0000171
Stockdale, L., Morrison, R. G., Palumbo, R., Garbarino, J., & Silton, R. L. (2017). Cool, callous and in control: Superior inhibitory control in frequent players of video games with violent content. Social Cognitive and Affective Neuroscience, 12(12), 1869–1880. https://doi.org/10.1093/scan/nsx115
Su, W., Potenza, M. N., Zhang, Z., Hu, X., Gao, L., & Wang, Y. (2018). Do individuals with problematic and non-problematic Internet game use differ in cooperative behaviors with partners of different social distances? Evidence from the Prisoner’s Dilemma and Chicken Game. Computers in Human Behavior, 87, 363–370. https://doi.org/10.1016/j.chb.2018.05.040
Sunil, S., Sharma, M. K., & Anand, N. (2021). Impact of PlayerUnknown’s Battlegrounds (PUBG) on mental health. The Medico-Legal Journal, 89(2), 99–101. https://doi.org/10.1177/0025817220981817
Szycik, G. R., Mohammadi, B., Münte, T. F., & Te Wildt, B. T. (2017). Lack of evidence that neural empathic responses are blunted in excessive users of violent video games: An fMRI study. Frontiers in Psychology, 8, 174–174. https://doi.org/10.3389/fpsyg.2017.00174
Tamborini, R., Eastin, M., Skalski, P., Lachlan, K., Fediuk, T., & Brady, R. (2004). Violent virtual video games and hostile thoughts. Journal of Broadcasting & Electronic Media, 48, 335–357.
Taylor, G. J., Ryan, D., & Bagby, R. M. (1985). Toward the development of a new self-report alexithymia scale. Psychotherapy and Psychosomatics, 44(4), 191–199. https://doi.org/10.1159/000287912
Taylor, S. P. (1967). Aggressive behavior and physiological arousal as a function of provocation and the tendency to inhibit aggression1. Journal of Personality, 35(2), 297–310. https://doi.org/10.1111/j.1467-6494.1967.tb01430.x
van den Eijnden, R., Koning, I., Doornwaard, S., van Gurp, F., & Ter Bogt, T. (2018). The impact of heavy and disordered use of games and social media on adolescents’ psychological, social, and school functioning. Journal of Behavioral Addictions, 7(3), 697–706. https://doi.org/10.1556/2006.7.2018.65
Wallace, B. C., Small, K., Brodley, C. E., Lau, J., & Trikalinos, T. A. (2012). Deploying an interactive machine learning system in an evidence-based practice center: abstrackr. In Proc. of the ACM Internation Health Informatics Symposium (IHI) (pp. 819–824). Presented at the Proc. of the ACM Internation Health Informatics Symposium (IHI).
Williams, D. (2006). On and off the ’net: Scales for social capital in an online era. Journal of Computer-Mediated Communication, 11(2), 593–628. https://doi.org/10.1111/j.1083-6101.2006.00029.x
World Health Organization. (2018). International classification of diseases (11th Revision).
Yan, H., Li, Q., Yu, K., & Zhao, G. (2021). Large-scale network dysfunction in youths with Internet gaming disorder: A meta-analysis of resting-state functional connectivity studies. Progress in Neuro-Psychopharmacology and Biological Psychiatry, 109, 110242. https://doi.org/10.1016/j.pnpbp.2021.110242
Yao, Y.-W., Liu, L., Ma, S.-S., Shi, X.-H., Zhou, N., Zhang, J.-T., & Potenza, M. N. (2017). Functional and structural neural alterations in Internet gaming disorder: A systematic review and meta-analysis. Neuroscience and Biobehavioral Reviews, 83, 313–324. https://doi.org/10.1016/j.neubiorev.2017.10.029
Young, K. (2016). Internet addiction test (IAT). Stoelting.
Zhen, S., Xie, H., Zhang, W., Wang, S., & Li, D. (2011). Exposure to violent computer games and Chinese adolescents’ physical aggression: The role of beliefs about aggression, hostile expectations, and empathy. Computers in Human Behavior, 27(5), 1675–1687. https://doi.org/10.1016/j.chb.2011.02.006
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Elodie Hurel received funding from the University of Nantes in the form of a doctoral allowance for her PhD. Additionally, this study received funding from the two French gambling operators holding exclusive rights (FDJ and PMU), as part of the implementation of the French obligation to finance scientific studies on gambling and related addictive disorders (Law n° 2010-476 of May 12th modified, art. 3).
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All authors contributed to the design of this review. EH and MBPD did the screening of the articles. EH wrote the draft, and all authors provided feedback and helped shape the manuscript. All authors have approved the manuscript.
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EH, MGB, MBPD, MCE, GCB, declare that the Endowment Fund of the University Hospital of Nantes received funding from the gambling industry (FDJ and PMU) for the present study as part of the implementation of the obligation to finance scientific studies on gambling and related addictive disorders (Law n° 2010-476 of May 12th modified, art. 3). This funding is carried out in the form of a sponsorship donated to the Endowment Fund of the University Hospital of Nantes whereas the sponsor of the study is the University Hospital of Nantes, making it possible to guarantee the scientific independence, objectivity and impartiality of the research work
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Hurel, E., Grall-Bronnec, M., Bouillard, O. et al. Systematic Review of Gaming and Neuropsychological Assessment of Social Cognition. Neuropsychol Rev (2023). https://doi.org/10.1007/s11065-023-09599-y
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DOI: https://doi.org/10.1007/s11065-023-09599-y