Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-16T15:25:23.622Z Has data issue: true hasContentIssue false
  • English
  • Français

Prevalence of schizophrenia spectrum and other psychotic disorders in problem gambling: A systematic review and meta-analysis

Published online by Cambridge University Press:  25 September 2024

Olivier Corbeil Open the ORCID record for Olivier Corbeil [Opens in a new window] ,
Laurent Béchard Open the ORCID record for Laurent Béchard [Opens in a new window] ,
Élizabeth Anderson Open the ORCID record for Élizabeth Anderson [Opens in a new window] ,
Maxime Huot-Lavoie Open the ORCID record for Maxime Huot-Lavoie [Opens in a new window] ,
Charles Desmeules Open the ORCID record for Charles Desmeules [Opens in a new window] ,
Lauryann Bachand Open the ORCID record for Lauryann Bachand [Opens in a new window] ,
Sébastien Brodeur Open the ORCID record for Sébastien Brodeur [Opens in a new window] ,
Pierre-Hugues Carmichael Open the ORCID record for Pierre-Hugues Carmichael [Opens in a new window] ,
Christian Jacques  and
Marco Solmi Open the ORCID record for Marco Solmi [Opens in a new window]
...Show all authors
Olivier Corbeil*
Affiliation:
Faculty of Pharmacy, Université Laval, Quebec, QC, Canada Quebec Mental Health University Institute, Quebec, QC, Canada CERVO Brain Research Centre, Quebec, QC, Canada
Laurent Béchard
Affiliation:
Faculty of Pharmacy, Université Laval, Quebec, QC, Canada Quebec Mental Health University Institute, Quebec, QC, Canada CERVO Brain Research Centre, Quebec, QC, Canada
Élizabeth Anderson
Affiliation:
CERVO Brain Research Centre, Quebec, QC, Canada School of Psychology, Université Laval, Quebec, QC, Canada
Maxime Huot-Lavoie
Affiliation:
CERVO Brain Research Centre, Quebec, QC, Canada Faculty of Medicine, Université Laval, Quebec, QC, Canada
Charles Desmeules
Affiliation:
CERVO Brain Research Centre, Quebec, QC, Canada Faculty of Medicine, Université Laval, Quebec, QC, Canada
Lauryann Bachand
Affiliation:
School of Psychology, Université Laval, Quebec, QC, Canada
Sébastien Brodeur
Affiliation:
Quebec Mental Health University Institute, Quebec, QC, Canada CERVO Brain Research Centre, Quebec, QC, Canada Faculty of Medicine, Université Laval, Quebec, QC, Canada Institute of Psychiatry, Psychology and Neuroscience, King’s College London, London, UK
Pierre-Hugues Carmichael
Affiliation:
Centre d’Excellence sur le Vieillissement de Québec, Quebec, QC, Canada
Christian Jacques
Affiliation:
School of Psychology, Université Laval, Quebec, QC, Canada Centre Québécois d’Excellence pour la Prévention et le Traitement du Jeu, Quebec, QC, Canada
Marco Solmi
Affiliation:
SCIENCES Lab, Department of Psychiatry, University of Ottawa, Ottawa, ON, Canada Department of Mental Health, The Ottawa Hospital, Regional Centre for the Treatment of Eating Disorders and On Track: The Champlain First Episode Psychosis Program, Ottawa, ON, Canada Ottawa Hospital Research Institute (OHRI), Clinical Epidemiology Program, University of Ottawa, Ottawa, ON, Canada Department of Child and Adolescent Psychiatry, Charité Universitätsmedizin, Berlin, Germany
Michel Dorval
Affiliation:
Faculty of Pharmacy, Université Laval, Quebec, QC, Canada CHU de Québec – Université Laval Research Centre, Quebec, Canada
Isabelle Giroux
Affiliation:
School of Psychology, Université Laval, Quebec, QC, Canada Centre Québécois d’Excellence pour la Prévention et le Traitement du Jeu, Quebec, QC, Canada
Marc-André Roy
Affiliation:
Quebec Mental Health University Institute, Quebec, QC, Canada CERVO Brain Research Centre, Quebec, QC, Canada Faculty of Medicine, Université Laval, Quebec, QC, Canada
Marie-France Demers
Affiliation:
Faculty of Pharmacy, Université Laval, Quebec, QC, Canada Quebec Mental Health University Institute, Quebec, QC, Canada CERVO Brain Research Centre, Quebec, QC, Canada
*
Corresponding author: Olivier Corbeil; Email: [email protected]

Abstract

Background

High rates of psychiatric comorbidities have been found in people with problem gambling (PBG), including substance use, anxiety, and mood disorders. Psychotic disorders have received less attention, although this comorbidity is expected to have a significant impact on the course, consequences, and treatment of PBG. This review aimed to estimate the prevalence of psychotic disorders in PBG.

Methods

Medline (Ovid), EMBASE, PsycINFO (Ovid), CINAHL, CENTRAL, Web of Science, and ProQuest were searched on November 1, 2023, without language restrictions. Studies involving people with PBG and reporting the prevalence of schizophrenia spectrum and other psychotic disorders were included. Risk of bias was assessed using the Joanna Briggs Institute critical appraisal checklist for systematic reviews of prevalence data. The pooled prevalence of psychotic disorders was calculated using a random effects generalized linear mixed model and presented with forest plots.

Results

Of 1,271 records screened, 22 studies (n = 19,131) were included. The overall prevalence of psychotic disorders was 4.9% (95% CI, 3.6–6.5%, I2 = 88%). A lower prevalence was found in surveyed/recruited populations, compared with treatment-seeking individuals and register-based studies. No differences were found for factors such as treatment setting (inpatient/outpatient), diagnoses of psychotic disorders (schizophrenia only/other psychotic disorders), and assessment time frame (current/lifetime). The majority of included studies had a moderate risk of bias.

Conclusions

These findings highlight the relevance of screening problem gamblers for schizophrenia spectrum and other psychotic disorders, as well as any other comorbid mental health conditions, given the significant impact such comorbidities can have on the recovery process.

Keywords

gamblingmeta-analysisprevalencepsychosisschizophrenia
Type
Review/Meta-analysis
Information
European Psychiatry , Volume 67 , Issue 1 , 2024 , e56
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of European Psychiatric Association

Introduction

A growing consensus in both research and clinical practice emphasizes the importance of adopting a transdiagnostic and holistic approach toward the care of people with mental health disorders [Reference Dalgleish, Black, Johnston and Bevan1, Reference Fusar-Poli, Solmi, Brondino, Davies, Chae and Politi2]. This approach goes beyond the treatment of the underlying primary psychiatric disorder to address the biopsychosocial factors that are central to recovery, surpassing mere symptom management. In light of this, a better understanding of the co-occurrence of conditions that may exacerbate the challenges faced by individuals becomes imperative [Reference Corbeil, Bérubé, Artaud and Roy3Reference Roy, Demers and Achim7].

Within the diverse spectrum of mental health disorders, problem gambling (PBG) has received increasing attention, particularly given the growing availability of various forms of gambling, including its increasingly widespread integration into online video games [Reference Kim, Leslie, Stewart, King, Demetrovics and Andrade8Reference Spicer, Fullwood, Close, Nicklin, Lloyd and Lloyd10]. Since the publication of the fifth edition of the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) in 2013, gambling disorder, which can be considered a more severe form of PBG, has been officially recognized as a behavioral addiction [11]. This is due, in part, to growing evidence that gambling disorder and PBG share many similarities with substance addiction [Reference Petry, Blanco, Auriacombe, Borges, Bucholz and Crowley12]. Studies have also suggested a complex relationship between PBG and psychiatric comorbidities, including mood and anxiety disorders [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen13, Reference Lorains, Cowlishaw and Thomas14].

High rates of psychiatric comorbidity have been reported in people with PBG. A recent nationwide registry study found that 77% of patients with gambling disorder (n = 2,099) had at least one co-occurring psychiatric diagnosis, with anxiety, affective, and substance use disorders being the most prevalent [Reference Håkansson, Karlsson and Widinghoff15]. A previous meta-analysis focusing on treatment-seeking individuals with PBG mirrored these patterns, reporting prevalences of current and lifetime comorbid Axis I disorders at 75% [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen13]. Major depressive disorder (29.9, 95% confidence interval [CI], 20.5–41.3%, 17 studies), substance use disorders (22.2, 95% CI, 16.1–29.8%, 26 studies), and anxiety disorders (17.6, 95% CI, 10.8–27.3%, 15 studies) were identified as the most common current comorbid diagnoses [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen13]. In addition, the prevalence of comorbid personality disorders, particularly cluster B disorders, could be as high as 47.9% (95% CI, 29.8–66.7%, 15 studies) [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen16]. Importantly, these comorbid mental health disorders add on to the challenges people with PBG struggle with, further diminishing their quality of life and impeding their recovery, thereby highlighting the need for integrative treatment approaches [Reference Echeburúa, Amor and Gómez17].

While there is a relatively large body of research examining the comorbidity of PBG with various mental health conditions, psychotic disorders have received less attention. Yet, in addition to the significant burden in terms of reduced quality of life and premature mortality associated with psychotic disorders [Reference Charlson, Ferrari, Santomauro, Diminic, Stockings and Scott18Reference Solmi, Seitidis, Mavridis, Correll, Dragioti and Guimond20], there is evidence suggesting that their co-occurrence with PBG may lead to more severe gambling problems, including greater financial difficulties and an increased risk of homelessness and suicidality [Reference Aragay, Roca, Garcia, Marqueta, Guijarro and Delgado21Reference Yakovenko, Clark, Hodgins and Goghari27]. A recent meta-analysis published by our group, including 12 studies and 3,443 individuals, estimated the overall prevalence of PBG in people with psychotic disorders to be 8.7% [Reference Corbeil, Anderson, Béchard, Desmeules, Huot-Lavoie and Bachand28]; in comparison, the prevalence of PBG in the general population worldwide is estimated to be 1.3% [Reference Gabellini, Lucchini and Gattoni29]. Although not directly compared, this suggests that PBG may be more common in people with psychotic disorders than in the general population. Conversely, at the time of publication of the most recent meta-analysis in 2015, only five studies had provided data on the prevalence of psychotic disorders among problem gamblers [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen13]. In the latter, the prevalence of psychotic disorders was estimated to be 4.7% in a relatively small sample of only 989 individuals with PBG, while psychotic disorders are estimated to affect approximately 1% of the global population [Reference Solmi, Seitidis, Mavridis, Correll, Dragioti and Guimond20, Reference Moreno-Küstner, Martín and Pastor30]. Since then, a substantial number of larger observational studies have been conducted [Reference Stefanovics, Potenza, Szymkowiak and Tsai26, Reference Granero, Fernández-Aranda, del Pino-Gutierrez, Etxandi, Baenas and Gómez-Peña31, Reference Larsson and Håkansson32], which may allow a more accurate estimate of the prevalence of psychotic disorders in people with PBG. This may also enable the investigation of variations due to methodological and population factors, which have not yet been done. This investigation is important because the increased prevalence of PBG in people with psychotic disorders found in our recent meta-analysis does not necessarily indicate that the prevalence of psychotic disorders in people with PBG is also increased compared to the corresponding prevalence in the general population, as these are two distinct populations with different vulnerability profiles. Therefore, the aim of this systematic review and meta-analysis was to estimate the prevalence of schizophrenia spectrum and other psychotic disorders in individuals with PBG and to examine potential variations due to factors such as population and treatment setting.

Methods

The reporting of this study conforms to the standards of the Preferred Reporting Items for Systematic reviews and Meta-Analyses (PRISMA) 2020 statement [Reference Page, McKenzie, Bossuyt, Boutron, Hoffmann and Mulrow33]. This review was registered in the International Prospective Register of Systematic Reviews (PROSPERO) on June 30, 2023 (CRD42023428242).

Search strategy and selection criteria

A comprehensive search strategy was developed with a health sciences librarian, and the following databases were searched on November 1, 2023: Medline (Ovid), EMBASE, PsycINFO (Ovid), CINAHL, Cochrane Central Register of Controlled Trials (CENTRAL), Web of Science, and ProQuest Dissertation and Thesis. The search strategy included a combination of terms related to gambling (e.g., “gambling” or “betting”) and psychotic disorders (e.g., “psychosis” or “schizophrenia”) in both controlled vocabulary and free text (Supplementary Table 1). Relevant peer-reviewed studies were also identified through a manual review of the reference lists of included studies and Google Scholar. There were no language restrictions.

Studies were included if they met the following inclusion criteria: 1) included a sample of individuals (of any age) with PBG (including but not limited to gambling disorder, and as classified by the authors based on DSM/ICD criteria or other clinically relevant definition); 2) reported on the prevalence of schizophrenia spectrum and other psychotic disorders (as classified by the authors based on DSM/ICD criteria), including non-affective (i.e., schizophrenia spectrum disorders) and psychotic mood disorders (i.e., bipolar disorder and depression with psychotic features); 3) observational (i.e., cohort, nested case-control, cross-sectional) and experimental (i.e., randomized and non-randomized trials) designs. There were no other exclusion criteria. If multiple articles reported data from the same study sample, only the article reporting the most detailed results (i.e., in terms of the data extracted for this review) or with the largest sample size was retained for inclusion.

After removing duplicate records, the principal investigator (O.C.) and an undergraduate psychology student (E.A.) independently screened titles/abstracts and then assessed relevant full-text articles for inclusion. Covidence systematic review software facilitated the screening process [34]. Discrepancies in judgment were thoroughly discussed, and consensus was reached or resolved by a third reviewer (L. Béchard).

Data extraction

The extraction of data was carried out by the principal investigator (O.C.) and two undergraduate psychology students (E.A. and L. Bachand). The information extracted included: 1) study design (e.g., cross-sectional, cohort, case-control, prevalence/survey, randomized controlled trial); 2) country, further categorized according to the regional distribution established by the World Health Organization (WHO), including Africa, Eastern Mediterranean, Europe, Americas, South-East Asia, and Western Pacific, as well as according to the World Bank income classifications for 2022 (i.e., high-income or low- and middle-income); 3) age and sex or gender criteria for inclusion; 4) mean age of the population; 5) proportion of men and women; 6) proportion of White and African/Afro-American (as these ethnicities were expected to be the most represented in the studies conducted to date, based on a previous review [Reference Yakovenko and Hodgins35]); 7) type of recruitment (i.e., treatment-seeking individuals, surveyed/recruited, register-based, other); 8) treatment setting (i.e., inpatient, outpatient, mixed); 9) sample size; 10) psychotic disorders diagnoses (i.e., schizophrenia only, schizophrenia spectrum disorders, or any psychotic disorders including psychotic mood disorders); 11) assessment methods (i.e., structured interview, medical diagnosis, other) and diagnostic criteria; 12) assessment time frame (i.e., current or lifetime). The primary outcome measured was the total count of individuals diagnosed with psychotic disorders. Study authors were contacted in cases of missing data. Any disagreements that arose were thoroughly discussed and resolved through consensus or resolved by a third reviewer (L. Béchard).

Study quality

The evaluation of the risk of bias in the included studies was carried out by the principal investigator (O.C.) and two undergraduate psychology students (E.A., L. Bachand) using the Joanna Briggs Institute (JBI) critical appraisal checklist for systematic reviews of prevalence data [Reference Munn, Moola, Lisy, Riitano and Tufanaru36]. This nine-item checklist is recognized as the most suitable tool for assessing the methodological quality of prevalence studies [Reference Migliavaca, Stein, Colpani, Munn and Falavigna37]. The adequacy of the study sample was evaluated based on a hypothesized prevalence of schizophrenia spectrum and other psychotic disorders of 5% in people with PBG and a 95% confidence level [Reference Naing, Winn and Rusli38]. Each study was assigned a quality score ranging from 0 to 9, with 1 point allocated for meeting each criterion. An overall risk of bias was then determined and categorized as high (0–3), moderate (4–6), or low (7–9) risk [Reference Munn, Moola, Lisy, Riitano and Tufanaru36]. These steps were facilitated by the Covidence systematic review software [34]. In instances of disagreements, consensus was reached through comprehensive discussions or resolved by a third reviewer (L. Béchard).

Statistical analysis

The main characteristics of each study were summarized using descriptive statistics. The prevalence was described using a box plot and outliers identified in this plot were removed in sensitivity analyses. The overall pooled prevalence estimate of schizophrenia spectrum and other psychotic disorders and its corresponding confidence interval (CI) were calculated by pooling the raw prevalence from each included study using a random effects generalized linear mixed model [Reference Lin and Chu39]. Further sensitivity analyses were performed on the overall pooled prevalence in random effects models using the inverse variance method and different transformations, namely the Freeman–Tukey double-arcsine transformation and the logit transformation. The presence of heterogeneity was evaluated using a χ 2 test, the between-study variance with τ 2, and the portion of total variation across studies due to heterogeneity with the I 2 statistic. I 2 values ranging from 0 to 25%, 26 to 50%, 51 to 75%, and 76 to 100% indicated low, moderate, substantial, and considerable heterogeneity, respectively [Reference Higgins, Thompson, Deeks and Altman40]. To explore potential sources of heterogeneity, subgroup meta-analyses were conducted for predetermined categorical moderators, including study publication year (before/after classification of gambling disorder as a behavioral addiction in the DSM-5, i.e., 2013), geographic region, country income, type of recruitment, treatment setting, psychotic disorder diagnoses, assessment method and time frame, and risk of bias. The results are visually presented through forest plots. All reported CIs represent the 95% range. All statistical analyses were conducted with R software, version 4.3.0 (R Project for Statistical Computing), using the meta and metafor packages [41, Reference Viechtbauer42]. Analyses were performed by the principal investigator and a biostatician (O.C. and P.H.C.).

Results

The electronic search yielded a total of 1,271 unique records after the removal of duplicates. Eligibility was assessed for 172 full-text articles, of which 22 non-overlapping studies met the predefined inclusion criteria (Figure 1) [Reference Shek, Chan and Wong25, Reference Stefanovics, Potenza, Szymkowiak and Tsai26, Reference Granero, Fernández-Aranda, del Pino-Gutierrez, Etxandi, Baenas and Gómez-Peña31, Reference Larsson and Håkansson32, Reference Bellaire and Caspari43Reference Yamada, Miyashita, Hashimoto, Hironaka, Takada and Shigeta60].

Figure 1. Flow chart of reviewed articles. Adapted from Page et al. [33].

Study characteristics

All 22 studies were included in the meta-analysis, collectively encompassing data from 19,131 individuals with PBG. As shown in Table 1, 12 studies (55%, n = 9,884) were conducted in the Americas, six (27%, n = 8,599) in Europe, and four (18%, n = 648) in the Western Pacific. All but two studies were carried out in high-income countries. Most of the included studies were cross-sectional (8/22; 36%) and cohort studies (7/22; 32%). There were 14 studies (64%, n = 6,819) conducted with treatment-seeking problem gamblers, of which six were carried out in outpatient settings, five in inpatient settings, and three in mixed settings. When explicitly documented, psychotic disorders reported were mostly schizophrenia spectrum disorders (13/22; 59%), while five studies focused only on schizophrenia and two included psychotic mood disorders (Table 2). The risk of bias was assessed as low in five studies (23%), moderate in 16 (73%), and high in one study (5%); the average score was 5.4 (range, 3–8; Supplementary Table 2).

Table 1. Characteristics of the included studies

Abbreviations: NA, not applicable.

a United States Armed Forces Veterans.

b Fraud offenders.

Table 2. Psychotic disorders assessment in the included studies

Abbreviations: DSM, Diagnostic and Statistical Manual of Mental Disorders; ICD, International Classification of Diseases; NS, not specified; SSD, schizophrenia spectrum disorders.

a Schizophrenia spectrum and other psychotic disorders, including psychotic mood disorders.

b Research diagnostic criteria.

c Computerised version of the Composite International Diagnostic Interview (CIDI-Auto).

The mean age of the populations studied ranged from 33.7 to 53.6 years (Supplementary Table 3), with six studies explicitly stating that only individuals over 18 years of age were included (over 17 years in one study). The proportion of women was 47% in one study, while the proportion of men ranged from 59 to 100% in all the other included studies (over 90% in 11 studies). Of the eight studies that reported ethnicity, the proportion of individuals of White ethnicity ranged from 63 to 97% and that of African/Afro-Americans from 0 to 31%. Three studies were conducted in Asia, of which only one explicitly reported that only Asians were included. The median prevalence of schizophrenia spectrum and other psychotic disorders reported in the included studies was 4.4% (range = 0.0–16.7%, interquartile range = 2.6–6.4%), and two studies were identified as outliers [Reference Dougherty, Staples, Maclean, Machart, Westmore and Nielssen46, Reference Grall-Bronnec, Bouju, Landreat-Guillou and Venisse48], both reporting prevalences of 16.7% (Figure 2).

Figure 2. Box plot of the prevalence of any psychotic disorders in people with problem gambling.

Pooled and stratified prevalence of schizophrenia spectrum and other psychotic disorders

The overall pooled prevalence of schizophrenia spectrum and other psychotic disorders in people with PBG was 4.9% (95% CI, 3.6–6.5%, I 2 = 88%), with considerable heterogeneity. The results of the subgroup analyses are shown in Table 3. There was a subgroup difference (P = 0.01) found in the prevalence according to the type of recruitment used in the studies; the prevalence of schizophrenia spectrum and other psychotic disorders was 2.1% (95% CI, 0.8–5.7%, I 2 = 0%) in surveyed/recruited populations, 4.5% (3.3–6.1%, I 2 = 73%) in individuals seeking treatment for PBG, and 7.7% (5.5–10.7%, I 2 = 97%) in register-based studies (Figure 3). Differences in publication year, geographic region, country income, treatment setting, psychotic disorder diagnoses included, method of psychotic disorder assessment, time frame, and risk of bias did not significantly contribute to the heterogeneity found in the overall prevalence of psychotic disorders (Table 3 and Supplementary Figures 1–8). In particular, the prevalence of schizophrenia only was 4.6% (95% CI, 2.5–8.5%, I 2 = 97%), of schizophrenia spectrum disorders 4.9% (95% CI, 3.5–6.8%, I 2 = 55%), and of any psychotic disorders including psychotic mood disorders 6.7% (95% CI, 1.9–20.9%, I 2 = 93%), but no significant differences emerged (P = 0.86). Similarly, the current and lifetime prevalences of schizophrenia spectrum and other psychotic disorders were not significantly different (5.6% [95% CI, 3.6–8.7%, I 2 = 75%] and 4.5% [95% CI, 3.5–5.7%, I 2 = 53%], respectively, P = 0.39).

Table 3. Results of moderator analyses for the prevalence of any psychotic disorders in people with problem gambling

a For subgroup differences (random effects).

b Other type of recruitment (i.e., fraud offenders chart review) in 1 study.

c In studies conducted among treatment-seeking patients (14 studies).

d Not specified for 2 studies.

e Computer-assisted version of the Composite International Diagnostic Interview (CIDI-Auto) for 1 study.

f Not specified for 5 studies.

g High risk of bias for 1 study.

Figure 3. Forest plot of the pooled estimated prevalence of any psychotic disorders in people with problem gambling according to type of recruitment. Abbreviations: CI, confidence interval.

Note: The overall pooled estimate is represented by the vertical dashed line.

Sensitivity analyses

Removal of the two studies identified as outliers resulted in an overall pooled prevalence of schizophrenia spectrum and other psychotic disorders of 4.5% (95% CI, 3.3–6.0%, I 2 = 89%; Supplementary Figure 9). Further sensitivity analyses were performed using the inverse variance method. In a random effects model using the Freeman–Tukey double-arcsine transformation, the pooled prevalence of schizophrenia spectrum and other psychotic disorders was 4.8% (95% CI, 3.4–6.4%, I 2 = 89%; Supplementary Figure 10), with considerable heterogeneity. The overall prevalence using a random effects model and the logit transformation was 5.5% (95% CI, 4.2–7.2%, I 2 = 89%; Supplementary Figure 11), with considerable heterogeneity. The latter method resulted in the exclusion of one study, which reported a 0% prevalence of schizophrenia spectrum and other psychotic disorders in 105 problem gamblers [Reference Grant and Potenza49].

Discussion

This study identified an estimated prevalence of psychotic disorders of 4.9% among 19,131 individuals with PBG from a variety of countries (from the Americas, Europe, and Western Pacific regions), different types of recruitment (treatment-seeking individuals, surveys, population-wide registers), and treatment settings (inpatients, outpatients, mixed). Of the factors examined, only the type of recruitment significantly contributed to the heterogeneity found. Noteworthy, the prevalence of psychotic disorders among individuals seeking treatment for PBG, who may be more representative of people encountered in clinical settings, was 4.5%; this is consistent with both the overall estimated prevalence and that of 4.7% found in a previous review [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen13], albeit in a total sample almost 20 times larger.

Although the prevalence of psychotic disorders in people with PBG may seem lower than that reported for other conditions, such as anxiety and mood disorders, their relative prevalence in the general population must be considered [Reference Dowling, Cowlishaw, Jackson, Merkouris, Francis and Christensen16]. A recent meta-analysis estimated the global lifetime prevalence of schizophrenia spectrum and other psychotic disorders in the general population to be 1.0% (95% CI, 0.7–1.2%, 28 studies) [Reference Moreno-Küstner, Martín and Pastor30], and nearly 24 million people worldwide were estimated to be affected by schizophrenia in 2019 [Reference Solmi, Seitidis, Mavridis, Correll, Dragioti and Guimond20]. In contrast, global lifetime prevalence estimates for mood and anxiety disorders have been reported to be 9.6% (95% CI, 8.5–10.7%, 83 studies) and 12.9% (95% CI, 11.3–14.7%, 70 studies), respectively [Reference Steel, Marnane, Iranpour, Chey, Jackson and Patel61]. Furthermore, although the global prevalence of schizophrenia is relatively low, it is amongst the most invalidating disorders worldwide in terms of quality of life, disability, mortality, and societal costs, which is especially concerning in low- and middle-income countries [Reference Charlson, Ferrari, Santomauro, Diminic, Stockings and Scott18Reference Solmi, Seitidis, Mavridis, Correll, Dragioti and Guimond20]. In addition to evidence suggesting that psychotic disorders in PBG may lead to more severe gambling problems and increased suicidality [Reference Aragay, Roca, Garcia, Marqueta, Guijarro and Delgado21Reference Yakovenko, Clark, Hodgins and Goghari27], PBG in psychotic disorders may, in turn, be associated with symptom exacerbation, greater symptom severity and psychological distress, and an increased likelihood of suffering from other comorbid mental health disorders, particularly substance abuse [Reference Granero, Fernández-Aranda, del Pino-Gutierrez, Etxandi, Baenas and Gómez-Peña31, Reference Kim, Cassetta, Hodgins, Tomfohr-Madsen, McGrath and Tavares53, Reference Winslow, Subramaniam, Qiu and Lee59, Reference Fortgang, Hoff and Potenza62, Reference Haydock, Cowlishaw, Harvey and Castle63]. Taken together, these elements warrant greater attention to this comorbidity. To this end, the finding of a lower prevalence of schizophrenia spectrum and other psychotic disorders in surveyed or recruited samples of individuals from the general population suggests that studies conducted in such settings may be less well suited to providing a comprehensive understanding of this comorbidity among problem gamblers.

The prevalence of schizophrenia spectrum and other psychotic disorders in people with PBG estimated in this study (4.9%) was not directly compared with that reported in the general population (1%) [Reference Solmi, Seitidis, Mavridis, Correll, Dragioti and Guimond20, Reference Moreno-Küstner, Martín and Pastor30], but it suggests that it may be increased in the former group. Similarly, the results of our recently published meta-analysis suggested an increased prevalence of PBG in people with psychotic disorders (8.7%) compared with that estimated in the general population (1.3%) [Reference Corbeil, Anderson, Béchard, Desmeules, Huot-Lavoie and Bachand28, Reference Gabellini, Lucchini and Gattoni29], although these were also not directly compared. While these two findings suggest that this comorbidity may be relatively common, they do not directly allow us to determine whether people with PBG are less or more likely to have comorbid psychotic disorders than people with psychotic disorders are to have comorbid PBG. In particular, the majority of studies included in each review were cross-sectional in design, limiting the possibility of confirming which of the two conditions preceded the other. While the available literature does not suggest that psychotic disorders per se are the cause of PBG, and vice versa, this comorbidity may be better explained by common risk factors and transition facilitators, including both at the genetic level (e.g., a polygenic risk score for schizophrenia has been associated with increased odds of disordered gambling [Reference Piasecki, Gizer and Slutske64]) and at the personality level (e.g., novelty seeking, reward dependence, and self-transcendence have been found to be central features in patients with schizophrenia and PBG [Reference Granero, Fernández-Aranda, Demetrovics, Lara-Huallipe, Morón-Fernández and Jiménez-Murcia65]). Although more research is needed to better understand the complex mechanisms involved in the development of this comorbidity, in the meantime, the results of this review inform stakeholders about a clinically relevant issue that needs to be considered in a holistic and recovery-oriented treatment approach.

The included studies were conducted with a wide range of populations, including but not limited to people who have sought treatment for PBG, and from multiple countries and different clinical settings; therefore, the estimated prevalence is more likely to reflect a broader range of the population as a whole, although there are caveats that are described below. This meta-analysis was also carried out according to the highest standards of systematic review and meta-analysis methodology, including pre-planned analyses and a pre-registered study protocol. While the reliability and precision of the results are highly contingent on the quality of the included studies, the risk of bias assessment conducted in this review indicated that the majority of the included studies had a moderate to low risk of bias, which may suggest that the prevalence calculated in this meta-analysis can be considered a good estimate of the true prevalence of schizophrenia spectrum and other psychotic disorders in this population. In this respect, the hypothesis that this prevalence is an underestimate rather than an overestimate is more plausible, as people with a severe mental disorder such as schizophrenia may be less likely to undergo screening for this comorbidity and to seek help for comorbid PBG [Reference Corrigan, Druss and Perlick66Reference Vanasse, Courteau, Courteau, Roy, Stip and Fleury70].

Of note, four studies included in this review reported prevalences that differed more widely from the estimated overall pooled prevalence. These included two outliers, both of which reported a prevalence of psychotic disorders of 16.7% [Reference Dougherty, Staples, Maclean, Machart, Westmore and Nielssen46, Reference Grall-Bronnec, Bouju, Landreat-Guillou and Venisse48]. Dougherty et al. (2021) examined a sample of 48 individuals who had committed fraud offenses to fund gambling in a study that was judged to be at high risk of bias, mainly due to the lack of a validated method for identifying PBG [Reference Dougherty, Staples, Maclean, Machart, Westmore and Nielssen46]. Grall-Bronnec et al. (2010), although in a well-conducted study with a low risk of bias, included a limited sample size of 24 problem gamblers, resulting in a very wide confidence interval [Reference Grall-Bronnec, Bouju, Landreat-Guillou and Venisse48]. Perhaps more interesting are the studies by Edens and Rosenheck (2012) and Ladouceur et al. (2006), which both found a prevalence of psychotic disorders of 11.6% [Reference Edens and Rosenheck47, Reference Ladouceur, Sylvain, Sévigny, Poirier, Brisson and Dias54]. The first study was conducted in a population-based registry that included data from 1,102,846 United States Armed Forces Veterans who used specialty mental health services in 2009 [Reference Edens and Rosenheck47]. The prevalence of psychotic disorders found among the 2,283 individuals with a diagnosis of pathological gambling is, therefore, likely to be overestimated due to the base cohort from which these problem gamblers were identified. This would also help to explain the remaining heterogeneity found in the subgroup of studies conducted using population-based registries, as the other two studies with a similar type of recruitment did not use registries specific to mental health users [Reference Stefanovics, Potenza, Szymkowiak and Tsai26, Reference Larsson and Håkansson32]. In the second study, Ladouceur et al. (2006) examined the prevalence of mental health disorders in a total sample of 233 individuals with a DSM-IV diagnosis of pathological gambling who sought specialized treatment for PBG and voluntarily chose the type of treatment they would receive, i.e., inpatient or outpatient [Reference Ladouceur, Sylvain, Sévigny, Poirier, Brisson and Dias54]. Interestingly, the prevalence of psychotic disorders differed by type of treatment setting: 4.0% (4/99) among outpatients and 17.2% (23/134) among inpatients, with the most significant difference being for schizoaffective disorders (1.0% versus 9.7%, P < 0.01). Again, this may indicate an increased likelihood of comorbid mental health disorders in the base population rather than due to the presence of PBG alone.

The results obtained must also be interpreted considering a few limitations. First, there was considerable heterogeneity in the prevalence estimates obtained in this meta-analysis that could not be explained by the various factors examined, including geographic region, treatment setting, and assessment methods. In particular, and as discussed above, some studies may have had a more significant impact on the overall heterogeneity found due to unique study population (i.e., United States Armed Forces Veterans who had used mental health specialty services) [Reference Edens and Rosenheck47] or study design (i.e., experimental study) [Reference Ladouceur, Sylvain, Sévigny, Poirier, Brisson and Dias54]. Additionally, the limited number of studies in most of the subgroups examined may have prevented the ability to detect significant differences. The prevalence of schizophrenia spectrum and other psychotic disorders in people with PBG may also be expected to vary according to factors not measured in this review, including cultural and social factors. As speculated above, it is possible that people with both a psychotic disorder and PBG are less likely to seek treatment. While the results cannot confirm or refute this hypothesis, the prevalence of schizophrenia spectrum and other psychotic disorders was lowest in surveyed/recruited samples of individuals, followed by treatment-seeking problem gamblers and registry-based populations, suggesting that prevalence may indeed be influenced by the type of recruitment that is used, as well as the base population in which it is measured, as previously discussed.

Second, despite a comprehensive search strategy, there remains a small possibility that some studies reporting on aggregate mental health conditions in individuals with PBG may have been missed, although efforts were made to limit this by manually searching the reference lists of all included studies. Similarly, publication bias is not readily assessable in reviews of prevalence studies [Reference Barker, Migliavaca, Stein, Colpani, Falavigna and Aromataris71], so its presence cannot be excluded, although the fact that the risk of bias of the included studies did not have a significant effect on the results, and that both smaller and larger studies reported very low and high prevalence estimates, may indicate only a small effect.

Third, assessment of PBG severity was rare in the included studies, so this information could not be extracted, and the nature and extent of its impact on psychotic disorders and vice versa could not be explored. Likewise, medication use was rarely, if ever, documented in the included studies, again preventing exploration of potential associations with PBG that have been described but remain to be better studied, such as the use of third-generation antipsychotics (i.e., partial dopamine agonists) [Reference Williams, Lee, Ewah and Neelam72]. Indeed, although mostly documented with the use of aripiprazole [Reference Corbeil, Corbeil, Dorval, Carmichael, Giroux and Jacques4, Reference Akbari, Jamshidi, Sheikhi, Alijani, Kafshchi and Taylor73Reference Wolfschlag and Håkansson79], the occurrence of PBG and other impulse control disorders, such as hypersexuality, has also been reported with the use of brexpiprazole and cariprazine [Reference Zazu, Morera-Herreras, Garcia, Aguirre and Lertxundi80, Reference Fusaroli, Raschi, Giunchi, Menchetti, Rimondini Giorgini and De Ponti81], suggesting that their partial dopamine agonist activity may be involved [Reference Wolfschlag and Håkansson82]. More specifically, such behavioral adverse events have previously been documented with the use of dopamine agonist drugs in the treatment of Parkinson’s disease, and agonism at central dopamine D3 receptors, in particular, has been suggested as a potential key mediator in this relationship [Reference Seeman83]. However, the evidence for an association between third-generation antipsychotics and PBG is mostly limited to case series and analyses of pharmacovigilance databases, which precludes any firm conclusions about causality.

Finally, the results obtained, although from a wide range of geographic regions, types of recruitment, and treatment settings, were still derived from samples composed mainly of White men aged 35 to 50 years living in high-income countries. Further studies with more vulnerable and marginalized populations, particularly in low- and middle-income countries, are therefore needed to gain a better understanding of the complex association between PBG and psychotic disorders, and to explore the consequences for the individual and the implications for preventive and therapeutic approaches.

Implications

Although relatively infrequent, our findings highlight the relevance of screening problem gamblers for schizophrenia spectrum and other psychotic disorders, as well as any other comorbid mental health conditions, given the important impact such comorbidities can have on the person. When comorbid with psychotic disorders, a holistic and global approach is needed that addresses not only PBG, but also its bidirectional relationship with psychosis. While more research is needed to better understand how this comorbidity varies according to individual and socioeconomic factors, efforts should be made to sensitize clinicians and improve access to health care for these individuals.

Supplementary material

The supplementary material for this article can be found at http://doi.org/10.1192/j.eurpsy.2024.1777.

Data availability statement

Template data collection forms, raw data extracted from included studies and used for all analyses are available from the corresponding author O.C. upon reasonable request.

Acknowledgements

None.

Financial support

This study received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

Competing interest

O.C. is currently receiving a fellowship award from the Canadian Institutes of Health Research (#202210MFE-491926-64860). L.Béchard is currently receiving a doctoral training scholarship from the Fonds de recherche du Québec – Santé (#331332). M.S. has received honoraria/has been a consultant for AbbVie, Angelini, Lundbeck, Otsuka. M.A.R. has received unrestricted grants from Mylan Canada and Otsuka-Lundbeck Alliance Canada. He has served on advisory boards for AbbVie, Janssen, and Otsuka-Lundbeck Alliance. He has also been a lecturer for AbbVie and Janssen Canada. M.F.D. reports consulting fees from AbbVie. She has also served on advisory boards and been a lecturer for AbbVie and Otsuka-Lundbeck Alliance Canada. All other authors declare no competing interests.

References

Dalgleish, T, Black, M, Johnston, D, Bevan, A. Transdiagnostic approaches to mental health problems: current status and future directions. J Consult Clin Psychol. 2020;88(3):179–95.Google Scholar
Fusar-Poli, P, Solmi, M, Brondino, N, Davies, C, Chae, C, Politi, P, et al. Transdiagnostic psychiatry: a systematic review. World Psychiatry. 2019;18(2):192207.Google Scholar
Corbeil, O, Bérubé, F-A, Artaud, L, Roy, M-A. [Detecting and treating comorbid disorders in first-episode psychosis: a lever for recovery]. Sante Ment Que. 2021;46(2):307–30.Google Scholar
Corbeil, O, Corbeil, S, Dorval, M, Carmichael, P-H, Giroux, I, Jacques, C, et al. Problem gambling associated with aripiprazole: a nested case-control study in a first-episode psychosis program. CNS Drugs. 2021;35(4):461–8.Google Scholar
Huot-Lavoie, M, Gabriel-Courval, M, Béchard, L, Corbeil, O, Brodeur, S, Massé, C, et al. Gaming disorder and psychotic disorders: a scoping review. Psychopathology. 2023;56(4):315–23.Google Scholar
Roy, MA, Achim, AM, Vallières, C, Labbé, A, Mérette, C, Maziade, M, et al. Comorbidity between anxiety disorders and recent-onset psychotic disorders. Schizophr Res. 2015;166(1–3):353–4.Google Scholar
Roy, MA, Demers, MF, Achim, AM. Social anxiety disorder in schizophrenia: a neglected, yet potentially important comorbidity. J Psychiatry Neurosci. 2018;43(4):287–8.Google Scholar
Kim, HS, Leslie, RD, Stewart, SH, King, DL, Demetrovics, Z, Andrade, ALM, et al. A scoping review of the association between loot boxes, esports, skin betting, and token wagering with gambling and video gaming behaviors. J Behav Addict. 2023;12(2):309–51.Google Scholar
Kristiansen, S, Severin, MC. Loot box engagement and problem gambling among adolescent gamers: findings from a national survey. Addict Behav. 2020;103:106254.Google Scholar
Spicer, SG, Fullwood, C, Close, J, Nicklin, LL, Lloyd, J, Lloyd, H. Loot boxes and problem gambling: investigating the “gateway hypothesis”. Addict Behav. 2022;131:107327.Google Scholar
American Psychiatric Association. Diagnostic and statistical manual of mental disorders. 5th ed. Arlington, VA: American Psychiatric Publishing; 2013, p. 1947.Google Scholar
Petry, NM, Blanco, C, Auriacombe, M, Borges, G, Bucholz, K, Crowley, TJ, et al. An overview of and rationale for changes proposed for pathological gambling in DSM-5. J Gambl Stud. 2014;30(2):493502.Google Scholar
Dowling, NA, Cowlishaw, S, Jackson, AC, Merkouris, SS, Francis, KL, Christensen, DR. Prevalence of psychiatric co-morbidity in treatment-seeking problem gamblers: a systematic review and meta-analysis. Aust N Z J Psychiatry. 2015;49(6):519–39.Google Scholar
Lorains, FK, Cowlishaw, S, Thomas, SA. Prevalence of comorbid disorders in problem and pathological gambling: systematic review and meta-analysis of population surveys. Addiction. 2011;106(3):490–8.Google Scholar
Håkansson, A, Karlsson, A, Widinghoff, C. Primary and secondary diagnoses of gambling disorder and psychiatric comorbidity in the Swedish health care system - A nationwide register study. Front Psychiatry. 2018;9:426.Google Scholar
Dowling, NA, Cowlishaw, S, Jackson, AC, Merkouris, SS, Francis, KL, Christensen, DR. The prevalence of comorbid personality disorders in treatment-seeking problem gamblers: a systematic review and meta-analysis. J Pers Disord. 2015;29(6):735–54.Google Scholar
Echeburúa, E, Amor, PJ, Gómez, M. Current psychological therapeutic approaches for gambling disorder with psychiatric comorbidities: a narrative review. Salud Mental. 2017;40(6):299305.Google Scholar
Charlson, FJ, Ferrari, AJ, Santomauro, DF, Diminic, S, Stockings, E, Scott, JG, et al. Global epidemiology and burden of schizophrenia: findings from the global burden of disease study 2016. Schizophr Bull. 2018;44(6):1195–203.Google Scholar
GBD 2019 Mental Disorders Collaborators. Global, regional, and national burden of 12 mental disorders in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet Psychiatry. 2022;9(2):137–50.Google Scholar
Solmi, M, Seitidis, G, Mavridis, D, Correll, CU, Dragioti, E, Guimond, S, et al. Incidence, prevalence, and global burden of schizophrenia - data, with critical appraisal, from the Global Burden of Disease (GBD) 2019. Mol Psychiatry. 2023.Google Scholar
Aragay, N, Roca, A, Garcia, B, Marqueta, C, Guijarro, S, Delgado, L, et al. Pathological gambling in a psychiatric sample. Compr Psychiatry. 2012;53(1):914.Google Scholar
Cassetta, BD, Kim, HS, Hodgins, DC, McGrath, DS, Tomfohr-Madsen, LM, Tavares, H. Disordered gambling and psychosis: Prevalence and clinical correlates. Schizophrenia Research. 2018;192:463–4.Google Scholar
Lubman, D, Manning, V, Dowling, N, Rodda, S, Lee, S, Garde, E, et al. Problem gambling in people seeking treatment for mental illness. Melbourne, VIC: Victorian Responsible Gambling Foundation; 2017, p. 1240.Google Scholar
Machart, T, Cooper, L, Jones, N, Nielssen, A, Doughty, E, Staples, L, et al. Problem gambling among homeless clinic attenders. Australas Psychiatry. 2020;28(1):91–4.Google Scholar
Shek, DTL, Chan, EML, Wong, RHY. Associations between pathological gambling and psychiatric comorbidity among help-seeking populations in Hong Kong. Int J Child Health Hum Dev. 2013;6(1):125–44.Google Scholar
Stefanovics, EA, Potenza, MN, Szymkowiak, D, Tsai, J. Chronically homeless veterans with gambling disorder: epidemiology, clinical correlates, and traumatic experiences. J Psychiatr Res. 2023;164:118–24.Google Scholar
Yakovenko, I, Clark, CM, Hodgins, DC, Goghari, VM. A qualitative analysis of the effects of a comorbid disordered gambling diagnosis with schizophrenia. Schizophr Res. 2016;171(1–3):50–5.Google Scholar
Corbeil, O, Anderson, É, Béchard, L, Desmeules, C, Huot-Lavoie, M, Bachand, L, et al. Problem gambling in psychotic disorders: a systematic review and meta-analysis of prevalence. Acta Psychiatr Scand. 2024;149(6):445–57.Google Scholar
Gabellini, E, Lucchini, F, Gattoni, ME. Prevalence of problem gambling: a meta-analysis of recent empirical research (2016-2022). J Gambl Stud. 2023;39(3):1027–57.Google Scholar
Moreno-Küstner, B, Martín, C, Pastor, L. Prevalence of psychotic disorders and its association with methodological issues. A systematic review and meta-analyses. PLoS One. 2018;13(4):e0195687.Google Scholar
Granero, R, Fernández-Aranda, F, del Pino-Gutierrez, A, Etxandi, M, Baenas, I, Gómez-Peña, M, et al. The prevalence and features of schizophrenia among individuals with gambling disorder. J Psychiatr Res. 2021;136:374–83.Google Scholar
Larsson, L, Håkansson, A. Mental illness and socio-economic situation of women and men diagnosed with gambling disorder (GD) in Sweden - nationwide case-control study. PLoS One. 2022;17(10):e0274064.Google Scholar
Page, MJ, McKenzie, JE, Bossuyt, PM, Boutron, I, Hoffmann, TC, Mulrow, CD, et al. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ. 2021;372:n71.Google Scholar
Veritas Health Innovation. Covidence systematic review software. 2024. Retrieved from www.covidence.orgGoogle Scholar
Yakovenko, I, Hodgins, DC. A scoping review of co-morbidity in individuals with disordered gambling. Int Gambl Stud. 2018;18(1):143–72.Google Scholar
Munn, Z, Moola, S, Lisy, K, Riitano, D, Tufanaru, C. Methodological guidance for systematic reviews of observational epidemiological studies reporting prevalence and cumulative incidence data. Int J Evid Based Healthc. 2015;13(3):147–53.Google Scholar
Migliavaca, CB, Stein, C, Colpani, V, Munn, Z, Falavigna, M. Quality assessment of prevalence studies: a systematic review. J Clin Epidemiol. 2020;127:5968.Google Scholar
Naing, L, Winn, T, Rusli, BN. Practical issues in calculating the sample size for prevalence studies. Archives of Orofacial Sciences. 2006;1:914.Google Scholar
Lin, L, Chu, H. Meta-analysis of proportions using generalized linear mixed models. Epidemiology. 2020;31(5):713–7.Google Scholar
Higgins, JP, Thompson, SG, Deeks, JJ, Altman, DG. Measuring inconsistency in meta-analyses. BMJ. 2003;327(7414):557–60.Google Scholar
R Project for Statistical Computing. R: a language and environment for statistical computing. 2024. Retrieved from https://www.R-project.org/Google Scholar
Viechtbauer, W. Conducting meta-analyses in R with the metafor package. J Stat Softw. 2010;36(3):148.Google Scholar
Bellaire, W, Caspari, D. Diagnosis and therapy of male gamblers in a university psychiatric hospital. J Gambl Stud. 1992;8(2):143–50.Google Scholar
Black, DW, Moyer, T. Clinical features and psychiatric comorbidity of subjects with pathological gambling behavior. Psychiatr Serv. 1998;49(11):1434–9.Google Scholar
Cunningham-Williams, RM, Cottler, LB, Compton 3rd WM, Spitznagel, EL. Taking chances: problem gamblers and mental health disorders -- results from the St. Louis Epidemiologic Catchment Area Study. Am J Public Health. 1998;88(7):1093–6.Google Scholar
Dougherty, E, Staples, L, Maclean, L, Machart, T, Westmore, B, Nielssen, O. A comparison of fraud to fund gambling with fraud for other reasons. Psychiatr Psychol Law. 2020;28(3):408–17.Google Scholar
Edens, EL, Rosenheck, RA. Rates and correlates of pathological gambling among VA mental health service users. J Gambl Stud. 2012;28(1):111.Google Scholar
Grall-Bronnec, M, Bouju, G, Landreat-Guillou, M, Venisse, JL. [Socio-demographic and clinical assessment, and trajectory of a sample of French pathological gamblers]. Encephale. 2010;36(6):452–60.Google Scholar
Grant, JE, Potenza, MN. Sexual orientation of men with pathological gambling: prevalence and psychiatric comorbidity in a treatment-seeking sample. Compr Psychiatry. 2006;47(6):515–8.Google Scholar
Grubbs, JB, Chapman, H, Milner, LA, Floyd, CG, Kraus, SW. Comorbid psychiatric diagnoses and gaming preferences in US armed forces veterans receiving inpatient treatment for gambling disorder. Addict Behav. 2023;147:107840.Google Scholar
Jiménez-Murcia, S, Granero Pérez, R, Fernández-Aranda, F, Álvarez Moya, E, Aymamí, MN, Gómez-Peña, M, et al. Comorbidity of pathological gambling: clinical variables, personality and response to treatment. Rev Psiquiatr Salud Ment. 2009;2(4):178–89.Google Scholar
Kausch, O. Suicide attempts among veterans seeking treatment for pathological gambling. J Clin Psychiatry. 2003;64(9):1031–8.Google Scholar
Kim, HS, Cassetta, BD, Hodgins, DC, Tomfohr-Madsen, LM, McGrath, DS, Tavares, H. Assessing the relationship between disordered gamblers with psychosis and increased gambling severity: the mediating role of impulsivity. Can J Psychiatry. 2018;63(6):370–7.Google Scholar
Ladouceur, R, Sylvain, C, Sévigny, S, Poirier, L, Brisson, L, Dias, C, et al. Pathological gamblers: inpatients’ versus outpatients’ characteristics. J Gambl Stud. 2006;22(4):443–50.Google Scholar
McCormick, RA, Russo, AM, Ramirez, LE, Taber, JI. Affective disorders among pathological gamblers seeking treatment. Am J Psychiatry. 1984;141(2):215–8.Google Scholar
Pavarin, RM, Fioritti, A, Marani, S, Gambini, D, Turino, E, Piazza, A. Who are the subjects with gambling-related problems requiring treatment? A study in northern Italy. J Clin Med. 2018;7(4):80.Google Scholar
Specker, SM, Carlson, GA, Edmonson, KM, Johnson, PE, Marcotte, M. Psychopathology in pathological gamblers seeking treatment. J Gambl Stud. 1996;12(1):6781.Google Scholar
Taber, JI, McCormick, RA, Russo, AM, Adkins, BJ, Ramirez, LF. Follow-up of pathological gamblers after treatment. Am J Psychiatry. 1987;144(6):757–61.Google Scholar
Winslow, M, Subramaniam, M, Qiu, S, Lee, A. Socio-demographic profile and psychiatric comorbidity of subjects with pathological gambling. Ann Acad Med Singapore. 2010;39(2):122–8.Google Scholar
Yamada, R, Miyashita, K, Hashimoto, TM, Hironaka, N, Takada, K, Shigeta, M, et al. Prevalence and clinical significance of psychiatric comorbidities with gambling disorder in 12 clinical settings in Japan. J Addict Med. 2023;17(2):140–6.Google Scholar
Steel, Z, Marnane, C, Iranpour, C, Chey, T, Jackson, JW, Patel, V, et al. The global prevalence of common mental disorders: a systematic review and meta-analysis 1980–2013. Int J Epidemiol. 2014;43(2):476–93.Google Scholar
Fortgang, RG, Hoff, RA, Potenza, MN. Problem and pathological gambling in schizophrenia: exploring links with substance use and impulsivity. J Gambl Stud. 2018;34(3):673–88.Google Scholar
Haydock, M, Cowlishaw, S, Harvey, C, Castle, D. Prevalence and correlates of problem gambling in people with psychotic disorders. Compr Psychiatry. 2015;58:122–9.Google Scholar
Piasecki, TM, Gizer, IR, Slutske, WS. Polygenic risk scores for psychiatric disorders reveal novel clues about the genetics of disordered gambling. Twin Res Hum Genet. 2019;22(5):283–9.Google Scholar
Granero, R, Fernández-Aranda, F, Demetrovics, Z, Lara-Huallipe, M, Morón-Fernández, A, Jiménez-Murcia, S. Network analysis of the structure of the core symptoms and clinical correlates in comorbid schizophrenia and gambling disorder. Int J Ment Health Addict. 2024;22:2247–73. https://doi.org/10.1007/s11469-022-00983-yGoogle Scholar
Corrigan, PW, Druss, BG, Perlick, DA. The impact of mental illness stigma on seeking and participating in mental health care. Psychol Sci Public Interest. 2014;15(2):3770.Google Scholar
Hu, J, Zheng, Q, Zhang, Y, Liu, C, Tian, X, Liu, X, et al. Help-seeking behavior of individuals with schizophrenia in the general population of Hunan, China. Sci Rep. 2021;11(1):23012.Google Scholar
Solmi, M, Fiedorowicz, J, Poddighe, L, Delogu, M, Miola, A, Høye, A, et al. Disparities in screening and treatment of cardiovascular diseases in patients with mental disorders across the world: systematic review and meta-analysis of 47 observational studies. Am J Psychiatry. 2021;178(9):793803.Google Scholar
Solmi, M, Firth, J, Miola, A, Fornaro, M, Frison, E, Fusar-Poli, P, et al. Disparities in cancer screening in people with mental illness across the world versus the general population: prevalence and comparative meta-analysis including 4 717 839 people. Lancet Psychiatry. 2020;7(1):5263.Google Scholar
Vanasse, A, Courteau, J, Courteau, M, Roy, MA, Stip, E, Fleury, MJ, et al. Multidimensional analysis of adult patients’ care trajectories before a first diagnosis of schizophrenia. Schizophrenia (Heidelb). 2022;8(1):52.Google Scholar
Barker, TH, Migliavaca, CB, Stein, C, Colpani, V, Falavigna, M, Aromataris, E, et al. Conducting proportional meta-analysis in different types of systematic reviews: a guide for synthesisers of evidence. BMC Med Res Methodol. 2021;21(1):189.Google Scholar
Williams, BD, Lee, K, Ewah, SO, Neelam, K. Aripiprazole and other third-generation antipsychotics as a risk factor for impulse control disorders: a systematic review and meta-analysis. J Clin Psychopharmacol. 2024;44(1):3948.Google Scholar
Akbari, M, Jamshidi, S, Sheikhi, S, Alijani, F, Kafshchi, P, Taylor, D. Aripiprazole and its adverse effects in the form of impulsive-compulsive behaviors: a systematic review of case reports. Psychopharmacology (Berl). 2024;241(2):209–23.Google Scholar
Corbeil, O, Corbeil, S, Giroux, I, Jacques, C, Dorval, M, Demers, M-F, et al. Problem gambling associated with aripiprazole in first-episode psychosis patients: a series of 6 case reports. J Clin Psychopharmacol. 2020;40(2):191–4.Google Scholar
Etminan, M, Sodhi, M, Samii, A, Procyshyn, RM, Guo, M, Carleton, BC. Risk of gambling disorder and impulse control disorder with aripiprazole, pramipexole, and ropinirole: a pharmacoepidemiologic study. J Clin Psychopharmacol. 2017;37(1):102–4.Google Scholar
Grall-Bronnec, M, Sauvaget, A, Perrouin, F, Leboucher, J, Etcheverrigaray, F, Challet-Bouju, G, et al. Pathological gambling associated with aripiprazole or dopamine replacement therapy do patients share the same features? A review. J Clin Psychopharmacol. 2016;36(1):6370.Google Scholar
Lachance, A, Corbeil, O, Corbeil, S, Chalifour, G, Breault, A-S, Roy, M-A, et al. Case reports of aripiprazole and problematic gambling in schizophrenia: a critical review of the evidence. J Clin Psychopharmacol. 2019;39(4):393–7.Google Scholar
Mahapatra, A, Sharma, P, Sagar, R. Aripiprazole induced impulse control disorders: where do we stand? Asian J Psychiatr. 2016;23:128–30.Google Scholar
Wolfschlag, M, Håkansson, A. Increased risk for developing gambling disorder under the treatment with pramipexole, ropinirole, and aripiprazole: a nationwide register study in Sweden. PLoS One. 2021;16(6):e0252516.Google Scholar
Zazu, L, Morera-Herreras, T, Garcia, M, Aguirre, C, Lertxundi, U. Do cariprazine and brexpiprazole cause impulse control symptoms? A case/non-case study. Eur Neuropsychopharmacol. 2021;50:107–11.Google Scholar
Fusaroli, M, Raschi, E, Giunchi, V, Menchetti, M, Rimondini Giorgini, R, De Ponti, F, et al. Impulse control disorders by dopamine partial agonists: a pharmacovigilance-pharmacodynamic assessment through the FDA adverse event reporting system. Int J Neuropsychopharmacol. 2022;25(9):727–36.Google Scholar
Wolfschlag, M, Håkansson, A. Drug-induced gambling disorder: epidemiology, neurobiology, and management. Pharmaceut Med. 2023;37(1):3752.Google Scholar
Seeman, P. Parkinson’s disease treatment may cause impulse-control disorder via dopamine D3 receptors. Synapse. 2015;69(4):183–9.Google Scholar
Figure 0

Figure 1. Flow chart of reviewed articles. Adapted from Page et al. [33].

Figure 1

Table 1. Characteristics of the included studies

Figure 2

Table 2. Psychotic disorders assessment in the included studies

Figure 3

Figure 2. Box plot of the prevalence of any psychotic disorders in people with problem gambling.

Figure 4

Table 3. Results of moderator analyses for the prevalence of any psychotic disorders in people with problem gambling

Figure 5

Figure 3. Forest plot of the pooled estimated prevalence of any psychotic disorders in people with problem gambling according to type of recruitment. Abbreviations: CI, confidence interval.Note: The overall pooled estimate is represented by the vertical dashed line.

Supplementary material: File

Corbeil et al. supplementary material

Corbeil et al. supplementary material
Download Corbeil et al. supplementary material(File)
File 1.9 MB
Submit a response

Comments

No Comments have been published for this article.