Postmarket safety profile of suicide/self-injury for GLP-1 receptor agonist: a real-world pharmacovigilance analysis

Congqin Chen; Rijing Zhou; Fang Fu; Jie Xiao

doi:10.1192/j.eurpsy.2023.2474

Postmarket safety profile of suicide/self-injury for GLP-1 receptor agonist: a real-world pharmacovigilance analysis

Published online by Cambridge University Press: 30 November 2023

Fang Fu and

Congqin Chen: Affiliation:
Department of Pharmacy, Xiamen Cardiovascular Hospital, Xiamen University, Xiamen, China
Rijing Zhou: Affiliation:
Department of Intensive Care Unit, Xiamen Cardiovascular Hospital, Xiamen University, Xiamen, China
Fang Fu: Affiliation:
Department of Pharmacy, Xiamen Cardiovascular Hospital, Xiamen University, Xiamen, China
Jie Xiao*: Affiliation:
Department of Pharmacy, Xiamen Cardiovascular Hospital, Xiamen University, Xiamen, China
*: Corresponding author: Jie Xiao; Email: yfxjbz666@163.com

Article contents

Abstract
Background
Methods
Results
Conclusions
Introduction
Methods
Results
Discussion
Conclusions
Author contribution
Financial support
Competing interest
Ethics statement
References

Abstract

Background

Recent reports of individuals experiencing suicidal and/or self-injurious behaviors while using liraglutide and semaglutide have heightened the concerns regarding neuropsychiatric safety of Glucagon-like peptide-1 agonists (GLP-1RAs). As real-world evidence is very limited, we explored the association between GLP-1RA and suicide/self-injury by mining the FDA Adverse Event Reporting System (FAERS) database.

Methods

The FAERS database was queried from 2005 Q2 to 2023 Q2. The Reporting Odds Ratio (ROR) and Empirical Bayes Geometric Mean (EBGM) were used to conduct the disproportionality analysis.

Results

A total of 534 GLP-1RA-associated suicide/self-injury cases were reported in the FAERS during the study period. GLP-1RA did not cause a disproportionate increase in overall suicidal and self-injurious cases (ROR: 0.16, 95%CI 0.15-0.18, P < 0.001; EBGM05: 0.15). Stratified analyses found no safety signal of suicide/injury for GLP-1RA in both females and males. The ROR for suicide/self-injury with GLP-1RA was slightly elevated (ROR: 2.50, 95%CI 1.02-6.13, P = 0.05) in children, while the EBGM05 was < 2 in this population. No significant signal value was observed in other age groups. No over-reporting of suicide/self-injury was identified for GLP-1RA before or after the COVID-19 pandemic outbreak.

Conclusions

The cases of suicide or self-injury reported to FAERS do not indicate any overall safety signal attributable to GLP-1RA at this time. Subgroup analysis revealed a marginal elevation of ROR for suicide and self-injury with GLP-1RA in children, but no safety signal was detected by EBGM05 in this population. Further large-scale prospective investigations are still warranted to further confirm this finding.

Keywords

FAERS GLP-1RA pharmacovigilance analysis self-injury suicide

Type: Research Article
Information: European Psychiatry , Volume 66 , Issue 1 , 2023 , e99

DOI: https://doi.org/10.1192/j.eurpsy.2023.2474 [Opens in a new window]
Creative Commons: 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), 2023. Published by Cambridge University Press on behalf of the European Psychiatric Association

Introduction

Glucagon-like peptide-1 receptor agonists (GLP-1RAs) are a class of medications that mimic the action of the natural hormone GLP-1, which plays a crucial role in regulating glucose metabolism and various other physiological processes [Reference Drucker1, Reference Trujillo, Nuffer and Smith2]. GLP-1RA has gained a sudden surge in popularity for its ability to trigger glycemic control, weight loss, and cardiovascular risk reduction [Reference Baggio and Drucker3–Reference Taha, Yahya, Satish, Laird, Agatston and Cainzos-Achirica6]. Recently, rare but serious psychiatric adverse events (AEs) associated with GLP1-RA, such as suicide and self-injury, have gained attention [Reference O’Neil, Aroda, Astrup, Kushner, Lau and Wadden7]. The Icelandic Medicines Agency’s alert regarding reports of suicidal thoughts and self-injury in individuals using liraglutide and semaglutide has raised concerns about the potential suicidal and/or self-injurious risk associated with GLP-1RA [8]. Although causality cannot be proved based on the case anecdotes, constant vigilance for this phenomenon is warranted.

Despite significant concerns raised by recent case reports, the evidence of GLP-1RA-associated suicidal and self-injurious risk is very limited. Wilding and colleagues pooled data from weight-management clinical trials to assess the neuropsychiatric safety of liraglutide [Reference O’Neil, Aroda, Astrup, Kushner, Lau and Wadden7]. The results of this exploratory pooled analysis revealed a slight numerical imbalance in suicidal ideation with liraglutide through AE reporting, while no imbalance was noted through prospective questionnaire assessments. The analysis is restricted to obese patients, and the drug under consideration is specifically liraglutide 3.0 mg. While safety assessments in clinical trials offer insights into AEs within the indicated population, these studies have limitations due to their duration and predefined patient criteria. Consequently, potential safety concerns may emerge in real-world settings that were not apparent during clinical trial evaluations [Reference Lucas, Ailani, Smith, Abdrabboh, Xue and Navetta9]. No substantial evidence has been accumulated to address the uncertainty regarding the association of GLP-1RA with suicide or self-injury to date. Therefore, in order to fully understand the potential risk of suicide/self-injury related to GLP-1RA, a postmarket pharmacovigilance study was carried out to explore the association between GLP-1RA and suicidal/self-injury reports by utilizing the Food and Drug Administration (FDA) Adverse Event Reporting System (FAERS) database.

Methods

Data source

Managed by the FDA, FAERS compiles AE reports from various contributors such as healthcare professionals, patients, drug manufacturers, and more [Reference Anand, Ensor, Trachtenberg and Bernicker10–Reference Yang, Lv, Yu, Mei, Xiang and Zhao12]. AE symptoms are categorized using the globally accepted and clinically validated Medical Dictionary for Regulatory Activities (MedDRA) terminology [Reference Kumar13]. FAERS enables the examination of unforeseen AE trends that might go unnoticed in clinical trials due to participant limitations [Reference Jedlowski, Jedlowski and Fazel14, Reference Woods15].

Data queries

In accordance with the aforementioned, the recent reports of individuals exhibiting suicidal and self-injurious behaviors while using liraglutide and semaglutide have sparked concerns. Therefore, the FAERS database was queried from the second quarter (Q2) of 2005 to the Q2 of 2023, to analyze disproportionality and investigate the association between GLP-1RA and AEs involving suicide and self-injury. Each report was classified based on the contingency table (Table 1), where “a” represents the number of suicide/self-injury reports for GLP-1RA, “b” represents the reports for GLP-1RA without suicide/self-injury, “c” represents the number of suicide/self-injury reports for all other drugs, and “d” represents the reports for all other drugs without suicide/self-injury. Reports associated with GLP-1RA were identified when any of the six GLP-1RAs (liraglutide, lixisenatide, exenatide, albiglutide, semaglutide, and dulaglutide) was classified as “primary suspected” or “secondary suspected” drug in reported cases. Suicidal and self-injurious reports were queried by combining the MedDRA 26.0 preferred terms (PTs) of the standard MedDRA query (SMQ) for “suicide/self-injury.” The precise terms used were “assisted suicide,” “Columbia suicide severity rating scale abnormal,” “completed suicide,” “depression suicidal,” “intentional overdose,” “intentional self-injury,” “poisoning deliberate,” “self-injurious ideation,” “suicidal behavior,” “suicidal ideation,” “suicide attempt,” “suicide threat,” “suspected suicide,” “suspected suicide attempt.” Utilization of globally accepted and clinically validated mesh terms enabled us to effectively address the reports pertaining to the objectives of this study. The detailed data processing procedure is shown in Figure 1.

Table 1. Contingency table for disproportionality analysis

GLP-1RA, glucagon-like peptide-1 receptor agonist.

Figure 1. Flow chart of data queries within the FAERS database. FAERS, the U.S. Food and Drug Administration (FDA) Adverse Event Reporting System; Q2, the second quarter; GLP-1RA, glucagon-like peptide-1 receptor agonist; PT, preferred term; SMQ, standard MedDRA (Medical Dictionary for Regulatory Activities) query.

Data analysis

A population-based pharmacovigilance study utilizing a case/non-case approach was employed to investigate the potential association between GLP-1RA and reports of suicidal tendencies and/or self-injury. This method is a prevalent technique employed in pharmacovigilance research to detect safety signals [Reference Chen, Ding, Fu and Xiao16–Reference He, Lam, Zhao, Yang, Li and Mo18]. From a mathematical perspective, the concept behind the case/non-case approach involves contrasting the reporting rate of a specific AE in patients who have been exposed to a particular drug with the reporting rate of the same AE in patients who haven’t been exposed to that drug [Reference Rothman, Lanes and Sacks19, Reference Sakaeda, Tamon, Kadoyama and Okuno20]. In this study, disproportionality was evaluated by the empirical Bayes geometric mean (EBGM) from multi-item gamma Poisson shrinker (MGPS) and the reporting odds ratio (ROR). Signal was defined when the EBGM05 metric, a lower one-sided 95% confidence limit of the EBGM ≥ 2.0 [Reference Sakaeda, Tamon, Kadoyama and Okuno20] or the lower limits of the 95% confidence intervals (95% CIs) of ROR exceeded 1 in at least three reports [Reference Zhai, Ye, Hu, Xu, Guo and Lin21]. The equations of EBGM and ROR are listed in Table 2.

Table 2. Equations and criteria for ROR and MGPS

a, the number of suicide/self-injury reports for GLP-1RA; b, the reports for GLP-1RA without suicide/self-injury; c, the number of suicide/self-injury reports for all other drugs; d, the reports for all other drugs without suicide/self-injury; 95% CI, 95% confidence interval; N, the number of reports; ROR, the reporting odds ratio; MGPS, multi-item gamma Poisson shrinker; EBGM, empirical Bayesian geometric mean; EBGM05, the lower limit of 95% CI of EBGM; GLP-1RA, glucagon-like peptide-1 receptor agonist.

Results

Data overview of adverse events reported in the FAERS database, 2005Q2–2023Q2

Over the study period, a total of 19,556,905 de-duplicated records were extracted from the FAERS database. Overall, 219,376 AEs were found to be related to GLP-1RA, and 288,138 reports related to suicide/self-injury were documented. Among them, GLP-1RA was identified as the suspected drug causing suicide/self-injury in 534 reports.

Descriptive analysis of suicidal and self-injurious adverse events among GLP-1RA users

The clinical characteristics of GLP-1RA-associated suicide/self-injury are presented in Table 3. Within this cohort, 53.18% were female and 41.20% were male. Cases of GLP-1RA-associated suicide/self-injury were more likely to be reported in adults aged 25 to 65 years (48.50%). Customers reported 38.58% of the cases, physicians reported 34.46% of the cases, pharmacists reported 9.55% of the cases, and 8.61% of the cases were reported by other healthcare providers. Most of the suicide/self-injury AEs related to GLP-1RA were reported during the first quarter of 2020 to the second quarter of 2023. After analyzing all the reported suicide/self-harm cases related to GLP-1RA, it was found that 51.50% exhibited symptoms of suicidal ideation, 19.29% had attempted suicide, and 18.73% experienced intentional overdose.

Table 3. Clinical characteristics of suicide/self-injury cases reported to FAERS during the study period

GLP-1RA, glucagon-like peptide-1 receptor agonist; PT, preferred term.

Disproportionality analysis for the association of suicide/self-injury with GLP-1RA

The results of overall disproportionality analysis are summarized in Figure 2. The analysis demonstrated that no over-reporting of suicide/self-injury was identified in GLP-1RA, with a pooled ROR of 0.16 (95% CI 0.15–0.18, P < 0.001) and EBGM05 of 0.15. We calculated the disproportional pattern of each suicidal and self-injurious PT with GLP-RA. No safety signal was detected for all related PTs.

Figure 2. Results of overall disproportionality analysis for GLP-1RA-associated suicide/self-injury at PT levels. (A) EBGM05s of GLP-1RA-associated suicide/self-injury. (B) RORs (95% CI) of GLP-1RA-associated suicide/self-injury. EBGM05, lower one-sided 95% confidence limit (95% CI) of the empirical Bayes geometric mean; PT, preferred term; ROR, reporting odds ratio; GLP-1RA, glucagon-like peptide-1 receptor agonist.

Figure 3A displays the number of reports for each specific GLP-1RA drug. It can be observed that among the suicidal and self-injurious reports related to GLP-1RA, 199 cases were associated with liraglutide, 134 cases with exenatide, 106 cases with semaglutide, 89 cases with dulaglutide, 3 cases with albiglutide, and 3 cases with lixisenatide. Stratified analyses revealed low ROR and EBGM05 value for suicide/self-injury in all GLP-1RAs, implying that none of the six GLP-1RA drugs examined in this study were linked to the risk of suicide and/or self-injury in general (Figure 3B,C).

Figure 3. Results of disproportionality analysis for suicidal and self-injurious reports associated with GLP-1RA at drug levels. (A) Number of suicide/self-injury and non-suicide/self-injury reports for each GLP-1RA drug. (B) EBGM05 of GLP-1RA-associated suicide/self-injury for each distinct GLP-1RA drug. (C) RORs (95% CI) of GLP-1RA-associated suicide/self-injury for each distinct GLP-1RA drug. ROR, reporting odds ratio; GLP-1RA, glucagon-like peptide-1 receptor agonist; EBGM05, lower one-sided 95% confidence limit (95% CI) of the empirical Bayes geometric mean.

To delve deeper into individual characteristics, separate sub-analyses were conducted based on gender, age, and reporting time (Figure 4). No safety signal of suicide/injury for GLP-1RA was detected in both females (ROR 0.15, 95% CI 0.13–0.17, P < 0.001; EBGM05 0.14) and males (ROR 0.16, 95% CI 0.14–0.19, P < 0.001; EBGM05 0.15). Stratified analysis by age showed that the ROR for suicide/self-injury with GLP-1RA was slightly elevated in children (ROR 2.50, 95% CI 1.02–6.13, P = 0.05), while the EBGM05 of GLP-1RA-associated suicide/self-injury was lower than 2 for children. No significant signal value was observed in other age groups based on the results of ROR and EBGM05. Using the fourth quarter of 2019 and the first quarter of 2020 as the cut-offs, we divided the reports into two different groups based on the time of COVID-19 pandemic outbreak. Among the reports of suicide/self-injury with GLP-1RA, 294 (55.06%) cases were reported in 2005Q2–2019Q4, and 240 (44.94%) cases were reported during 2020Q1–2023Q2. No over-reporting of suicide/self-injury was identified for GLP-1RA in the two periods.

Figure 4. Results of subgroup disproportionality analysis of GLP-1RA-associated suicide/self-injury based on age, sex and reporting time. (A) EBGM05s of GLP-1RA-associated suicide/self-injury in different sex, age and reporting time groups. (B) RORs (95% CI) of GLP-1RA-associated suicide/self-injury in different sex, age and reporting time groups. ROR, reporting odds ratio; 95% CI, 95% confidence limit; GLP-1RA, glucagon-like peptide-1 receptor agonist; EBGM05, lower one-sided 95% CI of the empirical Bayes geometric mean.

Discussion

The neuropsychiatric safety of GLP-1RAs has garnered attention, primarily owing to their centrally acting appetite-suppressing activity [Reference O’Neil, Aroda, Astrup, Kushner, Lau and Wadden7]. Concerns have escalated following recent reports of individuals exhibiting suicidal and self-injurious behaviors while using liraglutide and semaglutide [8]. The available evidence on the association between GLP-1RA and the risk of suicidal and self-injurious behaviors is quite limited. Wilding and his colleagues [Reference O’Neil, Aroda, Astrup, Kushner, Lau and Wadden7] conducted a comprehensive analysis by combining data from various weight-management clinical trials [Reference Blackman, Foster, Zammit, Rosenberg, Aronne and Wadden22–Reference Wadden, Hollander, Klein, Niswender, Woo and Hale27], focusing on the neuropsychiatric safety of liraglutide. The outcomes of this exploratory pooled analysis provide a level of reassurance regarding the suicidal safety associated with the use of liraglutide 3.0 mg in patients who share similarities with those involved in the examined trials. Safety assessments conducted in clinical trials provide valuable insights into AEs within a specified population. However, these studies have inherent limitations, primarily stemming from their controlled duration and predefined patient criteria [Reference Blackman, Foster, Zammit, Rosenberg, Aronne and Wadden22–Reference Wadden, Hollander, Klein, Niswender, Woo and Hale26]. The controlled nature of clinical trials may not fully capture the diverse and dynamic conditions encountered in real-world settings. As a result, potential safety concerns might arise in everyday clinical practice that were not evident during the more controlled and structured environment of clinical trial evaluations [Reference Paludetto, Olivier-Abbal and Montastruc28]. Therefore, postmarketing surveillance and real-world evidence play a crucial role in continuously monitoring the safety and effectiveness of medications once they are in widespread use [Reference Zhou, Peng, Lin, Jiang, Peng and Gu29–Reference Fan, Hu, Yang and Zhao31]. The analysis of pharmacovigilance for a drug, utilizing postmarketing safety databases like the FAERS, plays a crucial role in the ongoing management of risks by detecting safety signals that may not have been identified during the drug’s clinical development phase [Reference Anand, Ensor, Trachtenberg and Bernicker10, Reference Jedlowski, Jedlowski and Fazel14, Reference Egeberg and Thyssen32–Reference Yu, Krantz, Phillips and Stone35]. A previous pharmacovigilance study based on FAERS conducted an analysis of the potential risk between GLP-1RA and tumors and provided new real-world evidence for oncology safety information of GLP-1RA [Reference Yang, Lv, Yu, Mei, Xiang and Zhao12]. To the best of our knowledge, our study is the first pharmacovigilance study of suicide/self-injury AEs associated with GLP-1RAs based on the FAERS database. The results of our analysis did not reveal any abnormally elevated association of GLP-1RA with overall cases of suicide/self-injury, whether based on the SMQ level or focusing on specific subcategories at the PT level. This suggests that, based on the available data, there is no evidence to suggest a heightened risk of suicide or self-injury associated with the use of GLP-1RA. These findings contribute to the understanding of the safety profile of GLP-1RA in relation to these specific AEs.

We identified a total of 534 cases of suicidal and self-injurious behavior associated with GLP-1RAs in the FAERS database during the period from 2005Q2 to 2023Q2. Among these cases, 53.18% were female and 41.20% were male. Epidemiological data on suicide reveals that the 12-month prevalence of suicidal ideation is greater in females than males whereas the prevalence of suicide attempts is comparable for females and males [Reference Borges, Nock, Haro Abad, Hwang, Sampson and Alonso36]. Among the 534 cases of suicidal and self-injurious behavior associated with GLP-1RA in our study, 275 (51.50%) cases experienced suicidal ideation. This could potentially contribute to the higher proportion of females in all these cases. Following a subgroup disproportionality analysis based on gender, the findings indicate that no safety signals were identified for either females or males. This suggests that, within the studied population, there were no notable differences in the occurrence of suicidal and self-injurious AEs between the two genders that would raise concerns requiring further investigation.

In response to the Icelandic Medicines Agency’s alert regarding reports of suicidal thoughts and self-injury linked to the use of liraglutide and semaglutide, we undertook a comprehensive analysis to assess the risk of suicide/self-injury associated with various GLP-1RAs. Through a subgroup analysis based on the specific drug, the results revealed that none of the six GLP-1RA drugs examined generated a safety signal in relation to suicide or self-injury. This outcome suggests that, despite the specific concerns raised in the alert for liraglutide and semaglutide, the broader class of GLP-1RAs does not exhibit an elevated risk of these AEs based on the available data. The subgroup analysis enhances our understanding of the safety profile of individual GLP-1RA drugs in the context of suicide and self-injury.

Suicidal and self-injurious patterns linked to age differ among global regions. According to the results of a national survey conducted in 2015, the annual rate of suicide attempts is three to five times greater in young adults aged 18–25 years, compared with older age groups in the United States [Reference Piscopo, Cooney and Glasheen37]. The Office for National Statistics in UK detected an increase in suicide rates in children and young people in 2014 [Reference Stallard38]. We conducted a subgroup analysis based on age to assess the proportional imbalance of AEs related to suicide/self-injury for GLP-1RA within different age groups. Specifically, in the subgroup of children, the ROR indicated a slight elevation in the reporting pattern of suicide/self-injury. However, it is essential to interpret this result with caution, as the EBGM05 for GLP-1RA-associated suicide/self-injury in children was lower than 2, suggesting a lack of robust signal strength. Contrastingly, no statistically significant signal values were observed in other age groups, including younger adults, adults, and the elderly, based on both ROR and EBGM05. Compared to adults, relatively few studies have investigated the use of GLP-1RA in pediatric patients with diabetes and obesity. However, some studies have provided strong evidence for the beneficial effects of GLP-1RA in children with type 2 diabetes mellitus (T2D) and obesity, and have paved the way for GLP-1RA to be introduced to pediatric clinical practice [Reference Tamborlane, Barrientos-Perez, Fainberg, Frimer-Larsen, Hafez and Hale39–42]. Some GLP-1RAs have been approved in pediatric population several years ago. In June 2019, The FDA approved liraglutide for the treatment of pediatric patients over the age of 10 years with T2D. In December 2020, the FDA also approved liraglutide for treatment of obesity in adolescents 12–17 years of age. In July 2021, an extended-release formulation of exenatide was approved by FDA in patients ≥10 years old. In November 2022, dulaglutide was indicated as an adjunct to diet and exercise to improve glycemic control in adults and pediatric patients ≥10 years of age with type 2 diabetes mellitus. In December 2022, semaglutide was also indicated for chronic weight management in pediatric patients aged 12 years and older. While there is a marginal elevation of ROR in children, the discrepancy with the EBGM05 underscores the complexity of signal detection. Even our analytical period contains 4 years of GLP-1RA usage in pediatric population, it is still crucial for future research to explore the underlying mechanisms contributing to this observed association and to validate findings with larger and more diverse datasets.

The COVID-19 pandemic has had a significant impact on the mental well-being of people worldwide. Various factors associated with the COVID-19 pandemic, such as social isolation, economic stress, uncertainty, and disruptions to daily life, were identified as potential contributors to mental health challenges. These challenges, in turn, could be linked to an increased risk of suicidal thoughts and behaviors [Reference John, Pirkis, Gunnell, Appleby and Morrissey43, Reference Botchway and Fazel44]. We divided the reports of suicide and self-injury associated with GLP-1RA into two groups based on the time of the COVID-19 pandemic outbreak. Among the cases reported, 55.06% occurred from the second quarter of 2005 to the fourth quarter of 2019, while 44.94% cases were reported during the first quarter of 2020 to the second quarter of 2023. Notably, there was no identified over-reporting of suicide or self-injury for GLP-1RA in either of the two periods. During the pandemic, more adverse reactions related to suicide in individuals using GLP-1RA reported may be attributed to various factors. Notably, in June 2021, the FDA approved semaglutide for chronic weight management in adults dealing with general obesity or overweight and presenting at least one weight-related condition [Reference Davies, Faerch, Jeppesen, Pakseresht, Pedersen and Perreault45]. The introduction of this new indication may have led to a broader user population, consequently resulting in a higher number of reported adverse reactions.

With the increasing popularity of GLP-1RA, especially following its approval for obesity indications, a growing number of individuals may opt for GLP-1RA, potentially involving off-label use. We investigated pre-July 2017 FAERS data, predating the approval of GLP-1RA for pediatric use, and identified 80 cases of AEs in children related to GLP-1RA, suggesting the existence of off-label use. It is crucial to emphasize that off-label use must be justified by specific clinical needs, supported by scientific evidence from evidence-based medicine, and administered under close medical supervision [46, Reference McCarthy47]. Individuals should refrain from unauthorized off-label use, as it poses significant risks [Reference Eguale, Buckeridge, Verma, Winslade, Benedetti and Hanley48]. Each GLP-1RA has explicit indications and contraindications for weight loss [Reference Pratley, Kang, Trautmann, Hompesch, Han and Stewart49]. Blindly following trends in usage without adhering to specific requirements and medical supervision is strongly discouraged.

The utilization of the FAERS in pharmacovigilance is indispensable, yet its application is constrained by several notable limitations. Firstly, the majority of reports lack evidence establishing a causal link between the reported AE and drug exposure. The inability to definitively establish causality is a constraint shared by all pharmacovigilance studies and observational cohort studies [Reference Ruiz, Cocores, Tosti, Goadsby and Monteith50, Reference Wichelmann, Abdulmujeeb and Ehrenpreis51]. Secondly, cases in FAERS might contain incomplete information such as dose, complication, onset time, and other details. The incomplete capture of AEs hampers the comprehensiveness of the database, rendering it challenging to obtain a holistic understanding of a drug’s safety profile. Given the limitations mentioned, our study cannot provide a comprehensive assessment of the correlation between GLP-1RA dosage and indication with suicide/self-injury, and it also lacks the capability to thoroughly evaluate other potential risk factors or comorbidities. Furthermore, reporting bias is a significant concern, potentially skewing the perception of drug safety by overemphasizing widely publicized or severe events. Therefore, any conclusions drawn from pharmacovigilance analysis should be interpreted within the context of these constraints, and further research with a broader scope may be necessary to elucidate a more complete understanding of the relationships involved. Notwithstanding these limitations, disproportionality analysis still remains a crucial tool for detecting potential safety signals associated with drugs and guiding further investigations [Reference Chen, Ding, Fu and Xiao16, Reference Zhou, Peng, Lin, Jiang, Peng and Gu29, Reference Blau, Tella, Taylor and Rother33, Reference Ding, Chen, Yang, Fang, Cao and Liu52]. It is important to acknowledge that our study represents a preliminary snapshot based on available data and methodologies. Future research endeavors could consider employing additional approaches, such as prospective clinical trials or evidence-based cohort studies, to overcome some of the limitations associated with FAERS data.

Conclusions

Concerns regarding the potential risk of suicide or self-injury associated with GLP-1RA have been raised based on anecdotal case reports. This study contributes postmarket evidence on the neuropsychiatric safety profile of GLP-1RA. Analysis of suicide and self-injury cases reported to FAERS currently does not indicate any safety concerns directly attributable to GLP-1RA. Subgroup analysis has revealed a marginal increase in the ROR for suicide and self-injury associated with GLP-1RA use in children, but no safety signal was detected using EBGM05 in this specific population. Nevertheless, it is essential to emphasize that our study represents a preliminary snapshot based on available data and methodologies. To substantiate and enhance these initial findings, there is a pressing need for more comprehensive prospective investigations conducted on a larger scale.

Author contribution

C.C. contributed to data analysis, interpretation, and writing. R.Z. contributed to data analysis and revising. F.F. revised the manuscript. J.X. conceived and designed this study.

Financial support

This research received no specific grant from any funding agency, commercial, or not-for-profit sectors.

Competing interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Ethics statement

This study was determined to be exempt from institutional review board approval by Xiamen Cardiovascular Hospital because it used publicly available, de-identified data.

References

Drucker, DJ. Mechanisms of action and therapeutic application of glucagon-like peptide-1. Cell Metab. 2018;27(4):740–56.Google Scholar

Trujillo, JM, Nuffer, W, Smith, BA. GLP-1 receptor agonists: an updated review of head-to-head clinical studies. Ther Adv Endocrinol Metab. 2021;12:2042018821997320.Google Scholar

Baggio, LL, Drucker, DJ. Glucagon-like peptide-1 receptor co-agonists for treating metabolic disease. Mol Metab. 2021;46:101090.Google Scholar

Jepsen, MM, Christensen, MB. Emerging glucagon-like peptide 1 receptor agonists for the treatment of obesity. Expert Opin Emerg Drugs. 2021;26(3):231–43.Google Scholar

Nauck, MA, Meier, JJ, Cavender, MA, Abd El Aziz, M, Drucker, DJ. Cardiovascular actions and clinical outcomes with glucagon-like peptide-1 receptor agonists and dipeptidyl peptidase-4 inhibitors. Circulation. 2017;136(9):849–70.Google Scholar

Taha, MB, Yahya, T, Satish, P, Laird, R, Agatston, AS, Cainzos-Achirica, M, et al. Glucagon-like peptide 1 receptor agonists: a medication for obesity management. Curr Atheroscler Rep. 2022;24(8):643–54.Google Scholar

O’Neil, PM, Aroda, VR, Astrup, A, Kushner, R, Lau, DCW, Wadden, TA, et al. Neuropsychiatric safety with liraglutide 3.0 mg for weight management: results from randomized controlled phase 2 and 3a trials. Diabetes Obes Metab. 2017;19(11):1529–36.Google Scholar

Reactions Weekly 1966. Semaglutide, liraglutide: risk of suicidal ideation and self-injury. 2023. Available from: https://doi.org/10.1007/s40278-023-43459-0.Google Scholar

Lucas, S, Ailani, J, Smith, TR, Abdrabboh, A, Xue, F, Navetta, MS. Pharmacovigilance: reporting requirements throughout a product’s lifecycle. Ther Adv Drug Saf. 2022;13:20420986221125006.Google Scholar

Anand, K, Ensor, J, Trachtenberg, B, Bernicker, EH. Osimertinib-induced cardiotoxicity: a retrospective review of the FDA adverse events reporting system (FAERS). JACC CardioOncol. 2019;1(2):172–8.Google Scholar

Peng, L, Xiao, K, Ottaviani, S, Stebbing, J, Wang, YJ. A real-world disproportionality analysis of FDA adverse event reporting system (FAERS) events for baricitinib. Expert Opin Drug Saf. 2020;19(11):1505–11.Google Scholar

Yang, Z, Lv, Y, Yu, M, Mei, M, Xiang, L, Zhao, S, et al. GLP-1 receptor agonist-associated tumor adverse events: a real-world study from 2004 to 2021 based on FAERS. Front Pharmacol. 2022;13:925377.Google Scholar

Kumar, A. The newly available FAERS public dashboard: implications for health care professionals. Hosp Pharm. 2019;54(2):75–7.Google Scholar

Jedlowski, PM, Jedlowski, MF, Fazel, MT. DPP-4 inhibitors and increased reporting odds of bullous pemphigoid: a pharmacovigilance study of the FDA adverse event reporting system (FAERS) from 2006 to 2020. Am J Clin Dermatol. 2021;22(6):891–900.Google Scholar

Woods, RH. Potential cerebrovascular accident signal for risankizumab: a disproportionality analysis of the FDA adverse event reporting system (FAERS). Br J Clin Pharmacol. 2023;89(8):2386–95.Google Scholar

Chen, C, Ding, L, Fu, F, Xiao, J. Updated insights on dementia-related risk of sacubitril/valsartan: a real-world pharmacovigilance analysis. CNS Neurosci Ther. 2023;29(9):2548–54.Google Scholar

Gu, T, Jiang, A, Zhou, C, Lin, A, Cheng, Q, Liu, Z, et al. Adverse reactions associated with immune checkpoint inhibitors and bevacizumab: a pharmacovigilance analysis. Int J Cancer. 2023;152(3):480–95.CrossRef Google Scholar PubMed

He, Z, Lam, K, Zhao, W, Yang, S, Li, Y, Mo, J, et al. SGLT-2 inhibitors and euglycemic diabetic ketoacidosis/diabetic ketoacidosis in FAERS: a pharmacovigilance assessment. Acta Diabetol. 2023;60(3):401–11.CrossRef Google Scholar PubMed

Rothman, KJ, Lanes, S, Sacks, ST. The reporting odds ratio and its advantages over the proportional reporting ratio. Pharmacoepidemiol Drug Saf. 2004;13(8):519–23.Google Scholar

Sakaeda, T, Tamon, A, Kadoyama, K, Okuno, Y. Data mining of the public version of the FDA adverse event reporting system. Int J Med Sci. 2013;10(7):796–803.Google Scholar

Zhai, Y, Ye, X, Hu, F, Xu, J, Guo, X, Lin, Z, et al. Updated insights on cardiac and vascular risks of proton pump inhibitors: a real-world pharmacovigilance study. Front Cardiovasc Med. 2022;9:767987.CrossRef Google Scholar PubMed

Blackman, A, Foster, GD, Zammit, G, Rosenberg, R, Aronne, L, Wadden, T, et al. Effect of liraglutide 3.0 mg in individuals with obesity and moderate or severe obstructive sleep apnea: the SCALE Sleep Apnea randomized clinical trial. Int J Obes. 2016;40(8):1310–19.Google Scholar

Davies, MJ, Bergenstal, R, Bode, B, Kushner, RF, Lewin, A, Skjoth, TV, et al. Efficacy of liraglutide for weight loss among patients with type 2 diabetes: the SCALE diabetes randomized clinical trial. JAMA. 2015;314(7):687–99.Google Scholar

le Roux, CW, Astrup, A, Fujioka, K, Greenway, F, Lau, DCW, Van Gaal, L, et al. 3 years of liraglutide versus placebo for type 2 diabetes risk reduction and weight management in individuals with prediabetes: a randomised, double-blind trial. Lancet. 2017;389(10077):1399–409.Google Scholar

Pi-Sunyer, X, Astrup, A, Fujioka, K, Greenway, F, Halpern, A, Krempf, M, et al. A randomized, controlled trial of 3.0 mg of liraglutide in weight management. N Engl J Med. 2015;373(1):11–22.Google Scholar

Wadden, TA, Hollander, P, Klein, S, Niswender, K, Woo, V, Hale, PM, et al. Weight maintenance and additional weight loss with liraglutide after low-calorie-diet-induced weight loss: the SCALE maintenance randomized study. Int J Obes. 2013;37(11):1443–51.Google Scholar

Paludetto, MN, Olivier-Abbal, P, Montastruc, JL. Is spontaneous reporting always the most important information supporting drug withdrawals for pharmacovigilance reasons in France? Pharmacoepidemiol Drug Saf. 2012;21(12):1289–94.Google Scholar

Zhou, C, Peng, S, Lin, A, Jiang, A, Peng, Y, Gu, T, et al. Psychiatric disorders associated with immune checkpoint inhibitors: a pharmacovigilance analysis of the FDA adverse event reporting system (FAERS) database. EClinicalMedicine. 2023;59:101967.Google Scholar

Wang, Y, Cui, C, Deng, L, Wang, L, Ren, X. Cardiovascular toxicity profiles of immune checkpoint inhibitors with or without angiogenesis inhibitors: a real-world pharmacovigilance analysis based on the FAERS database from 2014 to 2022. Front Immunol. 2023;14:1127128.Google Scholar

Fan, Q, Hu, Y, Yang, C, Zhao, B. Myocarditis following the use of different immune checkpoint inhibitor regimens: a real-world analysis of post-marketing surveillance data. Int Immunopharmacol. 2019;76:105866.Google Scholar

Egeberg, A, Thyssen, JP. Increased reporting of cerebrovascular accidents with use of risankizumab observed in the Food and Drug Administration adverse events reporting system (FAERS). Br J Dermatol. 2023;188(6):793–4.Google Scholar

Blau, JE, Tella, SH, Taylor, SI, Rother, KI. Ketoacidosis associated with SGLT2 inhibitor treatment: analysis of FAERS data. Diabetes Metab Res Rev. 2017;33(8):10.1002/dmrr.2924.Google Scholar

Cirmi, S, El Abd, A, Letinier, L, Navarra, M, Salvo, F. Cardiovascular toxicity of tyrosine kinase inhibitors used in chronic myeloid leukemia: an analysis of the FDA adverse event reporting system database (FAERS). Cancers (Basel). 2020;12(4):826.Google Scholar

Yu, RJ, Krantz, MS, Phillips, EJ, Stone, CA Jr. Emerging causes of drug-induced anaphylaxis: a review of anaphylaxis-associated reports in the FDA adverse event reporting system (FAERS). J Allergy Clin Immunol Pract. 2021;9(2):819–29 e2.Google Scholar

Borges, G, Nock, MK, Haro Abad, JM, Hwang, I, Sampson, NA, Alonso, J, et al. Twelve-month prevalence of and risk factors for suicide attempts in the World Health Organization world mental health surveys. J Clin Psychiatry. 2010;71(12):1617–28.Google Scholar

Piscopo, K LR, Cooney, J, Glasheen, C. Suicidal thoughts and behavior among adults: results from the 2015 National Survey on Drug Use and Health. NSDUH Data Review; Department of Health & Human Services; Rockville, MD; 2016.Google Scholar

Stallard, P. Suicide rates in children and young people increase. Lancet. 2016;387(10028):1618.Google Scholar

Tamborlane, WV, Barrientos-Perez, M, Fainberg, U, Frimer-Larsen, H, Hafez, M, Hale, PM, et al. Liraglutide in children and adolescents with type 2 diabetes. N Engl J Med. 2019;381(7):637–46.Google Scholar

Ryan, PM, Seltzer, S, Hayward, NE, Rodriguez, DA, Sless, RT, Hawkes, CP. Safety and efficacy of glucagon-like peptide-1 receptor agonists in children and adolescents with obesity: a meta-analysis. J Pediatr. 2021;236:137–47 e13.CrossRef Google Scholar PubMed

Alorfi, NM, Alshehri, FS. Usage of glucagon-like peptide-1 for obesity in children; updated review of Clinicaltrialsgov. J Multidiscip Healthc. 2023;16:2179–87.Google Scholar

In brief: semaglutide (Wegovy) for weight loss in children. Med Lett Drugs Ther. 2023;65(1670):31–2.Google Scholar

John, A, Pirkis, J, Gunnell, D, Appleby, L, Morrissey, J. Trends in suicide during the COVID-19 pandemic. BMJ. 2020;371:m4352.Google Scholar

Botchway, S, Fazel, S. Remaining vigilant about COVID-19 and suicide. Lancet Psychiatry. 2021;8(7):552–3.Google Scholar

Davies, M, Faerch, L, Jeppesen, OK, Pakseresht, A, Pedersen, SD, Perreault, L, et al. Semaglutide 2.4 mg once a week in adults with overweight or obesity, and type 2 diabetes (STEP 2): a randomised, double-blind, double-dummy, placebo-controlled, phase 3 trial. Lancet. 2021;397(10278):971–84.Google Scholar

The Lancet. Prescribing off-label drugs for children: when will it change? Lancet. 2019;394(10204):1114.CrossRef Google Scholar

McCarthy, M. Off-label drug use is associated with raised risk of adverse events, study finds. BMJ. 2015;351:h5861.Google Scholar

Eguale, T, Buckeridge, DL, Verma, A, Winslade, NE, Benedetti, A, Hanley, JA, et al. Association of off-label drug use and adverse drug events in an adult population. JAMA Intern Med. 2016;176(1):55–63.Google Scholar

Pratley, RE, Kang, J, Trautmann, ME, Hompesch, M, Han, O, Stewart, J, et al. Body weight management and safety with efpeglenatide in adults without diabetes: a phase II randomized study. Diabetes Obes Metab. 2019;21(11):2429–39.Google Scholar

Ruiz, M, Cocores, A, Tosti, A, Goadsby, PJ, Monteith, TS. Alopecia as an emerging adverse event to CGRP monoclonal antibodies: cases series, evaluation of FAERS, and literature review. Cephalalgia. 2023;43(2):3331024221143538.Google Scholar

Wichelmann, TA, Abdulmujeeb, S, Ehrenpreis, ED. Bevacizumab and gastrointestinal perforations: a review from the FDA adverse event reporting system (FAERS) database. Aliment Pharmacol Ther. 2021;54(10):1290–7.Google Scholar

Ding, L, Chen, C, Yang, Y, Fang, J, Cao, L, Liu, Y. Musculoskeletal adverse events associated with PCSK9 inhibitors: disproportionality analysis of the FDA adverse event reporting system. Cardiovasc Ther. 2022;2022:9866486.Google Scholar