The causal relationship of female infertility and psychiatric disorders in the European population: a bidirectional two-sample Mendelian randomization study

Infertility is a medical condition characterized by the failure to achieve a clinical pregnancy after 12 months of regular and unprotected sexual intercourse [1]. This condition affects approximately 8–12% of couples of reproductive age worldwide, with potentially higher incidence rates observed in developing countries [1]. Female factors contribute to 33–41% of infertility cases, while 9–39% of cases involve a combination of male and female factors [1]. Assisted reproductive technology (ART) has made significant technological advancements and has become the standard treatment for infertility in recent decades. However, the success rate of ART remains relatively modest, with clinical pregnancy rates (35%) only marginally surpassing those of natural conception (20%) [2, 3]. Furthermore, although ART is generally considered safe, research indicates a heightened risk of infection, ovarian hyperstimulation syndrome, multiple pregnancies, placentation disorders, and adverse pregnancy outcomes, including pregnancy-induced hypertension, gestational diabetes mellitus, placenta previa, placental abruption, and low birth weight [4]. Moreover, the overall costs associated with female infertility treatments are substantial, placing a significant economic burden on individuals, families, healthcare systems, and society at large. A study conducted in Israel revealed that 5.4% of total health maintenance organization expenditure was allocated to female infertility costs [5]. Female infertility patients often endure a substantial psychological burden due to the side effects of treatments, uncertainty about treatment efficacy, and the high financial implications. Furthermore, the prevalence of psychiatric disorders has been found to be higher in female infertility patients compared to the general population [6, 7].

Numerous observational studies have extensively investigated the association between psychiatric disorders and female infertility as a common complication [8, 9]. Previous investigations have consistently demonstrated an increased risk of depression [8], anxiety [10], and eating disorders [11]. in women with infertility. Conversely, psychiatric disorders such as depression, anxiety, bipolar disorder, and eating disorders can also influence female fertility [12‐14]. Moreover, psychiatric disorders have been linked to clinical outcomes in ART treatments [15, 16]. However, the findings from these studies have been subject to controversy due to limitations, including a limited number of studies, methodological weaknesses, and significant heterogeneity across studies. Furthermore, these studies establish a correlation between mental illness and infertility but fail to establish a causal relationship due to the potential presence of confounding variables or reverse causation.

Mendelian randomization (MR) analysis, utilizing summary statistics from genome-wide association studies (GWAS), is a robust and efficient approach to establish causal associations between exposure phenotypes and outcome phenotypes. By mitigating the impact of confounding factors and reverse causation, MR analysis serves as a valuable tool for investigating causal relationships [17].

Considering the limited evidence regarding the link between female infertility and psychiatric disorders, we conducted a two-sample Mendelian randomization (MR) analysis to investigate the causal effects of female infertility on the risks of depression, anxiety, bipolar disorder, and eating disorders. Our study aims to unveil potential genetic mechanisms underlying the connection between female infertility and psychiatric disorders, offering scientific evidence for primary disease prevention.

No further ethics approval was deemed necessary for this study as it entailed a reanalysis of previously gathered and published data. Hence, no novel data collection was conducted, and the utilization of publicly available data rendered it exempt from additional ethics approval.

We conducted a MR analysis to investigate the causal relationship between female infertility and psychiatric disorders. Our analysis yielded important findings regarding the impact of specific psychiatric disorders on the risk of female infertility. Specifically, we found evidence supporting the adverse effect of depression on the risk of infertility in women. On the other hand, our analysis indicated that bipolar disorder does not increase the risk of infertility in women. However, our analysis did not reveal any evidence supporting a causal relationship between anxiety disorders and eating disorders on the risk of female infertility.

Previous observational studies have suggested a potential association between female infertility and psychiatric disorders [6‐9]. and our MR study provides support for some of these findings. Specifically, depression, a complex condition affecting both physical and mental well-being, has been found to be prevalent among infertile women. Prior research has indicated that depression may act as a risk factor for female infertility through various mechanisms, including the suppression of the HPOA, oocyte damage, and apoptosis of ovarian granulosa cells. Studies have highlighted the involvement of the hypothalamic–pituitary–adrenal (HPA) axis in depression, demonstrating abnormal activation of the HPA axis and subsequent release of corticotropin-releasing hormone (CRH). Elevated levels of CRH have been found to inhibit the HPOA by suppressing hypothalamic gonadotropin-releasing hormone (GnRH) release and directly affecting the ovary [30, 31]. Animal studies have shown that CRH can inhibit hypothalamic luteinizing hormone (LH) and stimulate follicle-stimulating hormone (FSH) release in female rats [30]. Additionally, CRH has been found to inhibit estrogen (E₂) production in rat and human granulosa cells [31]. Moreover, CRH induces increased glucocorticoid secretion from the adrenal cortex, and glucocorticoids have been shown to have detrimental effects on oocytes [32]. Experimental studies in female mice have demonstrated that exogenous glucocorticoid injections impair oocyte developmental potential and trigger apoptosis of ovarian granulosa cells and oocytes [33].

Bipolar disorder, another physical disorder, has been associated with lower fertility rates and a higher incidence of infertility in women according to previous research [14, 34]. Women with bipolar disorder often experience menstrual cycle disturbances [35], suggesting an imbalance in steroidal gonadotropic hormones, including reduced levels of estrogen and progesterone and increased levels of testosterone [36, 37]. However, our MR study findings indicate that bipolar disorder is not a risk factor for female infertility. This contradictory result may be attributed to confounding factors present in previous clinical studies and the potential influence of psychiatric medications, such as valproate, on the risk of polycystic ovary syndrome or the abnormal regulation of female steroid hormones due to lithium treatment [38, 39]. Further research is warranted to validate the relationship between bipolar disorder and female infertility.

Our study possesses several notable strengths. Firstly, we employed the MR design, which helps minimize the risk of reverse causation and confounding biases inherent in observational studies. Secondly, we focused on cohorts comprising individuals of European descent to mitigate potential confounding related to population stratification. Lastly, the lower likelihood of exposure to psychiatric disorders among our study subjects enhances the internal validity of our findings.

However, several limitations of our study should be acknowledged. Firstly, the generalizability of our findings to other populations is uncertain since all GWAS data used in our analysis are derived from European populations. Future investigations should include more diverse samples to assess the transferability of phenotypic and genetic associations across ancestry groups. Secondly, to increase the number of SNPs for assessing the causal effects of psychiatric disorders, we utilized a relatively lenient p-value threshold of 5 × 10^–6, potentially incorporating SNPs with weaker associations and smaller effect sizes. Future studies should consider employing stricter p-value thresholds to enhance the reliability and reproducibility of findings. Lastly, although our findings suggest a potential association between depression and female infertility, the lack of relevant data prevented us from conducting a subtype analysis of depression.

The results of our investigation provided limited evidence to support the hypothesis that depression may increase the susceptibility to female infertility. Additionally, our findings indicated that bipolar disorder is not associated with an increased risk of female infertility. These findings imply that interventions targeting emotional well-being could potentially have a positive impact on the prevention and treatment of female infertility. The disparity between our findings and traditional observational studies may be attributed to inherent limitations, including the possibility of reverse causation or residual confounding. Notably, our study offers a novel perspective by employing MR analysis, which effectively addresses these limitations and yields compelling evidence supporting a potential causal relationship between depression and female infertility.