The studies were obtained from four online databases including SCOPUS, Web of Science, PubMed, and Ovid MEDLINE from 1946 until September 2022. The last search was formed on 22^nd September 2022. The search strategy involved the combination (“AND”) of the following keywords: 1) corti* (cortisol, corticosteroid) OR hydrocorti* (hydrocortisone) OR glucocorti* (glucocorticoid); 2) infertil* (infertility, infertile) OR subfertil* (subfertility, subfertile). In addition, the references of all retrieved articles were reviewed for relevant citations.

All full-length original research articles published in the English language and using humans (male or female or both) as subjects that investigated cortisol and infertility were included. For studies involving female subjects, only studies that recruited infertile subjects, and their biological specimens taken prior to a stimulated cycle or during unstimulated or spontaneous cycles were included. Among these, only studies that compared the differences in cortisol levels between fertile and infertile groups, and the pregnancy outcomes of the infertile subjects were included.

Case series, case studies, books, reviews, letters to the editors, animal studies, cell culture studies, and conference abstracts were excluded. Human studies that specifically looked into infertile subjects with neurological or psychiatric comorbidities were excluded.

The articles retrieved from the four databases were independently reviewed by 2 authors (BVK and JK). Any disagreement in the selection process was resolved through discussion to reach a consensus. In general, the articles were screened through three stages. First, articles that did not meet the inclusion criteria were rejected based on their titles. Second, articles that were irrelevant to infertility and cortisol were eliminated based on the abstracts. Third, the remaining articles’ methods, and results were carefully reviewed, and the articles that did not meet the inclusion criteria were eliminated. Reasons for exclusion included (i) if it was not clearly mentioned whether the biological samples to measure cortisol level was taken prior to or after the hormonal stimulation during the infertility treatment, (ii) if the participants were not diagnosed with infertility, (iii) for pre- and post-treatment studies, cortisol level was not assessed prior to treatment, (iv) if the infertile subjects were diagnosed with mood disorders, (v) if the biological samples were taken after induced ovulation, (vi) if the subjects have undergone surgical procedures (varicocelectomy), (vii) infertility patients who were at a stage prior to, during, or after their intrauterine insemination or IVF treatment, (viii) if the biological samples were collected after the embryo transfer, (ix) not reporting absolute cortisol levels.

The study designs that were employed for studies involving male subjects only are case-control prospective studies (17–20), with a total of 400 subjects involving age-matched, healthy fertile controls and infertile subjects. Only one study stated the average age of the participants, infertile (32.4 ± 6.7 years) and fertile (32.7 ± 4.8 to 33.1 ± 5.4 years) (17). Three studies provided the age range of the participants, which was, in general, ranging from 25 to 38 years (18–20) (Table 1). One study recruited 150 subjects from both genders, with their age ranging from 30.9 ± 4.9 to 35.3 ± 3.5 years. The study design employed was prospective (21) (Table 2).

Studies involving female subjects employed designs such as cross-sectional (22, 23), prospective cohort (10), case-control study (24–26), case-control prospective study (7, 27), and prospective study (28–30). The total number of participants recruited was 1102. In general, ten studies reported the average age of the separate groups of patients recruited, such as fertile control (23.5 ± 0.4 to 34 ± 5 years) and infertile group (24.4 ± 0.3 to 33.4 ± 2.3 years) and infertile/pregnant (32.75 ± 5.78 to 36.3 ± 4.76 years) and infertile/non-pregnant (32.94 ± 4.04 to 36.35 ± 3.97 years) (7, 10, 22–29). One study provided the age range of the participants recruited (23-47 years) (30) (Table 3).

The diagnosis or types of infertility specified were diminished ovarian reserve (21), ovulatory disturbance (21), tubal factor (7, 21), unexplained (23, 27), idiopathic hyperprolactinemia (22), oligomenorrhea (25), and endometriosis (21). Some of the studies reported the types of infertility as female factor, male factor, and mixed (24), male factor, female factor, and unexplained (28), primary and secondary (29), normozoospermic infertility (18, 19), oligozoospermia (17, 18), cryptozoospermia (17), azoospermia infertility (17), asthenozoospermia infertility (18), and unknown origin (19). Whereas some studies did not report the diagnosis or types of infertility involved (10, 20, 30) (Table 4).

In general, the infertile females’ mean duration of infertility was ranging from 18.37 months to 8.47 ± 5.83 years. Some studies did not report the duration of infertility (10, 17–20, 22, 25, 29, 30). One of the studies reported the subjects’ duration of the marriage, which was ranging from 8.03 ± 4.68 to 8.47 ± 5.83 years (23). Another study reported the duration of infertility treatment, 3.1 ± 1.6 years, and the period of waiting before the treatment, 4.3 ± 1.5 years (7) (Table 5).

Some studies recruited newly diagnosed infertile patients (10, 17, 20, 21, 23–25). In some studies, infertile patients have already been exposed to infertility treatment in the past (7, 30). Whereas some studies did not report whether the recruited infertile patients were novices or have prior infertility treatment experience (18, 19, 22, 25–27, 29) (Table 6).

Various types of biological samples were collected to assess the cortisol level in the study subjects including serum (7, 10, 18–20, 22, 23, 25–29), saliva (21), and hair (24). Two studies used blood samples but did not specify whether plasma or serum was used for cortisol assessment (17, 30) (Table 7).

Some studies collected the biological specimens in the morning only (7, 10, 17–22, 25, 28, 29), around 0730-0900, upon waking up, and some studies collected samples on multiple time points, such as 15, 30, and 60 minutes after waking up (21). Two studies collected the biological specimens in both morning and evening (18, 19). Whereas some studies did not report the time of biological specimen collection (24, 26, 27) (Table 8).

The results of cortisol levels were reported in numerous units due to differences in the measuring techniques. Some have reported their results in µg/dL (10, 18–20, 26, 27), nmol/L (7, 17, 28), ng/mL (21), g/dL (30), µg/mL (23), µg/L (29), µmol/L (25), pg/mg (24), and nm/L (22) (Table 9).

Techniques employed in the studies to measure the cortisol level were chemiluminescence immunoassay (10, 17), radioimmunoassay (18, 19, 25, 28, 30), enzyme-linked immunosorbent assay (ELISA) (21, 22, 24, 27), liquid chromatography-mass chromatography (23, 29), and dissociation-enhanced lanthanide fluoroimmunoassay (DELFIA) (7). Two studies did not specify the techniques (20, 26) (Table 10).

Some studies specified the time of female biological specimen collection as early follicular phase or luteal phase or ovulation phase or prior to the stimulation day (7, 10, 22, 26–30). Some reported the specimens were taken during the time of recruitment or while on the waiting list for treatment or prior to the beginning of treatment (21, 23–25) (Table 11).

A study that assessed the cortisol levels in both male and female patients found no significant difference in the levels of cortisol among males with conceived and non-conceived female partners following the IVF treatment (21) (Table 12). Four studies evaluated the cortisol levels in infertile male patients only. Among these, three studies reported elevated cortisol levels among infertile males compared to healthy controls (18–20). One study found no significant difference between infertile and healthy controls (17) (Table 13).

Among the studies that recruited female subjects, seven studies compared the cortisol levels between the infertile and fertile female subjects. Out of these, four studies reported elevated cortisol levels in infertile female subjects compared to the fertile group (10, 22, 23, 26). Three studies found no significant difference in the cortisol levels between the fertile and infertile subjects (7, 25, 27) (Table 14). Nine studies measured the cortisol levels prior to treatment or stimulation in infertile subjects that conceived at the end of IVF treatment and those that did not. Two studies reported elevated cortisol levels in infertile female subjects that could not conceive following IVF compared to those who could (10, 26). However, five studies found no significant difference in the cortisol levels between the conceived, infertile female subjects and those did not (7, 24, 28–30). In contrast, one study reported that the median value of cortisol was higher among females that conceived compared to those who did not (21) (Table 15).

Four studies reported changes in blood cortisol levels in healthy fertile and infertile males, with one reporting no significant difference (17), and three found significantly higher cortisol in infertile male patients (18–20). Out of these four studies, only three studies specified the causes of infertility which included normozoospermic, oligozoospermic, cryptozoospermic, azoospermic, asthenozoospermic, and unknown infertility (17, 18). None of the studies reported a significant direct correlation between cortisol levels and infertility characteristics investigated. One study reported higher Beck Depression Inventory (BDI), and State-Trait Anxiety Inventory (STAI-1 and STAI-2) scores to be significantly associated with higher cortisol levels in infertile patients, and BDI score also significantly negatively correlated with sperm count and ejaculate volume. Lower STAI-1 and STAI-2 scores were associated with a higher percentage of sperm with progressive motility (20). A recent systematic review reported mental disorders such as depression, sleep disorders, addiction, eating disorders, and stress negatively impact fertility in males and females (6). It is not within the scope of the present review to relate stress with infertility, nevertheless perceived stress, anxiety, and depression was reported in the past to elevate cortisol level (32, 33).

Harth and Linse (17) found no significant difference in the blood cortisol levels between infertile subjects (normozoospermic, cryptozoospermic, or azoospermic) and a combined cortisol level from Group A (normozoospermic, high prolactin, and stress levels) and Group B (normozoospermic, normal stress and prolactin levels), 580.7 nmol/L (infertile) against 557.4 nmol/L (Group A+B). Nevertheless, earlier reports on prolactin showed that prolactin may directly induce adrenal steroidogenesis, thus increasing the level of cortisol (34, 35). This should be taken into consideration when interpreting the results. In the same study, the cortisol level in Group B subjects was much lower, 478.1 nmol/L, however, no description was given of the individual comparison between group B and C. Harth and Linse (17) recruited participants between the age range of 18-45 years old, a much wider range, whereas the other three studies recruited between the age of 27-33 (20), 30-38 (18), and 25-38 (19) years old participants, with the lowest age being 25 and oldest 38. The average age of the participants recruited by (17) was 32.7 ± 4.8 to 33.1 ± 5.4 years old, whereas the other three studies did not report the participants’ average age. Cortisol is synthesized from cortisone by the enzyme 11β-hydroxysteroid dehydrogenase type 1 (11βBHSD1) and converted to inactive cortisone by 11β-hydroxysteroid dehydrogenase type 2 (11βBHSD2). Age alters the activity of 11βBHSD2 (36). Furthermore, an increase of 17 nmol/L in serum cortisol per year of age was reported. This accounts for approximately 32% of the difference in serum cortisol levels between patients (R2 = 0.315; 36).

Two studies (18, 19) reported the morning cortisol level (10.2 to 10.84 µg/dL) to be higher than the evening cortisol level (5.0 to 5.8 µg/dL) in healthy fertile subjects, which is in line with circadian cortisol rhythmicity reported in the past (37–39). Normozoospermia (18, 19), asthenozoospermia (18), and unknown origin (19) were reported as infertility-related factors in infertile males with higher cortisol. To date, very little literature is available to physiologically link asthenozoospermia to altered cortisol levels. At the preclinical level, asthenozoospermia induced via the inactivation of AMP-activated protein kinase-α1 (AMPKα1) in mice caused no significant changes in plasma cortisol level (40).

Four studies found that the cortisol level in infertile females was significantly higher compared to fertile females (10, 22, 23, 26). Out of this, only one study reported a significant negative correlation between high cortisol (after ovulation) and LH level during ovulation, progesterone level after ovulation, estradiol level during and post-ovulation, follicle size and endometrial thickness during and post-ovulation (10). One study recruited infertile patients with idiopathic hyperprolactinemia hence elevated cortisol levels due to the direct effect of enhanced prolactin on adrenal steroidogenesis should be considered in the interpretation of results (34, 35). Three studies reported no significant difference in the cortisol level (7, 25, 27). All seven studies measured cortisol using serum samples taken in the morning, except for two studies that did not state the time of biological specimen collection (26, 27). In general, studies that reported elevated cortisol levels in infertile females recruited a larger pool of participants (929 subjects in four studies) compared to the studies that reported no significant difference in the cortisol level (117 subjects in three studies). The average age of participants recruited by studies reporting significant differences in the cortisol level (control: 23.6 ± 0.3 to 31.22 ± 6.02; infertile: 24.4 ± 0.3 to 31.13 ± 5.7 years old) is also lower compared to the studies that found no significant difference in the cortisol (control: 32.8 ± 1.2 to 34 ± 5; infertile: 33 ± 4 to 33.4 ± 2.3 years old). Higher age of the control group (in studies that found no significant difference in cortisol level) may have reduced the deficit in the cortisol value between study groups due to the aging-related effects on cortisol value (36, 41).

Two studies reported higher cortisol in infertile/non-pregnant patients (10, 26), however, none of the studies reported a significant association with pregnancy outcomes. Five studies found no significant change in the cortisol level (7, 24, 28–30). Both sets of studies recruited an almost similar pool of participants (525 versus 595 subjects). In general, the average age of participants in studies with elevated cortisol is in their 20s. Infertility factor such as idiopathic hyperprolactinemia (22) was reported in infertile females with elevated cortisol. Hyperandrogenism was reported in PCOS due to dysregulation of 11β-hydroxysteroid dehydrogenase (42, 43).

The menstrual cycle is known to affect the activity of the HPA axis which can result in variation in cortisol synthesis, such as higher cortisol levels during the luteal phase compared to the follicular phase (31). 14 out of 17 selected studies collected the biological specimen for cortisol analysis in the morning, and four studies did not specify the time of collection (10, 17, 20, 30). Physiological cortisol level is usually higher in the morning, especially 30-45 minutes after awakening and gradually reduces for the rest of the day under normal conditions (44).

Eight out of 17 selected studies did not report whether the recruited infertile patients have any prior exposure to IVF treatment procedures. Anticipatory stress was associated with higher stress reactivity for cortisol (45) and higher stress task-induced increase in cortisol (46). Contrary to this, some researchers found no significant association between cortisol awakening response and stress anticipation (47). Furthermore, reports on the effects of stress during and prior to IVF treatment on pregnancy outcomes have been conflicting (48, 49). It will be interesting to see in future studies whether there is a significant difference in stress and stress-related hormones among infertile patients that undergoing ART treatment for the first time and those with prior exposure.

Based on the data we have listed, while high cortisol may have been reported in most of the infertile subjects, this is not always the case (Tables 13–15). It is challenging to ascribe infertility to cortisol levels due to the presence of various other confounding factors. The complex interactions of multiple hormones, each of which plays a specialized role in regulating fertility, make the human reproductive system even more complex. The stress hormone cortisol interacts with this complex hormonal network and has the potential to cause disruptions (50), which is still poorly understood. Finding the precise mechanisms through which cortisol affects infertility is challenging due to the complexity of the hormonal pathways and feedback mechanisms involved in fertility regulation. Nevertheless, a majority of results have linked chronically elevated cortisol levels with disrupted reproductive endocrinology based on observational and correlational data. For instance, excessive amounts of cortisol might interfere with GnRH’s pulsatile release, which controls the menstrual cycle and ovulation. This can result in irregular or absent ovulation and, ultimately, infertility (51, 52). High cortisol levels could inhibit LH and FSH release as well, which affects ovarian function and lowers the likelihood of pregnancy. The menstrual cycle is hampered by increased secretion of cortisol and prolactin in infertile women by lowering pre-ovulatory LH peak and E2 and post-ovulatory E2 levels that alter endometrial development and thus lower the likelihood of conception (10). However, it’s crucial to remember that some people might be more resilient to the effects of cortisol on reproductive function. In line with this, it was reported that psychopathology, stress, and hair cortisol concentration scores were higher for pregnant women with poorer resilience than for those with better resilience (53). The likelihood that someone would experience infertility due to cortisol can depend on a variety of variables, including genetic differences, general health state, and stress resilience. It is difficult to establish a universal link between cortisol and infertility owing to this individual diversity.

In the present review, we noticed a large span in the age difference of the recruited study participants. The relationship between age and infertility is complex, with aging older having a significant role in both men’s and women’s declining fertility (54–56). In women, the quality and quantity of eggs decrease during aging, resulting in a decreased ovarian reserve (57), which leads to a longer time to conceive, decreased fertility, and a higher risk of pregnancy-related complications (58, 59). An increase in paternal age also has an impact on reproductive outcomes in males, affecting sperm volume, motility, and morphological changes that may result in decreased fertility (55). Individuals’ stress response systems may change as they get older (60), which could have an impact on how cortisol is regulated. Age-related changes in cortisol patterns, such as a diurnal cortisol fluctuation (61, 62), or changes in overall cortisol output (63). These alterations may be caused by aging-related effects on the hypothalamic-pituitary-adrenal (HPA) axis, the system that regulates cortisol. The relationship between cortisol and age might be bidirectional. Aging-related elements including long-term underlying illness (64), endocrinological changes (65), or psychological stressors (66) could affect cortisol levels. On the contrary, cortisol dysregulation by itself may hasten aging (67, 68), resulting in a complicated interplay between cortisol levels and age. While cortisol and age can both have an independent impact on fertility, they may also affect fertility synergistically. The delicate hormonal balance required for fertility can also be upset by altered cortisol levels linked to long-term stress or by age-related changes in cortisol regulation (10, 52). Hormonal imbalances brought on by cortisol may make the age-related decline in fertility worse and aid infertility.

Stress has long been thought to affect fertility as well as other areas of general well-being (69). While stress is associated with elevated cortisol (70), proving a direct cause-and-effect relationship between cortisol and fertility is challenging, and thus it necessitates more research. The delicate hormonal balance involved in reproductive processes is thought to be affected by prolonged exposure to elevated cortisol levels, which may affect fertility. Based on existing literature, in both genders, prolonged stress has been associated with diminished reproductive functions (71, 72). Even though cortisol is part of the stress-fertility relationship, it’s vital to understand that fertility is a complex process that governed by a myriad of factors. Stress affects fertility indirectly through psychological and physiological impacts such as change in lifestyle factors (73, 74), sleep quality (75, 76), and sexual behavior (77). Understanding the connection between cortisol and fertility presents a substantial problem in separating the precise effects of cortisol from the general stress response. Individual variation in stress reactions and coping mechanisms further complicates the interpretation of research findings. While some people can handle stress better than others, some may be more susceptible to its negative consequences (78). Furthermore, patients who are diagnosed as infertile suffer from a great deal of emotional instability as a result of their condition, increasing the risk of anxiety, depression, and other mood disorders substantially. Infertility drugs like leuprolide, gonadotropins, and clomiphene can affect the patient’s psychological well-being causing side effects such as irritability, anxiety, and depression. Hence, it is often challenging to distinguish between the psychological impacts of infertility and the adverse effects of the medications when evaluating symptoms in women receiving infertility-related pharmacotherapy (70). Therefore, it is important to note that stress can cause infertility, and vice versa, and given the complexity, pinpointing cortisol’s exact function in the relationship between stress and fertility is challenging at present.