Abstract
Introduction There are numerous conflicting studies which have addressed the question whether the measurement of anti-Müllerian hormone (AMH) concentrations should be done at a certain time during the menstrual cycle. We aimed to investigate AMH fluctuations during the follicular and luteal phases of the menstrual cycle and to determine whether AMH variations, if present, might influence the clinical utility of ovarian reserve markers.
Materials and Methods A total of 257 infertile women eligible for inclusion were categorized into three groups based on their total antral follicle count: 1. hypo-response group (< 7 follicles, n = 66), 2. normo-response group (7 – 19 follicles, n = 98), and 3. hyper-response group (> 19 follicles, n = 93).
Results Mean follicular AMH levels were elevated compared to levels in the luteal phase in all response groups (p < 0.001). There were significant and strong positive correlations between follicular and luteal AMH levels in all response groups (Spearmanʼs r = 0.822, r = 0.836, and r = 0.899, respectively; p < 0.001 for all groups). Fisherʼs Z-test comparisons of these correlations in all response groups demonstrated that there was no statistically significant difference (Z = 0.277, Z = − 1.001, and Z = − 1.425, respectively; p < 0.001).
Conclusion We found that serum AMH levels in the follicular phase were higher than those in the luteal phase in all three response groups. In current practice, fluctuations in serum AMH concentrations are not large enough to alter the timing of AMH measurements during the menstrual cycle. The issue is important for the assessment of ovarian reserve in infertile women with AMH levels near to the cut-off value.
Key words: Anti-Müllerian hormone, AMH, fluctuation, ovarian reserve, variation, measurement
Zusammenfassung
Einleitung Es gibt zahlreiche widersprüchliche Studien, die sich der Frage widmen, ob die Messung des Anti-Müller-Hormon-(AMH-)Spiegels an einem bestimmten Zeitpunkt im Menstruationszyklus durchgeführt werden sollte. Ziel dieser Studie war es, Fluktuationen des Anti-Müller-Hormon-Spiegels während der Follikelphase und der Lutealphase des Menstruationszykluses zu messen, auch um zu bestimmen, ob Fluktuationen des AMH-Spiegels, falls es sie gibt, den klinischen Nutzen als Marker der ovariellen Reserve beeinflussen könnten.
Material und Methoden Insgesamt 257 unfruchtbare Frauen, welche die Einschlusskriterien erfüllten, wurden in die Studien eingeschlossen und in 3 Reaktionsgruppen eingeteilt. Die Einteilung beruhte auf der jeweiligen Gesamtzahl antraler Follikel, wie folgt: 1. Hypo-Gruppe (< 7 Follikel, n = 66), 2. Normalgruppe (7 – 19 Follikel, n = 98), und 3. Hyper-Gruppe (> 19 Follikel, n = 93).
Ergebnisse Verglichen mit der Lutealphase war der durchschnittliche AMH-Spiegel während der Follikelphase in allen 3 Gruppen erhöht (p < 0,001). Es gab eine signifikante und starke positive Korrelation zwischen dem AMH-Spiegel in der Follikelphase und dem AMH-Spiegel in der Lutealphase bei allen Gruppen (Korrelationskoeffizient nach Spearman r = 0,822, r = 0,836 bzw. r = 0,899; p < 0,001 für alle Gruppen). Der Vergleich dieser Korrelationen mithilfe des Fisher-z-Tests zeigte, dass es in keiner der Gruppen einen statistisch signifikanten Unterschied gab (z = 0,277, z = − 1,001 bzw. z = − 1,425; p < 0,001).
Schlussfolgerung Es stellte sich heraus, dass in allen 3 Gruppen der AMH-Spiegel in der Follikelphase höher war als der AMH-Spiegel in der Lutealphase. Die Flukutationen des AMH-Spiegels sind jedoch nicht hoch genug, um den Zeitpunkt der AMH-Messung während des Menstruationszyklus in der aktuellen klinischen Praxis zu ändern. Dieses Thema ist aber für die Evaluierung der ovariellen Reserve von unfruchtbaren Frauen mit AMH-Spiegeln, die nahe beim Cut-off-Wert sind, von Bedeutung.
Schlüsselwörter: Anti-Müller-Hormon, AMH, Fluktuation, ovarielle Reserve, Variation, Messung
Introduction
A reliable assessment of ovarian reserve status is essential when designing strategies for individualized controlled ovarian stimulation, not only for poor- and hyper-responders, but also for women of more advanced age and women who want to delay their pregnancy for numerous reasons. Fertility preservation is an emerging field that encompasses a range of fertility therapies for women facing circumstances that threaten their future reproductive outcomes. Consequently, the assessment of ovarian reserve has become an important aspect of fertility preservation strategies 1 , 2 .
In the current body of literature, various markers of ovarian reserve have been described, including age, estradiol (E2), follicle-stimulating hormone (FSH), inhibin B, antral follicle count (AFC), and anti-Müllerian hormone (AMH) levels 3 , 4 , 5 . Currently, AMH and AFC are thought to be efficient and equivalent predictors, especially in women at the extremes of ovarian reserve status 6 , 7 , 8 , 9 . In daily clinical practice, the choice of ovarian reserve marker depends on several variables, including the clinicʼs organization, the clinicianʼs preference, and a number of specific patient characteristics.
Recently, AFC has been reported to be one of the most accepted predictors for evaluating ovarian reserve 10 , 11 . Many studies have demonstrated that an AFC < 7 is associated with fewer retrieved oocytes 12 and lower pregnancy rates 13 . Moreover, an AFC value of more than 19 may indicate an excessive ovarian response to controlled ovarian stimulation and an increased likelihood of ovarian hyperstimulation syndrome 14 .
AMH is a unique glycoprotein released by the granulosa cells of small growing follicles. AMH expression is initiated by the recruitment of primordial follicles; the highest level of AMH expression is observed in pre-antral and small antral follicles. During the FSH-dependent stages of follicle growth and in atretic follicles, AMH is not secreted into the circulation 15 . Unlike FSH levels, AMH expression has only mild intra- and inter-cycle fluctuations 16 , 17 , 18 . Although previous studies reported a low variability in AMH levels during the menstrual cycle 18 , 19 , 20 , 21 , more recent studies reported a decrease in AMH levels in the luteal phase of menstruation 26 , 27 . Hence, in clinical practice, practitioners have asked whether the measurement of AMH concentrations in serum should be preferably carried out at a specific time in the menstrual cycle.
The present study aimed to investigate AMH fluctuations during the follicular and luteal phases of the menstrual cycle and to determine whether variations in AMH levels, if present, might influence the clinical utility of ovarian reserve markers.
Materials and Methods
Study design
This cross-sectional study was conducted at the Reproductive Endocrinology Department of Hitit University Hospital between 1 February 2015 and 20 December 2015. The ethics committee of Ankara Numune Hospital approved this project in accordance with the 2013 Declaration of Helsinki (20796219-724.087). After obtaining the informed consent of patients, women ranging in age from 18 to 38 were given a questionnaire to identify their eligibility for inclusion in the study.
Exclusion criteria were gestation, breastfeeding, premature ovarian insufficiency, current medication use, interventions and systemic diseases known to affect reproductive functions, hyperprolactinemia, ovarian surgery, hysterectomy and/or oophorectomy, endometriosis, ovarian masses, severe obesity (body mass index [BMI] ≥ 35 kg/m 2 ), and smoking. A level of midluteal progesterone > 3 ng/dL was taken in all participants to be an indicator of ovulation.
All participants underwent a physical examination, and weight, height and waist circumference (WC) measurements were obtained from all participating patients. Body mass index (BMI) was calculated by dividing the weight in kilograms by the height in meters squared. WC measurements were obtained at the level of the iliac process and the umbilicus, with the same scale used to assess abdominal obesity. During routine pelvic evaluation, AFC was evaluated using ultrasonography (Toshiba Xario 100, Toshiba Medical Systems Corporation, Nasu, Japan) with a 7.5-MHz vaginal transducer; ultrasonography was carried out by the same clinician on days 2 – 5 of the menstrual cycle.
A total of 257 infertile women eligible for inclusion were categorized into three groups, based on their total AFC, an ovarian response pattern marker, as follows:
hypo-response group (< 7 follicles, n = 66),
normo-response group (7 – 19 follicles, n = 98), and
hyper-response group (> 19 follicles, n = 93).
Specimen collection and assays
After an overnight fast, blood samples were drawn from the participants between the hours of 08:00 and 10:00 on days 2 – 5 of their menstrual cycle to obtain follicular AMH (F-AMH), E2 and FSH values. Blood samples were also drawn one week before the expected onset of menstruation to obtain luteal AMH (L-AMH) values in the same menstrual cycle. The blood samples were left to clot completely at room temperature for 30 min before centrifugation at 1500 × g for 4 min. The serum specimens for E2 and FSH were analyzed daily by electrochemiluminescence immunoassay (ECLIA) using an autoanalyzer (Cobas 6000, E 601 Roche Diagnostics GmbH, Mannheim, Germany). The sera for both follicular and luteal AMH were frozen at − 20 °C within 2 h for a maximum of one week. All assays of serum samples to measure AMH levels were also carried out according to a weekly schedule in accordance with the manufacturerʼs guidelines and using the AMH Gen II enzyme-linked immunosorbent assay (ELISA) from Beckman Coulter (Beckman Coulter, Co. Clare, Ireland).
Statistical analysis
All data were analyzed using SPSS (Statistical Package for the Social Sciences) version 21 (SPSS Inc., Chicago, IL, USA). Continuous variables were first evaluated using the Kolmogorov-Smirnov test for normality distribution. Because continuous variables were not normally distributed, non-parametric tests were used for statistical analysis. Descriptive data are given as mean (± standard deviation) and figures (%). Data from the three AFC groups were compared using one-way analysis of variance (ANOVA) with post-hoc analysis. Spearmanʼs correlation was used to determine if there was any linear relationship between AMH levels and other study variables. The correlation coefficients were compared using Fisherʼs Z-test. A p-value < 0.05 and a confidence interval of 95% were considered statistically significant.
Results
Baseline clinical and biochemical characteristics
A total of 257 infertile women were included in this study. The comparisons of clinical and biochemical characteristics of all ovarian response groups are presented in Table 1 . Based on their AFC categorization, the mean age of the hypo-responder group was 35.5 (± 3.1) years; the normo-responder and hyper-responder groups had mean ages of 28.3 (± 5.0) and 27.6 (± 4.7), respectively (p < 0.001). Characteristics such as BMI, WC, and duration of infertility were statistically similar for the hypo-, normo-, and hyper-response groups (p = 0.879, p = 0.738, and p = 0.318, respectively).
Ovarian response groups | ||||
---|---|---|---|---|
Hypo-responders AFC < 7 (n = 66, 25.7%) |
Normo-responders AFC 7 – 19 (n = 98, 38.1%) |
Hyper-responders AFC > 19 (n = 93, 36.2%) |
p | |
Values are shown as mean (± standard deviation). BMI: body mass index; WC: waist circumference; F-AMH: follicular anti-Müllerian hormone; L-AMH: luteal anti-Müllerian hormone; E2: estradiol; FSH: follicular stimulating hormone; AFC: antral follicle count. * p-value is statistically significant (p < 0.05). | ||||
Age (years) | 35.5 (± 3.1) | 28.3 (± 5.0) | 27.6 (± 4.7) | < 0.001* |
BMI (kg/m 2 ) | 26.3 (± 4.1) | 26.4 (± 5.5) | 26.0 (± 4.9) | 0.879 |
WC (cm) | 90.9 (± 9.5) | 89.0 (± 12.2) | 90.0 (± 15.5) | 0.738 |
Duration of infertility (weeks) | 52.7 (± 56.4) | 45.3 (± 42.3) | 39.4 (± 36.2) | 0.318 |
E2 (pg/mL) | 53.5 (± 31.4) | 42.5 (± 20.5) | 39.7 (± 22.0) | 0.065 |
FSH (IU/L) | 9.0 (± 2.7) | 6.8 (± 1.2) | 6.3 (± 2.0) | < 0.001* |
F-AMH (ng/dL) | 1.3 (± 1.7) | 3.4 (± 1.8) | 7.3 (± 4.6) | < 0.001* |
L-AMH (ng/dL) | 1.1 (± 1.2) | 2.63 (± 1.63) | 5.95 (± 3.54) | < 0.001* |
AFC | 6.0 (± 1.5) | 12.51 (± 3.46) | 28.03 (± 3.78) | < 0.001* |
With regard to biochemical characteristics, there was no difference in mean E2 levels for all three groups (p = 0.065). As could be expected, the hypo-responder group had a higher FSH concentration (p < 0.001) compared to the other ovarian response groups, and the mean AFC was higher in the hyper-responder group in comparison to the other ovarian response groups (p < 0.001). Mean follicular and luteal AMH levels were found to be elevated in hyper-responder women (p < 0.001, for all groups).
AMH levels in the respective ovarian response groups
Comparisons of serum AMH concentrations during the follicular and luteal phases of the menstrual cycle and comparisons between the three response groups are presented in Table 2 . Significant differences were found in the F-AMH and L-AMH levels of women in the hypo-, normo- and hyper-response groups (p < 0.001, for all groups). The mean F-AMH levels in all response groups were elevated compared to the mean F-AMH levels in the luteal phase (p < 0.001).
All subjects (n = 171, 100%) | Hypo-responders AFC < 7 (n = 66, 25.7%) |
Normo-responders AFC 7 – 19 (n = 98, 38.1%) |
Hyper-responders AFC > 19 (n = 93, 36.2%) |
p-value | |
---|---|---|---|---|---|
Values are shown as mean (± standard deviation). F-AMH: follicular anti-Müllerian hormone; L-AMH: luteal anti-Müllerian hormone; AFC: antral follicle count. * p-value is statistically significant (p < 0.05). | |||||
F-AMH | 4.3 (± 3.9) | 1.3 (± 1.7) | 3.4 (± 1.8) | 7.3 (± 4.6) | < 0.001* |
L-AMH | 3.5 (± 3.1) | 1.1 (± 1.2) | 2.6 (± 1.6) | 6.0 (± 3.5) | < 0.001* |
Spearmanʼs correlation (r) | 0.928 | 0.852 | 0.836 | 0.899 | |
p-value | < 0.001* | < 0.001* | < 0.001* | < 0.001* |
Correlations of biochemical parameters in the ovarian reserve groups
Table 3 shows the correlation matrix for the biochemical parameters of each ovarian response group. There were significant and strong positive correlations between follicular AMH levels and luteal AMH levels of women in the hypo-, normo-, and hyper-response groups (Spearmanʼs r = 0.822, r = 0.836, and r = 0.899, respectively; p < 0.001 for all groups). However, as shown in Table 4 , Fisherʼs Z-test comparisons of these correlations in all response groups demonstrated that there was no statistically significant difference (Z = 0.277, Z = − 1.001, and Z = − 1.425, respectively; p < 0.001 for all groups). In other words, the differences in the correlation coefficients of all ovarian response groups were statistically similar for all ovarian response groups.
Ovarian response groups | F-AMH | L-AMH | E2 | FSH | |
---|---|---|---|---|---|
Values are shown as Spearmanʼs correlation coefficients (r). F-AMH: follicular anti-Müllerian hormone; L-AMH: luteal anti-Müllerian hormone; E2: estradiol; FSH: follicular stimulating hormone; AFC: antral follicle count. * p-value is statistically significant (p < 0.05). | |||||
Hypo-responders AFC < 7 (n = 66, 25.7%) |
F-AMH | 1.000 | |||
L-AMH | 0.852* | 1.000 | |||
E2 | 0.210 | 0.164 | 1.000 | ||
FSH | − 0.241 | − 0.258 | − 0.229 | 1.000 | |
Normo-responders AFC 7 – 19 (n = 98, 38.1%) |
F-AMH | 1.000 | |||
L-AMH | 0.836* | 1.000 | |||
E2 | − 0.035 | − 0.061 | 1.000 | ||
FSH | − 0.020 | − 0.155 | − 0.130 | 1.000 | |
Hyper-responders AFC > 19 (n = 93, 36.2%) |
F-AMH | 1.000 | |||
L-AMH | 0.899* | 1.000 | |||
E2 | − 0.210 | − 0.202 | 1.000 | ||
FSH | 0.022 | 0.037 | − 0.087 | 1.000 |
Correlation coefficients | Comparison of hypo- and normo-responders | Comparison of hypo- and hyper-responders | Comparison of normo- and hyper-responders | |
---|---|---|---|---|
Values are shown as Spearmanʼs correlation coefficient (r) and Fisherʼs Z-values. AFC: antral follicle count. * p-value is statistically significant (p < 0.05). | ||||
Hypo-responders AFC < 7 (n = 66, 25.7%) |
r = 0,852* Z = 1.26 |
Z = 0.277 p > 0.01 |
Z = − 1.001 p > 0.01 |
Z = − 1.425 p > 0.01 |
Normo-responders AFC 7 – 19 (n = 98, 38.1%) |
r = 0,836* Z = 1.21 |
|||
Hyper-responders AFC > 19 (n = 93, 36.2%) |
r = 0,899* Z = 1.47 |
Discussion
Our study mainly focused on whether serum AMH levels exhibit any variability throughout the follicular and luteal phases of the menstrual cycle in infertile women with different ovarian response patterns and whether AMH variation, if present, might have an impact on clinical practice with regard to the timing of AMH measurement. Our evidence revealed that mean AMH concentrations in the follicular phase were markedly elevated compared to mean L-AMH concentrations in the hypo-, normo-, and hyper-response groups. F-AMH and L-AMH were also strongly and positively correlated in all three groups. There was no statistically significant difference with regard to correlation in all response groups.
As previously emphasized, the existing literature has provided no consistent information about intracyclic AMH variation. La Marca et al. 24 performed AMH measurements independently of the day of the menstrual cycle; in their study, they noted that serum AMH levels did not differ across the menstrual cycle. Other investigators reported similar findings 18 , 19 . Some researchers have thought that either no AMH variation occurs during the menstrual cycle or that the variation is minimal 25 , 26 . In contrast, we have concluded that AMH fluctuates greatly across the menstrual cycle.
Numerous studies have investigated intracyclic AMH variations during the menstrual cycle. Although there are discrepancies in previous studies with regard to the timing of serum AMH concentrations, extreme values during the menstrual cycle, the pattern of variation, and the statistical significance, some degree of variation in AMH levels between different phases of the menstrual cycle has been reported 26 . In other published studies, a peak AMH level was observed in the mid-follicular phase; AMH levels then started to decline prior to a rise in serum E2 and reached their nadir in the early luteal phase 25 , 27 . In a recent study by Randolph et al., a biphasic pattern with an elevation and depression in both the follicular and the luteal phases was found in healthy premenopausal women 28 . Others have reported that serum AMH rises steadily and then declines during the entire luteal phase in premenopausal women. Hadlow et al. also investigated AMH fluctuations in infertile women. In line with our results, the authors reported that the mean AMH concentration was significantly depressed in the luteal phase of menstruation 22 .
In a study by Sowers et al. with a very small sample size (n = 20), serum AMH levels were shown to fluctuate throughout the menstrual cycle 23 . Women with low AMH levels had small fluctuations, while women with high AMH levels exhibited relatively high fluctuations throughout the menstrual cycle. The authors described the fluctuating AMH levels as “aging ovary” and “younger ovary” patterns 25 . The same younger ovary pattern was also reported by Wunder et al. 25 . In contrast, we did not observe that pattern of variation in our study. In fact, all ovarian response groups exhibited significant variations in AMH levels in different phases of the menstrual cycle.
The reliability of the findings reported in previous studies on AMH fluctuations may be influenced by inappropriate sample processing and storage. Therefore, those findings should be considered critically. Numerous studies in the existing literature have reported findings on AMH variability utilizing AMH samples frozen at − 80 °C. However, Kumar et al. reported only minimal variation in samples when frozen at − 20 °C for a period of seven days 29 . The most significant fluctuations appeared to occur when entire blood samples were kept at room temperature for a long period of time. Some authors have proposed that the average variation between fresh samples and samples stored for 7 days at room temperature was nearly 4%, and that it was 1% in frozen samples 29 . At present, the discrepancies in existing studies may be explained by variations in serum sample collection, processing and storage 30 . Consequently, our study was done using an optimal methodology based on current evidence.
La Marca et al. published a review on AMH variations in normal women 16 . The authors stated that fluctuations in AMH levels throughout the menstrual cycle appear to be random and minor, and that AMH can be measured independently of the cycle phase. They also criticized a study by Hadlow et al., declaring that the study was based on a very small group of subjects (n = 12) 26 . However, our study was conducted with a greater number of participants (n = 257). We also demonstrated a substantial fluctuation in AMH levels across the menstrual cycle in contrast to the review by La Marca et al 16 . It appears that AMH fluctuations are similarly clinically relevant for women with all types of ovarian response.
While real ovarian reserve does not vary throughout a natural cycle or between consecutive cycles of menstruation, the serum AMH level fluctuates, presumably due to biological variations and atypical AMH isoforms 31 . AMH that may be partially responsive to gonadotropins may also contribute to a variety of biological variations 32 . It has also been reported that gonadotropins may participate in stimulating the gonadotropin-dependent follicles and the AMH level 33 . Depmann et al. stated that variations in peripheral AMH levels throughout the menstrual cycle occur in parallel with AFC variations. This implies that intracyclic AMH variations may be due to changes in the number of antral follicles 34 .
One strength of this study is that the study population consisted of infertile women, because the assessment of ovarian reserve is considered to be essential for predicting controlled ovarian stimulation in infertile women. Another strength is that a relatively large number of participants were included in the study. A major limitation of the study is the limited number of AMH measurements obtained throughout the menstrual cycle (only two measurements).
In conclusion, our study revealed significant fluctuations in serum AMH levels between the follicular and luteal phases of the menstrual cycle. Serum AMH levels in the follicular phase were higher than those in the luteal phase in infertile women with hypo-, normo-, and hyper-response patterns. However, these AMH fluctuations were not statistically significant, so it was not possible to propose an optimal time for AMH measurement. The fluctuations in serum AMH concentrations observed in our study were not large enough to modify the timing of AMH measurement during the menstrual cycle in current clinical practice. The statistically significant changes during the menstrual cycle support the need for a greater understanding of potential AMH changes in normal follicles. Most importantly, the issue may play a critical role in the assessment of ovarian reserve in infertile women with an AMH level that is near the cut-off value. Thus, further largescale prospective studies and meta-analyses are warranted to determine the optimal time for AMH measurement.
Acknowledgements
The authors would like acknowledge the contributions of the staff of the Reproductive Endocrinology Unit of Hitit University.
Footnotes
Conflict of Interest The authors declare that they have no conflict of interest.
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