1 IVF Unit, Department of Obstetrics and Gynecology, and 2 Institute of Hormone Research, Shaare-Zedek Medical Center, Ben Gurion University of the Negev, Jerusalem, Israel
3 To whom correspondence should be addressed at: Department of Obstetrics and Gynecology, Shaare-Zedek Medical Center, Jerusalem 91031, Israel. Email: gevat{at}szmc.org.il
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Abstract |
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Key words: anti-Mullerian hormone/controlled ovarian hyperstimulation/hyperandrogenism/polycystic ovaries
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Introduction |
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Serum AMH level is strongly correlated with the number of antral follicles and is more strongly related to ovarian reserve than other known markers such as day 3 FSH, inhibin B or estradiol (de Vet et al., 2002; Seifer et al., 2002; van Rooij et al., 2002
; Fanchin et al., 2003a
). Women with polycystic ovary syndrome (PCOS) have higher serum AMH levels than normal controls (Fallat et al., 1997
; Cook et al., 2002
; Pigny et al., 2003
; La Marca et al., 2004a
; Laven et al., 2004
). This is presumably related to the increased number of small antral follicles in PCOS. However, the diagnosis of PCOS in these studies was usually based on the Rotterdam consensus (Rotterdam ESHRE/ASRM Sponsored PCOS Consensus Workshop Group, 2004
), where only two out of three criteriahyperandrogenism, typical ultrasonic ovarian morphology and oligo- or amenorrhoeawere needed for the diagnosis. Therefore, they did not differentiate between women with or without hyperandrogenism. Women with PCOS were reported to have higher AMH serum levels than other WHO 2 infertile women (Laven et al., 2004
). PCOS women, however, have both increased serum androgens and higher number of small antral follicles. Moreover, although serum AMH levels were positively correlated with the number of small antral follicles (Pigny et al., 2003
; Laven et al., 2004
), controversies existed as to the correlation with serum androgens.
Serum AMH levels decline gradually during controlled ovarian hyperstimulation (COH), whereas other hormones such as estradiol, inhibin A, inhibin B and progesterone increase (Fanchin et al., 2003b; La Marca et al., 2004
b
). It has been suggested that this reflected the reduction in the number of small antral follicles in parallel to the increase in the number of larger ones. Hawever, serum levels of androgens, such as androstenedione and testosterone, also increase during COH (Hamori et al., 1992
; Martin et al., 1997
; Fanchin et al., 2003b
). To gain further insight into the relationship between ovarian androgens, folliculogenesis and AMH secretion, we investigated AMH levels during COH in women having PCO with or without hyperandrogenism, and compared them with normal controls.
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Materials and methods |
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Twenty-nine women were diagnosed with PCOS according to the Rotterdam consensus (Rotterdam ESHRE/ASRM Sponsored PCOS Consensus Workshop Group, 2004). They had oligo- or amenorrhoea and at least 12 follicles 29 mm in diameter per ovary. Nineteen of the women had hyperandrogenism (testosterone >3 nmol/l, free androgen index >4.5 and/or androstenedione >12 nmol/l) (group A, PCO with hyperandrogenism) and 10 women had normal serum androgens levels and no clinical hyperandrogenism (group B, PCO without hyperandrogenism). Twenty-three women had normal ovulatory cycles, no endocrine abnormalities (normal TSH, prolactin, day 3 FSH and estradiol, and no hyperandrogenism) and normal ultrasonic ovarian morphology (group C, controls).
The women were treated with the long down-regulation protocol consisting of Decapeptyl Depot 3.75 mg (Ferring Ltd, Herzliya, Israel) intramuscularly starting in the midluteal phase or on the 16th day of using contraceptive pills. Ovarian stimulation was commenced after at least 2 weeks, when estradiol levels were <150 pmol/l and ovarian cysts were excluded by vaginal ultrasound. The standard protocol consisted of one ampoule of HMG (Menogon; Ferring Ltd) and 150 IU recombinant FSH (Gonal F; Serono, Herzliya, Israel). The standard protocol was modified when there was a previous history of poor response or a risk of hyperstimulation. Ultrasound for follicular tracking and blood sampling for estradiol levels were performed every 23 days. After the first 35 treatment days, the daily dose could be adjusted based on the follicular development and estradiol levels, and 10 000 IU HCG (Pregnyl; Organon, Petach Tiqva, Israel) was administered when at least three follicles with a diameter of 17 mm were detected. Oocyte retrieval was performed 36 h later. Up to three embryos were transferred 4872 h later.
Basal hormone levels were determined on day 34 of spontaneous or induced menses. Insulin levels were measured after fasting for at least 8 h. Blood samples were obtained on the day in which pituitary desensitization was confirmed, before starting gonadotropins treatment (day 0) and every 23 days from the third day of gonadotropins treatment up to the day of HCG administration. Serum was stored at 70 °C until assayed for AMH and androstenedione concentrations. Serum androstenedione was measured on day 0 and day of HCG.
Serum levels of estradiol, androstenedione, testosterone, FSH, LH and sex hormone binding globulin (SHBG) levels were measured using Immulite 2000 (Diagnostic Products Corp, Los Angeles, CA, USA). Insulin was measured using ADVIA Centaur (Bayer Corporation, Tarrytown, NY, USA). Free androgen index was calculated as: 100 x total testosterone (nmol/l)/SHBG (nmol/l). AMH was measured using a commercially available ultrasensitive two-site ELISA (Immunotech-Coulter, Marseilles, France). The assay sensitivity was 0.7 pmol/l. Inter- and intra-assay coefficients of variation were 8.7% and 5.3%, respectively.
Statistical analysis was performed using Student's t-test and the MannWhitney U-test as appropriate. Longitudinal changes between the three groups were assayed using KruskalWallis one-way analysis of variance by ranks, Cuzick test for trend and Pee-Freedman test for all strata trend. Relationship between day 0 AMH and other data was assayed using univariate and multivariate linear regression analyses. A P-value <0.05 was considered statistically significant.
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Results |
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Highly significant (P<0.001) positive correlations were found between day 0 AMH and androgens (testosterone and free androgen index), the number of small follicles, the number of oocytes per total FSH dose and AMH on the day of HCG administration, whilst negative correlation were found with the total FSH dose (Table III; Figures 2 and 3). Day 0 AMH showed significant, but lower (P<0.010.05), positive correlations with LH and androstenedione, and negative correlations with patient's age and FSH. When calculated separately, the above correlations in the controls (group C) and the PCO women (groups A & B together) were usually similar, excluding the number of oocytes and maximal stradiol, which correlated with AMH only in the control group (Table III). The correlation between day 0 AMH and testosterone in the control group was 0.44 (P<0.05). On the day of HCG administration, serum AMH showed highly significant correlations with both the number of small follicles and androstenedione/estradiol ratio (Figure 4). The correlation between the proportional changes in AMH levels during stimulation and the proportional changes in the number of small follicles was not significant (r=0.26).
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Discussion |
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In accordance with previous studies, we found that women with PCO have significantly higher serum AMH levels (Fallat et al., 1997; Cook et al., 2002
; Pigny et al., 2003
; La Marca et al., 2004a
; Laven et al., 2004
) and that AMH was associated with the number of small antral follicles (van Rooij et al., 2002
; Laven et al., 2004
). Our results are in agreement with those of Pigny et al. (2003)
, showing no significant correlations between AMH and BMI or fasting insulin. However when comparing PCO patients with and without hyperandrogenism, we found that in women with polycystic ovaries, hyperandrogenism was associated with an additional increase in AMH. Furthermore, using multiple regression analysis we showed that both the number of small follicles and serum testosterone levels were independently related to the levels of serum AMH.
Using univariate regression analysis, two previous studies also found significant correlations between serum AMH and androgens in PCOS (Pigny et al., 2003; Laven et al., 2004
). However, two small studies found no such correlations in either PCOS or normal women (Cook et al., 2002
; La Marca et al., 2004a
), while one study found no correlations in normal ovulatory women after GnRH agonist suppression (Fanchin et al., 2003b
). The reasons for the differences between the findings are unclear, although the study populations differ in their number, mean age, basal FSH levels, BMI, previous hormonal treatment (pill, GnRH agonist) and possibly other unknown factors. Still, our results are different from those of Pigny and colleagues, who used multiple regression analysis to show that only the number of 25 mm follicles, but not androgens, was significantly related to AMH in PCOS women (Pigny et al., 2003
). We found that the number of both small follicles and serum androgens were correlated to AMH, in the whole group of patients and in each group (PCO and controls) separately (Table III). However, in the study by Pigny and colleagues, of the 59 PCOS women tested, 29% had no hyperandrogenism and 20% had no menses abnormalities. In addition, the mean number of follicles 29 mm in both ovaries was 16.6 (1090th percentiles 10.828.5), compared with 29.2 ± 12.7 and 26.4 ± 9.2 (mean ± SD) in groups A and B, respectively, in our study (Table II).
We found that serum AMH levels decreased significantly during ovarian stimulation, in accordance with previous studies (Fanchin et al., 2003b; La Marca et al., 2004
b
). Fanchin and colleagues assumed that the gradual decrease in serum AMH during COH probably reflected the reduction in the number of small antral follicles following gonadotropins treatment. However, in our study, despite similar numbers of small follicles in the two groups of PCO women, AMH levels were significantly higher throughout COH in women with hyperandrogenism. Recently, La Marca and colleagues reported that although AMH plasma levels did not change significantly during the follicular phase in spontaneous cycles, its levels decreased progressively in FSH-treated cycles (La Marca et al., 2004
b
). They found significant positive correlations between the decrease in AMH and the increase in estradiol plasma levels in FSH-treated cycles and between basal AMH and the peak estradiol during exogenous FSH administration, similar to our findings. They assumed that the decrease in AMH serum levels following exogenous FSH administration was probably secondary to the gonadotropin effect on the process of follicular development. However, Baarends and coworkers showed that treating prepubertal rats with GnRH antagonist and either FSH or estradiol resulted in inhibition of AMH mRNA and AMH-receptor-II mRNA expression in preantral and small antral follicles (Baarends et al., 1995
). Cook and coworkers also showed an inverse correlation between serum levels of AMH and estradiol in PCOS, but not in normal women (Cook et al., 2002
). In our study, serum estradiol levels during COH were similar between the three groups, but the serum androstenedione/estradiol ratio was significantly higher in the women with hyperandrogenism (Table II), and was positively correlated with AMH (r=0.71; P<0.001; Table III). Furthermore, the decrease in mean serum AMH was lower in PCO patient with hyperandrogenism (group A, 35±24%) compared with PCOS without hyperandrogenism (group B, 60 ± 25%) or to the controls (group C, 71 ± 18%). We speculate that the gradual increase in intraovarian androgen/estradiol ratio during COH may reduce AMH secretion. This ratio is lower in follicular fluid from small follicles in PCOS women compared with size-matched follicles from women with normal ovaries (Eden et al., 1990
; Teissier et al., 2000
), and may restrain the decrease in AMH.
The role of androgens in preantral follicle development is still unclear. However, it has been hypothesized that intraovarian hyperandrogenism can prompt the increased number of early stages follicles. Hyperandrogenism of extra-ovarian origin, e.g. congenital adrenal hyperplasia, virilizing tumors and especially high-dose exogenous androgen treatment, can cause PCO-like ovarian morphology in women (Pache et al., 1991) and in the androgenized monkey model (Vendola et al., 1998
). The trophic effect of androgens predominates in granulosa cells within small follicles due to their richness in androgen receptors (Hillier et al. 1997
). Our results support the assumption that hyperandrogenism may instigate the increased number of preantral and small antral follicles, leading to increased AMH secretion, which cause refractoriness to FSH-induced follicle differentiation seen in PCOS.
In conclusion, we have demonstrated that AMH levels declined gradually throughout gonadotropins treatment in all women, that women with polycystic ovaries retained significantly higher serum AMH levels during COH than controls, and that hyperandrogenism was associated with an additional increase in AMH. It is conceivable that hyperandrogenism may reflect more severe disruption of folliculogenesis in women with polycystic ovaries, expressed as an increase in the number of preantral (in addition to the small antral) follicles, or may directly affect AMH secretion from ovarian granulosa cells. We recognize that the association between serum AMH and androgens does not necessarily infer a cause and effect. In-vitro studies may help to further understand the causal relationships between androgens and AMH.
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Acknowledgements |
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References |
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Submitted on December 29, 2004; resubmitted on February 13, 2005; accepted on February 23, 2005.