GnRH antagonists followed by a decline in serum estradiol results in adverse outcomes in donor oocyte cycles

S.R. Lindheim1 and A.J. Morales

Fertility Specialist Medical Group, San Diego, California, USA

1 To whom correspondence should be addressed at: University of Wisconsin-Madison, Department of Obstetrics and Gynecology, H4/628 Clinical Science Center, 600 Highland Avenue, Madison, WI 53792, USA. e-mail: doclalalindheim{at}aol.com


    Abstract
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
BACKGROUND: The aim of this retrospective study was to assess clinical outcomes using GnRH antagonists in oocyte donation cycles. METHODS: Between July 2000 and June 2001, 40 recipient cycles generated from donor oocytes were evaluated. Controlled ovarian hyperstimulation (COH) was started on cycle day 2 using recombinant gonadotrophins (225 IU daily). GnRH antagonist was started on cycle day 6 of COH. All recipients were synchronized to donors using GnRH agonist followed by estrogen and progesterone supplementation. Main outcome measures were days of stimulation (DOS), number of ampoules used, peak serum estradiol, number of oocytes, fertilization rate, embryo score, clinical on-going pregnancy rate and implantation rate. RESULTS: Thirty-seven donor cycles (93%) underwent oocyte retrieval, resulting in 36 embryo transfers. Fourteen cycles (35%) had decreased serum estradiol after initiation of GnRH antagonist. No differences were seen in numbers of FSH ampoules, DOS, peak serum estradiol, number of retrieved oocytes, fertilization rate and embryo quality. However, clinical pregnancy rate per initiated cycle [14% (2/14) versus 54% (14/26)], ongoing pregnancy rate per initiated cycle [7% (1/14) versus 46% (12/26)] and implantation rate (4 versus 24%) were all significantly less (P <0.05) following a decrease in serum estradiol after initiation of GnRH antagonist. No clinical predictor, including donor age, basal day 2 FSH or estradiol, ovarian morphology or serum estradiol prior to GnRH antagonist, was predictive of a decline in serum estradiol following GnRH antagonist. CONCLUSION: These data demonstrate an adverse effect on clinical outcome in cycles, resulting in a decline in serum estradiol after GnRH antagonist administration. This effect was unpredictable and provided a simplified protocol for oocyte donation cycles; nonetheless, further study is needed to clarify the adverse effects of GnRH antagonists in oocyte donation cycles.

Key words: controlled ovarian hyperstimulation/GnRH antagonists/IVF/oocyte donation


    Introduction
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
Suppression of the hypothalamic-pituitary axis to prevent a premature LH surge using either GnRH agonists or GnRH antagonists has maximized the outcomes during ovarian hyperstimulation for IVF cycles (Porter et al., 1984Go; Neveu et al., 1987Go; Ganirelix Dose Finding Study Group, 1998Go). The advantages of GnRH antagonists over GnRH agonists include immediate suppression of pituitary gonadotrophins, thereby obviating the prolonged period until pituitary suppression becomes effective. Moreover, gonadotrophin requirements, monitoring costs and the risk of ovarian hyperstimulation syndrome (OHSS) have been reported to be less (de Jong et al., 1998Go; Ganirelix Dose Finding Study Group, 1998Go; The North American Ganirelix Study Group, 2001Go).

However, decreases in serum estradiol, pregnancy rate (PR) and implantation rate (IR) have been reported in GnRH antagonist-stimulated cycles (Ganirelix Dose Finding Study Group, 1998Go; Fauser et al., 1999Go; Felberbaum and Diedrich, 1999Go), suggesting an adverse effect of GnRH antagonists on either oocyte quality, embryo development or the endometrium. Oocyte donation provides a unique model to eliminate confounding variables that typically occur when comparing groups of patients undergoing IVF. The aim of the present study was to gain further insight and present preliminary results using GnRH antagonists in oocyte donation cycles, and also to assess their impact on clinical outcomes.


    Materials and methods
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
A retrospective analysis was made of all GnRH antagonist cycles undergoing IVF-embryo transfer cycles using donated oocytes.

Subjects
Between July 2000 and June 2001, oocyte donors (n = 32) underwent 40 cycles using ovarian hyperstimulation with recombinant FSH (rec-FSH; Follistim; Organon) and GnRH antagonist (Antagon; Organon, Inc., West Orange, NJ, USA). The mean (± SEM) age of all oocyte donors was 27.7 ± 0.7 (range 21–36) years. All donors had normal cycle day 2–3 serum FSH levels (5.0 ± 0.6 mIU/ml) and serum estradiol levels (33.8 ± 2.8 pg/ml). The recipients [n = 31; mean age 43.1 ± 0.7 (range 36–54) years] underwent 40 fresh embryo transfer cycles. Severe male factor (<1 x 106 sperm/ml) and hydrosalpinges were excluded from the evaluation, since the latter has been shown previously adversely to affect implantation in donor oocyte cycles (Cohen et al., 1999Go).

COH protocol
Prior to cycle stimulation, all oocyte donors received 1–2 months treatment with oral contraceptives (Mircette; Organon, Inc.) for cycle synchronization. Following a withdrawal bleed, ovarian stimulation was started on day 2 with three ampoules per day of rec-FSH for the first 4 days of treatment, and adjusted according to ovarian response. From cycle day 6 of stimulation, daily injection of GnRH antagonist (0.25 mg, s.c.) was added. All cycles were monitored using transvaginal ultrasound and serum estradiol levels, starting on cycle day 5 of stimulation. When three or more follicles reached 18–20 mm, hCG was given to trigger ovulation. Transvaginal oocyte aspiration was performed 36 h later, under ultrasound guidance. Recipients were synchronized to an oocyte donor using a regimen of oral micronized estradiol and i.m. progesterone (Sauer et al., 1995Go).

Following fertilization, embryos were assessed and assigned using a standardized scoring system [cell number x symmetry (symmetric = 3; slightly asymmetric = 2; asymmetric = 1) x fragmentation (<10% = 4; 10–20% = 3; 20–30% = 2; >30% = 1)]. After 72 h, the embryos were transferred transcervically to the recipient’s uterus under ultrasound guidance. Pregnancy was confirmed by serial beta-hCG measurement at 9 and 12 days after embryo transfer.

Hormone assays
Serum samples were assayed on cycle day 2 for FSH (DPC, Los Angeles, CA, USA) and estradiol (DPC) using CIA Immulite kits. The intra- and inter-assay coefficients of variation (CV) were 5.4 and 8.1% for FSH, and 6.3 and 6.4% for estradiol.

Statistical analysis
Statistical analyses were performed using the SPSS statistical package. A chi-square and a t-test were used to assess differences between groups, and stepwise logistic regression was used to assess correlations. A P-value < 0.05 was considered statistically significant.

The measured outcomes included dose of gonadotrophins, days of stimulation, serum estradiol levels, number of oocytes, fertilization rate (FR), embryo score, IR and pregnancy rate (PR). Clinical pregnancies were defined as the presence of a fetal heart beat on ultrasonographic examination. Ongoing pregnancies were defined as pregnancies after 12 weeks from the embryo transfer.


    Results
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
Overall, 37 donor cycles underwent oocyte retrieval (93%), and this resulted in 36 (90%) embryo transfers. One cycle was cancelled due to a poor response, and two others surged on the day of retrieval (fluid in cul-de-sac and collapse of dominant follicles). One embryo transfer was not performed due to fluid identified in the uterine cavity on the day of transfer. Numbers of oocytes, FR, numbers of embryos transferred, clinical PR, on-going PR and IR are detailed in Table I. No cases of severe OHSS were encountered.


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Table I. IVF-embryo transfer results for oocyte donors receiving GnRH antagonist
 
Following GnRH antagonist administration, 14 donor cycles (35%) had a decrease in serum estradiol prior to hCG administration. Thirteen of these (93%) showed a decrease in serum estradiol at >3 days after GnRH antagonist administration. When compared to cycles without any decline in serum estradiol (n = 26), no differences in age, day-2 FSH and estradiol and cycle stimulation characteristics (including the number of ampoules used), days of stimulation, cycle day-5, -7, -8 and peak serum estradiol and number of retrieved oocytes were seen (Table II).


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Table II. Comparison of cycle stimulation for oocyte donors receiving GnRH antagonist, and the effect on serum estradiol (E2)
 
The numbers of cases requiring ICSI, as well as FR, embryo transfer score and the number of embryos transferred and cryopreserved, were similar in both groups after GnRH antagonist treatment (Table III). However, the clinical PR per initiated cycle [14% (2/14) versus 54% (14/26), P = 0.05], the ongoing PR per initiated cycle [7% (1/14) versus 46% (12/26)], and IR (4 ± 3% versus 24 ± 5%) (both P < 0.05) were significantly less if the serum estradiol was decreased following the initiation of GnRH antagonist treatment.


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Table III. Comparison of recipient outcomes and effect on serum estradiol (E2) after GnRH antagonist for oocyte donors
 
In a stepwise regression analysis, age, ovarian morphology, baseline FSH, estradiol, days of stimulation, number of ampoules used and cycle day-5 serum estradiol were shown not to be significant predictors of any estradiol response to GnRH antagonist treatment.


    Discussion
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 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
The presence of GnRH receptors outside the pituitary has been identified at the level of the ovarian follicle and endometrium (Dekel et al., 1988Go; Emons et al., 1993Go). It has been suggested that GnRH antagonists have a role in interacting with these extra-pituitary receptors and may adversely impact on folliculogenesis and embryo development, as reflected by lower serum estradiol concentrations, ongoing PR and IR rates compared with conventional GnRH agonist use (Ganirelix Dose Finding Study Group, 1998Go; Fauser et al., 1999Go; Felberbaum and Diedrich, 1999Go).

To discern the impact on folliculogenesis and endometrial level is difficult in conventional IVF cycles. However, the ovum donation model allows for the study of isolated parameters that may affect outcome, by standardizing for embryo quality and endometrial receptivity. Overall, in the present study, a decrease in serum estradiol, which was seen in almost one-third of the cycles, resulted in a significant reduction in pregnancy outcome following GnRH antagonist treatment. While these adverse effects were not seen with respect to cycle stimulation or embryo quality, it still suggests an adverse effect of GnRH antagonists on folliculogenesis and embryo development that cannot be seen morphologically. As such, the plateau or decrease in serum estradiol in the late follicular phase of some cycles may be the result of over-suppression of LH by GnRH antagonists that, seemingly, is important in oocyte maturation of some—but curiously not all—cycles. The specific role of LH in folliculogenesis and oocyte maturation is unclear. However, it is believed that LH is necessary to stimulate androgen substrate by the theca cells (Adashi, 1996Go; Gougeon, 1996Go) and in the late follicular phase acts in synergy with FSH to support follicular growth (Erickson et al., 1979Go). It is possible that the use of gonadotrophins with both LH and FSH preparations would eliminate this effect.

The unpredictable effect of GnRH antagonists is puzzling. Decreases in serum estradiol could not be predicted based on parameters such as age, basal FSH/estradiol, ovarian morphology or cycle day-5 estradiol. Interestingly, eight donors underwent a repeat cycle using the same protocol. Two of these women who had a decrease in serum estradiol following GnRH antagonist treatment in their first cycle resulting in no pregnancies did not show this effect in their second cycle, the results being one spontaneous abortion and one ongoing pregnancy. Three donors who had a normal response in their first cycle that resulted in two ongoing pregnancies, showed a decline in their second cycle that resulted in one spontaneous abortion.

The use of GnRH antagonists has facilitated short and simple treatment, and is particularly attractive for oocyte donors where prolonged pituitary suppression and a risk of OHSS are significant issues. However, such use of GnRH anatagonists has an unpredictable effect on estradiol production during follicular recruitment that appears adversely to affect pregnancy outcome if a decline in serum estradiol occurs. Further study is needed to clarify the effect of GnRH antagonists on serum estradiol, and how this may impact on pregnancy outcomes.


    FOOTNOTES
 
Presented at the 50th Annual Meeting of The Pacific Coast Reproductive Society, April 19–21, 2002.


    References
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
Adashi, E.Y. (1996) The climacteric ovary: an androgen-producing gland. In: Adashi, E.Y., Rock. J.A. and Rosenwaks, Z. (eds), Reproductive Endocrinology, Surgery, and Technology. Volume 2. Lippincott-Raven Publishers, Philadelphia, USA, pp. 1745–1757.

Cohen, M.A., Lindheim, S.R. and Sauer, M.V. (1999) Hydrosalpinges adversely affects implantation in donor oocyte cycles. Hum. Reprod., 14, 1087–1089.[Abstract/Free Full Text]

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Submitted on April 22, 2003; accepted on June 26, 2003.





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