Background
In assisted reproduction, the selection of sperm, oocytes, and embryos to achieve better clinical results are important tasks for the embryologist. This goal has particular relevance when religious, ethical, or legal considerations limit embryo selection after fertilization. The morphological evaluation of oocytes, although subjective, is still the standard criterion to help identify the cells with the greatest potential for development. The denudation step not only allows for the evaluation of oocyte maturity by identifying the first polar body but also allows for morphological assessment of the zona pellucida, perivitelline space, and cytoplasm [
1]. Oocyte dysmorphisms may occur due to age, genetic changes, and factors related to the treatment itself, including the ovarian stimulation and the hormonal environment to which the oocyte is exposed [
2‐
4].
The first therapeutic uses of
in vitro fertilization (IVF) were performed in natural cycles without ovarian stimulation. However, there is currently a consensus that better results are obtained with the induction of ovulation. Thus, different protocols are being developed, many of which rely primarily on the administration of gonadotropins to induce multifollicular development, thus increasing the number of available oocytes and thereby the number of developing embryos to be selected and transferred. However, the induction of ovulation might induce a premature surge in luteinizing hormone (LH), which would cause premature luteinization or ovulation and thereby prevent the collection of oocytes [
5‐
9].
Both agonist and antagonist analogues of the gonadotropin-releasing hormone (GnRH) play an important role in reducing the incidence of premature LH surges by reversibly blocking the secretion of pituitary gonadotropins. It is estimated that without the use of GnRH analogues, a surge in LH occurs after approximately 20% of all IVF cycles/intracytoplasmic sperm injections (ICSI) [
10,
11]. As a result, the frequency of cancelled assisted conception cycles has decreased and pregnancy rates have increased. GnRH agonists (GnRH-a) have been used in assisted reproduction treatments since the 1980s. They suppress the release of gonadotropins, including follicle-stimulating hormone (FSH) and LH, by desensitizing pituitary receptors, a phenomenon called “down-regulation” [
8,
12]. GnRH antagonists (GnRH-ant) have only recently (since the late 1990s) been used as part of the therapeutic arsenal in the field of assisted reproduction [
13]. They act by directly binding the GnRH receptors and block them in a competitive manner [
8]. Thus, GnRH-ant cause an immediate, reversible, and rapid suppression of gonadotropin release [
6,
8,
12,
14].
Although it is accompanied by some disadvantages, GnRH-a have become well accepted in clinical practice, and their use is associated with an increase in the rate of pregnancy [
15]. The development of GnRH-ant capable of blocking the pituitary receptors offered a new therapeutic option. Comparative studies between the two analogues have suggested that the use of antagonists is associated with a shorter duration of the ovulatory stimulus and a decreased incidence of ovarian hyperstimulation syndrome; however, the rates of pregnancy and live birth do not appear to be significantly affected, depending on the type of GnRH analogue used [
15‐
20]. Takahashi et al. [
21] found that the use of a GnRH-ant in controlled ovarian hyperstimulation improves the outcome of pregnancy in patients who have experienced several failed IVF/ICSI cycles under a GnRH-a protocol, most likely due to an improvement in the quality of the blastocysts generated. However, GnRH-a has applications in assisted reproductive technology cycles other than the down-regulation of pituitary receptors [
15,
22,
23].
Although the human ovary expresses GnRH receptors, the mechanism of the action of GnRH on the ovary remains controversial and is not completely understood. Thus, when GnRH analogues are used in IVF cycles, their mechanism of action on the oocytes is unknown. GnRH receptors are found in the luteal cells and granulosa cells of the antral follicles but not in primordial and pre-antral follicles [
24,
25]. The correlation between the expression of GnRH receptors and the stage of follicular development suggests a direct influence of GnRH on folliculogenesis and oocyte development. Unfortunately, there are only a few studies on the possible action of GnRH analogues on oocyte phenotype [
1,
4,
26]. Those results that have been published are often contradictory.
To better understand the effects of GnRH analogues on the ovaries, the objective of this prospective, randomized study was to evaluate whether the prevalence of oocyte dysmorphism is influenced by the type of pituitary suppression (GnRH-a or GnRH-ant) used in ovarian stimulation.
Results
Basic demographic characteristics, such as maternal age, BMI, duration of infertility, smoking, alcohol use, and infertility etiology, were not significantly different (
P ≫ 0.05) between the GnRH-a and GnRH-ant patient groups. The distribution (
P ≫ 0.05) of the main characteristics of the ovarian stimulation cycle observed for the GnRH-a and GnRH-ant groups was equal. These data are summarized in Table
1.
Table 1
The basic demographic characteristics of the patients and the cycle of ovarian stimulation
Patients (n) | 32 | 32 | |
Age (years) | 33.2 ± 3.0 | 32.5 ± 3.0 | 0.39 |
BMI (kg/m2) | 23.5 ± 3.2 | 23.2 ± 3.0 | 0.48 |
Duration of infertility (years) | 4.4 ± 3.0 | 4.1 ± 3.0 | 0.33 |
Infertility
| | | 0.11 |
Primary | 56.2% (18/32) | 78.1% (25/32) | |
Secondary | 43.8% (14/32) | 21.9% (7/32) | |
Tobacco use (%) | 3.1% (1/32) | 0 (0/32) | 0.31 |
Regular alcohol use | 12.5% (4/32) | 3.1% (1/32) | 0.35 |
Etiology
| | | 0.59 |
Male factor | 50% (16/32) | 53.1% (17/32) | |
Idiopathic | 34.4% (11/32) | 21.9% (7/32) | |
Tubal factor | 9.3% (3/32) | 18.7% (6/32) | |
Male + Tuboperitoneal | 6.3% (2/32) | 6.3% (2/32) | |
Total dose FSH (UI) | 2185.5 ± 617 | 1877.3 ± 817 | 0.09 |
Total dose LH (UI) | 1094.5 ± 258 | 1026.5 ± 385 | 0.87 |
Time of stimulation (days) | 11 ± 1.8 | 10.4 ± 3.2 | 0.82 |
Follicles (n) (hCG day)
| | | |
Total (≥10 mm) ≥16 mm | 15.9 ± 8.3 6.9 ± 3.1 | 17.7 ± 9.2 7.5 ± 3.6 | 0.49 0.47 |
≥18 mm | 4.1 ± 2.1 | 4.1 ± 1.8 | 0.65 |
Retrieved oocytes:
| | | |
Total | 12.5 ± 6.9 | 13.4 ± 7.0 | 0.57 |
Metaphase II stage | 9.3 ± 5.9 | 9.8 ± 6.0 | 0.77 |
Metaphase I stage | 1.3 ± 1.5 | 1.4 ± 1.4 | 0.22 |
Germinal vesicle stage | 1.3 ± 2.5 | 0.9 ± 1.4 | 0.88 |
Implantation rate | 29% (18/62) | 27.4% (17/62) | 1.00 |
Pregnancy rate | 40.6% (13/32) | 37.5% (12/32) | 0.79 |
A total of 681 oocytes were obtained: 330 oocytes from the GnRH-a group and 351 from the GnRH-ant group. Of these, 189 (27.8%) were morphologically normal, 220 (32.3%) had cytoplasmic dysmorphisms, 124 (18.2%) had extracytoplasmic alterations, and 148 (21.7%) had both dysmorphisms. The oocyte dysmorphisms were not significantly different between the GnRH-a and GnRH-ant groups (
P ≫ 0.05). Logistic regression analysis revealed that the probability of finding a normal oocyte in the GnRH-ant group was higher (OR:1.29, 95% CI: 0.76-2.22) than in the GnRH-a group. However, the probability of detecting an oocyte with cytoplasmic dysmorphism in the GnRH-ant group was similar (OR:1.05, 95% CI: 0.62-1.81) to the probability of detecting such an oocyte in the GnRH-a group. However, the probability of detecting an oocyte with extracytoplasmic dysmorphism or both dysmorphisms in the GnRH-ant group was lower (OR: 0.78, 95% CI: 0:38–1:59 and OR: 0.77. 95% CI: 0.38-1.54, respectively) than for the GnRH-a group. Again, these groups were not significantly different. These data are summarized in Table
2.
Table 2
Comparison of the overall prevalence of oocyte dysmorphisms in the GnRH agonist and GnRH antagonist groups
Oocytes:
| | | | 0.34 | 1.29 (0.75–2.22) | |
Normal | 27.8% (189) | 25.8% (85) | 29.6% (104) | | |
Dysmorphic | 72.2% (492) | 74.2% (245) | 70.4% (247) | | | |
Cytoplasmic dysmorphism | 32.3% (220) | 32.1% (106) | 32.5% (114) | 0.84 | 1.05 (0.61–1.80) | |
Extracytoplasmic dysmorphism | 18.2% (124) | 19.4% (64) | 17.1% (60) | 0.48 | 0.78 (0.37–1.59) | |
Cytoplasmic + extracytoplasmic dysmorphism | 21.7% (148) | 22.7% (75) | 20.8% (73) | 0.45 | 0.77(0.38–1.54) | |
It is possible that the oocytes exhibited more than one change in morphology. When each dysmorphism was analyzed, it was observed that alterations in polar body shape (31.8%, 217/681) and the presence of diffuse cytoplasmic granulations (22.8%; 155/681), refractile bodies (18.5%; 126/681) and central cytoplasmic granulations (13.6%; 93/681) were the most common alterations. Other morphological abnormalities were present in less than 10% of the oocytes analyzed. Interestingly, cytoplasmic vacuoles (0.7%; 5/681) and changes in oocyte shape (1.9%; 13/681) were not very common. The individual incidences of oocyte dysmorphism obtained from the GnRH-a and GnRH-ant groups were not significantly different (
P ≫0.05). These data are summarized in Table
3.
Table 3
Comparison of the prevalence of specific dysmorphisms in the GnRH agonist and GnRH antagonist groups
Cytoplasmic dysmorphism (presence of) | | | | | |
Diffuse granulation | 22.8% (155) | 25.2% (83) | 20.5% (72) | 0.17 | 0.95 (0.44–2.06) |
Central cytoplasmic granulation | 13.6% (93) | 12.1% (40) | 15.1% (53) | 0.32 | 1.06 (0.48–2.44) |
Refractile bodies | 18.5% (126) | 20.3% (67) | 16.8% (59) | 0.27 | 0.88 (0.32–2.43) |
SER aggregations | 2.3% (16) | 1.8% (6) | 2.8% (10) | 0.45 | 1.41 (0.25–7.85) |
Vacuoles | 0.7% (5) | 0.9% (3) | 0.6% (2) | 0.93 | 0.66 (0.07–6.37) |
Extracytoplasmic (alterations) | | | | | |
Polar body shape | 31.3%(213) | 30.9%(102) | 31.6%(111) | 0.90 | 0.78 (0.38–1.61) |
Perivitelline space | 6.8% (46) | 8.2% (27) | 5.4% (19) | 0.19 | 0.66 (0.28–1.52) |
Zona pellucida | 3.4% (23) | 4.8% (16) | 2.0% (7) | 0.06 | 0.40 (0.15–1.06) |
Oocyte shape | 1.9% (13) | 1.1% (7) | 1.7% (6) | 0.78 | 0.79 (0.26–2.35) |
Discussion
Oocyte quality is a major determinant of embryo quality and the subsequent success of fertility treatment. Thus, to improve the outcomes of assisted reproduction procedures, it is important to identify non-invasive parameters to evaluate oocyte quality. Among these, the examination of egg phenotype using optical microscopy is the most commonly used method.
A normal MII oocyte has a round shape, a single intact polar body, a clear zona pellucida, a small perivitelline space, and a transparent and smooth cytoplasm without granules or inclusions [
1,
27,
30,
32,
33]. However, most of the oocytes collected after ovarian stimulation from infertile patients or from some fertile donors have some type of dysmorphism [
27,
28,
30,
32‐
37]. Various studies have demonstrated the clinical importance of oocyte dysmorphism. Indeed, specific intra- and extracellular morphological changes in oocytes, such as granulations, cytoplasmic inclusions, and abnormalities of the polar body, zona pellucida, perivitelline space, and oocyte shape, have been shown to be related to fertilization, cleavage, embryo development, and clinical outcomes [
1,
26,
29,
30,
33‐
47]. However, the results are controversial. Other studies have reported the prognostic value of oocyte morphology with respect to the IVF results, depending on the dysmorphism and results analyzed [
27,
39,
46‐
51]. The variance in results can be explained by the use of different morphological criteria and/or a lack of standardization in the assessment of oocytes. Additionally, the factors involved in the induction of the morphological changes may have contributed to this variability.
For the oocyte to be capable of being fertilized by a sperm, it needs to go through a series of events that lead to both nuclear and cytoplasmic maturity. However, these events may occur independently [
1,
46,
52]. After denudation, it is possible to verify the presence of the first polar body, which proves the maturity of the oocyte nucleus. However, the assessment of cytoplasmic maturation is not well established. Some authors correlate this cytoplasmic maturity with the lack of cytoplasmic inclusions. In other words, a mature oocyte is one without granulation, with vacuoles, and with uniform and clear cytoplasm [
53]. Therefore, the presence of cytoplasmic inclusions could represent cytoplasmic immaturity, which would affect fertilization and embryonic development. Although immature oocytes can be fertilized, the subsequent course of embryonic development is abnormal [
53]. Extra-cytoplasmic alterations may also be related to the maturity of the oocyte. An increase in the perivitelline space could be related to the premature exocytosis of cortical granules, suggesting a post-mature cytoplasm [
54]. The presence of granulation in the perivitelline space is likely to be a physiologic phenomenon related to oocyte maturity, mainly because the incidence of this change was significantly more frequent in oocytes at stage MII (mature oocytes) as compared with immature oocytes. The control of meiotic resumption in mammalian oocytes depends on a network of extracellular and intracellular molecular interactions [
55‐
58]. Understanding the regulatory role of such interactions in oocyte maturation is important for the analysis of oocyte phenotype. Some mechanisms that regulate GnRH or gonadotropin-regulated oocyte quality/maturity may regulate gamete morphology.
GnRH receptors are expressed in the human ovary, but the action of GnRH analogues on oocyte morphology and quality remains controversial. In the present study, no significant difference was observed between the incidence of oocyte dysmorphisms and the type of analogue used for pituitary suppression during IVF. In contrast to our findings, Murber
et al.[
4] found a significantly higher incidence of cytoplasmic changes in the GnRH-ant group than in the GnRH-a group (62.1% and 49.9%, respectively;
P ≪ 0.01). In another study in which different stimulation protocols were evaluated, Otsuki
et al.[
26] found that SER aggregations were more common in short GnRH-a protocols as compared with long-term protocols. However, differences in the study design [
4,
26], in the populations, and in the analysis methods prevent comparisons with our findings. Our findings are in agreement with those of Rienzi
et al.[
1], who analyzed 1,191 MII oocytes. Their retrospective study included three distinct protocols for controlled ovarian hyperstimulation, a long-term GnRH-a protocol (268 cycles), a GnRH-ant protocol (142 cycles), and a natural cycle with minimal stimulation (106 cycles). No correlation was found between the protocol used for ovarian hyperstimulation and oocyte morphology [
1].
Pharmacological doses of gonadotropins in stimulated cycles create a hormonal environment that induces the growth of a cohort of follicles that would otherwise degenerate under
in vivo conditions. Thus, the type of gonadotropin used is also a factor that likely influences the quality of the oocyte. In our study, regardless of the analogue used (agonist or antagonist), all cycles were stimulated by r-LH in addition to r-FSH, and this factor has yet to be analyzed. Some studies have reported the beneficial effects of using r-LH on ovarian physiology and clinical outcomes [
59,
60]. In addition, Ruvolo
et al.[
61] suggested that supplementation with r-LH improves the chromatin quality of cumulus cells and protects them from apoptosis, possibly acting directly on granulosa cells or via a paracrine effect. These authors suggested that by maintaining the physiological function of the cumulus cells over time, the nuclear and cytoplasmic maturation of the oocyte would also be maintained, which would improve the quality of the oocytes at the time of retrieval. Detti
et al.[
62] speculated that supplementation with LH and FSH may have had a positive effect on oocyte quality. Acevedo
et al.[
63] randomly assigned 20 oocyte donors to ovarian stimulation protocols using GnRH-ant alone or GnRH-ant with recombinant LH and observed that LH activity supplementation improved oocyte quality. Thus, it can be hypothesized that the r-LH used in our study had a positive effect on oocyte morphology, which compensated for any possible deleterious effect of GnRH-a or GnRH-ant on ovarian physiology. In fact, Hernadez
et al.[
64] reported that a GnRH-ant inhibited the cell cycle by decreasing the synthesis of growth factors and thereby compromised the mitotic program of follicles and oocyte quality. However, this hypothesis needs to be tested with additional controlled trials. It should be noted that in our study, the overall incidences of oocyte dysmorphism in both the GnRH-a and GnRH-ant groups were similar to those reported in the literature, suggesting that any beneficial effects were associated with the protocols used for ovarian stimulation. In addition, Rashidi
et al.[
3] performed a randomized study comparing human menopausal gonadotropin (HMG) with r-FSH and did not find differences in the morphology of the MII oocytes retrieved.
Although there are several studies that have evaluated the clinical protocols of ovarian stimulation, very little is known regarding the correlation between these protocols and oocyte morphology. The majority of published studies that focus on oocyte morphology have examined its association with the results of IVF and not with the ovarian stimulation protocol [
33,
34,
38,
40,
47,
49]. In a recent meta-analysis [
46], the oocyte dysmorphisms that were negatively correlated with fertilization rate, i.e., a lower chance of the fertilization of an oocyte, included changes in the first polar body, an increase in the perivitelline space, and the presence of refractile bodies and cytoplasmic vacuoles. The present study found that 72.2% of oocytes had at least one morphologic change, which is consistent with the 60-80% values reported by Figueira
et al. [
52] (60.2%); Rienzi
et al.[
1] and Yakin
et al. [
29] (84%); Kahraman
et al. [
39] (65.8%); Aguiar
et al. [
65] (67.3%); Balaban
et al. [
32] (63.1%); and De Sutter
et al. [
27] (63.5%). Among the dysmorphisms, cytoplasmic changes were the most common (32.3%), followed by the simultaneous occurrence of cytoplasmic and extracytoplasmic changes (21.7%). Strictly extracytoplasmic changes were the least common (18.2%). Conflicting data were reported by Balaban
et al.[
32], who showed a higher percentage of extracytoplasmic changes, followed by extra- and cytoplasmic changes and then finally by cytoplasmic changes. Mikkelsen and Lindenberg [
54] also reported a higher incidence of extracytoplasmic changes followed by a smaller increase in the frequency of cytoplasmic changes.
When the dysmorphisms were evaluated individually, the most common cytoplasmic change found was cytoplasmic granularity (diffuse and central), followed by refractile bodies, SER aggregations and, finally, the presence of vacuoles. Balaban
et al.[
32] reported a different order of prevalence (in decreasing order of frequency): dark cytoplasm, refractile bodies, and granular cytoplasm. Rienzi
et al.[
1] reported an order of prevalence similar to ours: cytoplasmic granularity was the most common, followed by refractile bodies, vacuoles, and SER; the only difference was in the observed frequencies of vacuoles and SER. In our study, the most prevalent changes in the extracytoplasmic dysmorphisms were related to the first polar body, followed by changes in the perivitelline space, zona pellucida, and oocyte shape, as reported by Rienzi
et al.[
1]. However, Balaban
et al.[
32] showed that the most frequent extracytoplasmic alterations were an increase in the perivitelline space, followed by a dark pellucida area and shape abnormalities. Aguiar
et al.[
48] showed that 42.8% of oocytes had multiple changes, 40% had cytoplasmic inclusions, 14.3% exhibited fragmentation of the polar body, and 2.9% displayed enlargements of the perivitelline space.
Some limitations of our study should be noted. The population of 64 patients is small (32 patients per group), despite the inclusion of over 300 eggs per group. This low number may have influenced the results. However, a study [
1] involving a larger number of patients did not reveal significant differences in oocyte morphology in relation to the ovarian stimulation protocol used. Our study is randomized in terms of the patient population, but the statistical analysis is calculated based on the number of eggs. If the patient population is randomized, it is fair to assume that the egg quality is similar up until stimulation and that any changes observed will be due to the stimulation itself. While randomization could compensate for any bias in terms of known and unknown patient-related factors that influence egg quality, certain factors will tend to be over-represented by those patients who provide more eggs (on average each patient provided 10 eggs). However, it should be noted that, again, a study [
1] that limited the number of oocytes analyzed per patient did not reveal significant differences in oocyte morphology in relation to the ovarian stimulation protocol used.
Competing interest
The authors declare that they have no competing interest.
Authors’ contributions
AMMC participated in the design of the study, data interpretation, and the drafting of the manuscript. All authors were responsible for the data collection, analysis, and interpretation presented in the manuscript. JBAO participated in the design of the study, collected the data, and coordinated the study. CGP conducted the laboratory analysis of oocytes. JGFJ participated in critical revision of the manuscript. All authors read and approved the final manuscript.