Clínica e Centro de Pesquisa em Reproducião Humana Roger Abdelmassih, São Paulo, Brasil
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Abstract |
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Key words: blastocyst/ICSI/IVF/monozygotic twinning
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Introduction |
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More specifically, several authors have directed attention to alterations of the zona pellucida in embryos produced in vitro, and their possible association with MZT incidence. Cohen et al. (1990) suggested that both abnormal in-vitro zona hardening and assisted hatching could favour MZT (Cohen et al., 1990). Hershlag et al. (1999) reported a possible relationship of MZT with mechanical assisted hatching. The authors described an increase in pregnancy rates on poor prognosis cases in which assisted hatching was used with a concomitant elevation on the number of identical twins (Hershlag et al., 1999
). Alikani et al. (1994) presented six cases of MZT in patients treated with IVF (Alikani et al., 1994
). The common feature among the embryos of these women was a naturally thin zona, or its artificial breach by assisted fertilization or hatching. However, more recently a large retrospective analysis reported by Scott Sills et al. (2000) did not find significant differences in the incidence of MZT between zona intact and zona manipulated groups after IVF (Scott Sills et al., 2000
).
Prolonging embryo culture in vitro to the blastocyst stage has been presented as an effective form of embryo selection that results in increased implantation rates. This approach has gained popularity due to the excellent results recently reported (Gardner and Schoolcraft, 1999), with the introduction of sequential media. On the other hand, the ideal culture conditions for an embryo to reach its biological potential are not completely defined, and prolonged exposure of the embryo to laboratory conditions may not be free of risk.
Five pregnancies complicated with monozygotic twins, after intracytoplasmic sperm injection (ICSI) and transfer of embryos at the blastocyst stage, are presented here. These pregnancies occurred during a period of 8 months and represent an important increase in the historical incidence of MZT in our centre.
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Materials and methods |
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Ovarian stimulation was achieved using luprolide acetate (0.51.0 mg/day s.c.) and recombinant FSH (Gonal F®; Serono, São Paulo, Brasil). Follicular development was monitored with periodic measurements of serum oestradiol and vaginal ultrasound. Human chorionic gonadotrophin (HCG) 10 000 IU (Profasi®; Serono) was administered when at least two follicles reached a mean diameter of 18 mm and oocyte retrieval was performed by ultrasound guided vaginal aspiration 34 h later.
Oocytes collected in pure follicular fluid were immediately sent to the adjacent embryology laboratory, where they were identified using a dissecting microscope at x50 magnification. After being identified, oocytes were placed in a single well culture dish (3260; Costar, Cambridge, MA, USA) with 1.0 ml of 80 IU/ml of hyaluronidase (Hyase-1®; Scandinavian IVF Science, Gothenburg, Sweden) for 30 s and subsequently washed several times in IVF 50 medium (Scandinavian IVF Science), and one oocyte was put inside one droplet containing 30 µl of IVF 50 medium and covered with light mineral oil (Ovoil 150®; Scandinavian IVF Science) and incubated for 24 h at 37°C in an atmosphere with 5% CO2. At the end of the incubation period, cumulus and radiate cells were removed with an 125 µm gauge pipette, connected to a stripper (Mid Atlantic Diagnostics Inc., Medford, NJ, USA).
Assessment of the stage of oocyte development and quality was performed evaluating its polar body, nuclear status and morphological characteristics using inverted microscope (Nikon Diaphot Microscope®; Nikon Corporation, Tokyo, Japan) at x200400 magnification. Metaphase II (MII) oocytes were micro-injected within a period of 24 h after collection. Metaphase I (MI) oocytes were analysed as to extrusion of first polar body at 4 h intervals up to 8 h after retrieval and the injection was performed accordingly.
The methods for sperm preparation and injection have been previously reported (Abdelmassih et al., 1996). After sperm injection, oocytes were incubated in 1 ml of IVF 50 medium (Scandinavian IVF Science) and covered with mineral oil for 1618 h. Oocytes were then observed for the presence or absence of pronuclei and polar bodies. Fertilization was considered normal when two clearly distinct pronuclei containing nucleoli were present. If a single pronucleus was observed, a second evaluation was carried out ~4 h later.
Oocytes containing two pronuclei were put separately into droplets of 30 µl of IVF 50 medium (Scandinavian IVF Science) into a Petri dish (3260 Costar) and covered with mineral oil if the transfer was to be performed in day 3 of culture, or into S1 medium (Scandinavian IVF Science) for day 5 transfers and incubated until the next morning. The embryos were observed at 42 h after injection and classified according to the criteria proposed by Palermo et al. (1992). Embryos with >50% fragmentation were not transferred. If the transfer was to be held on day 5, the embryos were placed in S2 medium (Scandinavian IVF Science) on day 3 (72 h) and remained in this medium until day 5 (120 h).
At the time of transfer, embryos were loaded into 15 µl of IVF 50 or S2 medium using an Edwards Wallace Catheter of 23 cm (Simcare Manufacturing Ltd, Hythe, UK). The patients rested in bed for 20 min after the transfer and later were sent home with instructions to rest for 24 h.
The luteal phase was supplemented with daily administration of 800 mg of oral/vaginal progesterone (Utrogestan®; Laboratoires Besins-Isvovesco, Paris, France) and transdermic 100 µg oestradiol patches changed daily (Estraderm TTS100®; Laboratório Biogalênica, São Paulo, Brasil). Serum ßHCG concentrations were measured 12 days after follicular aspiration.
Transvaginal ultrasound was performed in all patients with ascending ßHCG titres; presence and number of intrauterine gestational sacs were assessed, as well as the presence of a fetal pole and cardiac activity. Pregnancies were monitored by the patient's obstetrician and the final outcome was reported to the clinic both by the obstetrician and the patient.
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Results |
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Table I shows the distribution of patients according to the aetiology of infertility. No significant differences were observed between the two groups.
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Discussion |
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The detailed mechanism of embryo hatching in humans has not been established. Two processes are known to be important. One is digestion of the zona by embryonal or maternal enzymes. A second one is mechanical pressure exerted by the expanding blastocyst causing the thinning of the zona. Most of the literature that suggests there is a relationship between IVF-related techniques and increased incidence of MZT focuses on zona pellucida alterations and manipulation. Embryos with a naturally thinner zona and those in which some form of zona manipulation occurred appear to be at a higher risk. ICSI and assisted hatching (Alikani et al., 1994; Hershlag et al., 1999
) have all been associated with MZT. One probable mechanism is that artificial piercing of the zona may create a non-natural gap through which the blastocyst herniates prematurely, favouring the embryo splitting.
All cases reported here involved ICSI as the form of fertilization. However, the historical control group also contained only pregnancies achieved with embryos formed after ICSI but transferred at the 2- to 8-cell stage, so the zona manipulation should not be the only explanation for the increased incidence of MZT. Moreover, the report of Scott Sills et al. (2000), in which pregnancies achieved with embryos transferred at 72 h of culture were reviewed, confirms the higher incidence of MZT after an in-vitro embryo culture, but minimizes the possible relationship with zona pellucida manipulation (Scott Sills et al., 2000). The authors did not find a difference in the frequency of MZT in pregnancies achieved after ICSI or assisted hatching versus those achieved with conventional IVF.
Unfortunately, routine measurement of the zona thickness is not part of our embryology laboratory routine, so zona characteristics of the embryos transferred were not documented. However, thinning of the zona is more common in older patients (Cohen et al., 1992), and in three of the cases the ages of the patients were 37 or more. Furthermore, four out of five cases reported had at least one expanding blastocyst and three a hatching blastocyst transferred which implies that an important proportion of zona thinning occurred in vitro.
The physical changes occurring in the zona pellucida after fertilization are commonly known as `zona hardening' (Wassermann, 1994). Spontaneous hardening has also been described in in-vitro aged unfertilized mouse ova (Long, 1981). Moreover, abnormal zona hardening has been proposed as a result of extended exposure of embryos to laboratory conditions, resulting in an impaired capacity to hatch and implant (Cohen et al., 1990). Enhancement of embryo implantation rates in specific groups of patients, by assisted zona hatching or drilling, are indirect proof that zona hardening affects in-vitro produced embryos in the human (Malter and Cohen, 1989
; Cohen et al., 1990
; Tucker et al., 1991
). This same phenomenon could play a role in favouring MZT. The herniation of the blastocyst through a less flexible zona may favour its division.
As described previously, sequential media were used as the form of embryo culture in cases in which the transfer was performed on day 5. The protocol followed was similar to the one published by Gardner et al. (1998), in which excellent pregnancy and implantation rates were achieved. This same group of authors has expanded their original experience, and confirmed the good results obtained with this method of culture (Scholtes and Zeilmaker, 1998; Schoolcraft et al., 1999; Marek et al., 1999
). However, they do not report an increased number of monozygotic twins. Furthermore, none of the large series of blastocyst transfers refers to MZT as a significant complication (Schoolcraft et al., 1999). Only recently Peramo et al. (1999) described what appear to be the first cases reported, in which two monozygotic twin pregnancies resulted after embryos were transferred at the blastocyst stage.
Our own experience includes only cases in which ICSI was used as the technique of oocyte fertilization. Since this technique is used in most cases performed in our centre, it is not possible to evaluate the relative importance of the prolonged culture and ICSI, other than the comparison with the historical control of transfers performed at the 2- to 8-cell stage shown here. Furthermore, the retrospective nature of the analysis cannot account for all potential differences between the two groups of patients compared. A larger number of cases reported, where pregnancies were achieved after prolonged embryo culture in vitro, will be necessary to determine the significance of our experience.
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Notes |
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References |
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Submitted on July 18, 2000; accepted on November 10, 2000.