1 Assisted Reproductive Unit, Al Amal Hospital, P.O. Box 921988, Amman, Jordan and 2 Uni. Frauenklinik, IVF Labor, Ratzeburger Allee 160, 23538 Lubeck, Germany
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Abstract |
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Key words: embryo transfer/implantation/time of transfer/transfer catheter
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Introduction |
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Increasing implantation rates after embryo replacement attract much attention. Classically, crucial variables such as age, number and quality of transferred embryos have been directly linked to successful implantation. Very often, a single variable is evaluated alone in relation to a successful transfer. In this study, we aim to examine other factors related to the conditions of embryo transfer and evaluate their impact on pregnancy rates.
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Materials and methods |
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Embryo transfer of frozenthawed supernumerary embryos (intracytoplasmic sperm injection embryos of 21 patients and conventional IVF embryos of 13 patients) was performed. Patients had their endometrium exogenously prepared using sequential oestrogen and progesterone replacement (Navot et al., 1991a,b
).
Ovarian stimulation, oocyte retrieval and IVF
Ovarian stimulation was accomplished with follicle stimulating hormone (Metrodin; Serono, Rome, Italy) and human menopausal gonadotrophin (HMG) (Pergonal; Serono) after pituitary down-regulation with gonadotrophin-releasing hormone analogue (Decapeptyl; Beaufour Ipsen International, Paris, France). The dosage of HMG was adjusted individually according to the ovarian response. When at least three leading follicles had reached a mean diameter of 18 mm and serum oestradiol concentration was appropriate, human chorionic gonadotrophin (HCG) (10 000 IU, Pregnyl; Organon, Oss, The Netherlands) was administered intramuscularly (i.m.). Oocyte retrieval was scheduled to take place 3436 h later by transvaginal ultrasound guidance. Six hours later the oocytes were inseminated and fertilization was confirmed by the presence of two pronuclei ~16 h after insemination. Preincubation, insemination and embryo culture were carried out in IVF media (Medi-cult a/s, Copenhagen, Denmark), details of which have been extensively described before (Ghazzawi et al., 1998
).
Embryo development and morphology
On the morning of embryo transfer, embryos were examined and the number of cells determined. Each embryo was scored according to its symmetry and the extent of fragmentation of blastomeres (Plachot et al., 1986; Dawson et al., 1987
; Scott et al., 1991
). Briefly, grade I embryos contained symmetrical and unfragmented blastomeres, grade II embryos were even but with slight cellular debris and grade III embryos had at least one degenerated cell. Embryos were assigned to grade IV if three or more cells had completely fragmented. Embryos with the best morphology and the most advanced stage of development were selected for transfer. Normally up to three embryos were transferred in each group; however, in the event of slowly developing embryos in patients who were allocated for 48 h transfer, we had to delay the procedure a further 24 h.
Technique of embryo transfer
Patients were positioned supine (lithotomy position) on an electrohydraulic gynaecological chair. The chair was tilted 20° to 30° from the horizontal so that the patient was in a head down position. The Erlangen catheter consisted of an introducing a metal cannula (fitted with an obturator) and an insertion catheter. The cannula has an external diameter of 2 mm, and its tip is olive-shaped with a diameter of 3 mm. The silicon movable collar is usually placed 2 to 3 cm from the tip. The instrument has a length of 25 cm. To facilitate handling, the proximal end of the instrument is provided with a ring to accommodate the operator's finger. The quality of the steel used for the instrument permits the cannula to be bent to match the individual `angle of kink' between the uterine corpus and the cervix. We make use of an opened-tip vena cava catheter (17 guage) as the insertion catheter, the tip of which is slightly rounded. The outer diameter of the catheter is 1.2 mm and it bears two marks: one corresponding to the length of the introducing cannula, and the second located 4 cm proximal to the first. We first mark the catheter and then sterilize it using gas (ethylene oxide).
The EdwardsWallace catheter (H.G.Wallace Ltd, Colchester, UK) is made of polyethylene, soft open-ended and has a rigid outer Teflon introducer.
Transfer technique
The cervix was exposed with a bivalve speculum. No disinfectant or medium was employed. Any cervical mucus encountered was removed gently with a simple swab ensuring that no bleeding was induced on a presenting ectropion. The cervix was grasped with a tenaculum applied at 11 o'clock in all patients of the Erlangen group, as this would straighten the cervical canal and make the introduction of the metal cannula easier.
Drawing up the embryos into the insertion catheter was done with the aid of a disposable tuberculin syringe using the `three-drop procedure' in which the embryos are separated by a bubble of air from a preceding and a following drop of medium. The total volume of medium drawn up into the tuberculin syringe was about 3 x 0.02 ml. When the Erlangen catheter was used, the cannula with its mandrel was introduced into the cervical canal until its olive-shaped tip just passed through the internal cervical os (i.e. about 2.5 cm, which is the length of the cervical canal), then the plastic collar was moved down until it touched the external cervical os. The embryologist then carried the loaded catheter to the surgeon who passed the catheter through the cannula (after withdrawing the mandrel) up to the second mark in the catheter. The catheter was slightly pulled back and the medium containing embryos was gently expelled into the mid-uterine cavity with the aid of the tuberculin syringe. The catheter remained in place for 1015 s after the embryos were expelled. The insertion catheter was drawn back into the introducing cannula and the two instruments were removed together. The two instruments were flushed with medium under a stereomicroscope to ensure that the embryos were actually released into the uterine cavity.
The EdwardsWallace soft silicon catheter was preloaded with embryos and then inserted through the Teflon sleeve, which was then passed through the external and internal cervical os following precise markings so that the embryos were placed into the uterine cavity and not into the fundus. The mark at the external os would correspond to the length of the cervical canal. Grasping the cervix was performed only when difficulty in introducing the catheter was encountered. From then onward, the same steps were followed as previously mentioned. In patients with difficult transfers, sounding the uterus (i.e. measurement of the uterine cavity length using a uterine sound instrument) and occasionally dilatation of the cervix was performed under light anaesthesia. Details of the transfer procedure including duration, bleeding, mucus and excessive manipulation were carefully recorded. Ease of use of catheters was measured by incidence of uterine sounding, cervical dilatation and bleeding. At the end of the procedure, the patient was carried to a bed where she remained for 1 h. Thereafter, she was discharged and allowed to take up her usual activities. Vaginal progesterone pessaries (Cyclogest; Hoechst, Frankfurt, Germany) supported the luteal phase.
Transmyometrial embryo transfer
In five patients (not included in the groups compared) with a history of repeated IVF failures, in whom embryo transfer was extremely difficult or even impossible, transvaginaltransmyometrial transfer was performed under ultrasound scan guidance. A 5 MHz probe (Hitachi 405) was inserted in the vagina and a `Towako' embryo transfer catheter (Cook, Queensland, Australia) was used. The catheter 18-gauge needle with its stylet was passed under ultrasound guidance through the anterior fornix of the vagina and the myometrium of the anterior uterine wall. In one case, the uterus was retroverted, and the needle was passed through the posterior fornix and the posterior uterine wall. The needle was advanced through the myometrium to the junction with the endometrium without puncture of the latter. The stylet was then removed and the preloaded transfer catheter was passed through the needle. After release of the embryos, the catheter was checked in the laboratory to ensure that all embryos had been transferred.
Pregnancy was confirmed by an increased serum ß-HCG concentration 1416 days after embryo transfer. Clinical pregnancy was diagnosed by ultrasonography at 67 weeks of pregnancy.
Data analysis
Statistical analysis of discrete variables was by 2 analysis with Fisher's exact test where applicable. The differences were considered significant at a level of P < 0.05.
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Results |
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Discussion |
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Time of embryo replacement
It is generally agreed that the selection of embryos for transfer on the basis of morphology and development relates well to pregnancy outcome (Dawson et al., 1995). Embryos are usually transferred 2 days after insemination, after confirming fertilization and subsequent cleavage, at the 2- and 4-cell stages of development. Delaying embryo transfer until day 3 (when 68-cell stage of development is expected) provides an opportunity to observe the embryos for a further 24 h in culture. Any morphologically normal embryos on day 2 which subsequently arrest or degenerate can be identified and their transfer avoided. The embryo quality is unlikely to change between day 2 and day 3 (Dawson et al., 1995
). In this study, the transfer of the more advanced growing embryos (day 3) achieved higher pregnancy rates than transfer on day 2 (Table III
) but this difference was not significant. In a study by Gardner et al. (1998), a pregnancy rate of 70% was achieved by transferring the blastocysts on day 5 using sequential culture media in the absence of co-culture and serum. However, the true value of delaying transfer to beyond day 2 post-insemination can only be assessed using randomized prospective study with matched patient groups.
The choice of catheter for embryo replacement
Among the few essential steps of embryo transfer, catheter technology emerges as one crucial factor which has not gained enough attention and scrutiny. The aim must be to transfer the embryos with a high degree of reliability atraumatically, i.e. without any traces of blood on the introducing cannula and/or the insertion catheter. The operators' experience plays an important role. In a study by Barber et al. (Barber et al., 1996), a comparable success rate was achieved when an infertility nurse performed the embryo transfer. Since 1994, we have preferred soft embryo transfer catheters to the more rigid ones, because the latter are more likely to induce cervical and endometrial lacerations. However, passing soft catheters through the cervical canal was often difficult and sometimes impossible. Soft catheters resulted in the highest rate (37.6%) of difficult embryo transfer with the consequences of lowering the pregnancy rate (Mansour et al., 1990
). Failed embryo transfer and repeated attempts to replace the embryos using different catheters are very frustrating and might have adverse effects on the embryos. Therefore, the initial choice of transfer catheter is an important decision to make, and the physician must be comfortable and familiar with it.
The type of transfer catheter has been addressed in few studies. Wisanto et al. (Wisanto et al., 1989) recommended the use of the Frydman set over the Wallace catheter because of higher pregnancy rates. Gonen et al. (Gonen et al., 1991
) has shown that the tef cat catheter yielded a higher pregnancy rate than the Frydman set. Al-Shawaf et al. (Al-Shawaf et al., 1993
) showed that there was no difference in the performance of the Wallace and the Frydman catheters with regard to pregnancy rates (30.3% versus 30.7% respectively).
Taking into consideration that the above transfer catheters show few differences in concept and technology, these findings suggest that the issue of catheter type is still controversial and that there is no clear-cut advantage of one catheter over another. In the present study, we have investigated the use of a catheter which has major differences from the above traditional types of catheters. The Erlangen catheter was first introduced for clinical use in the early 1980s (Trontnow et al., 1983). Embryo transfer was carried out using the afterload method. Technically, various investigators handle embryo transfer in quite different ways (Lopata et al., 1980
; Craft et al., 1981
; Wood et al., 1981
). There are various arguments in favour of the use of an insertion catheter as well as an introducing cannula. If only a single instrument is used, that is if the attempt is made to enter the uterine cavity only with the insertion catheter itself, it is not possible to exclude reliably an occasional haemorrhage or mucus while negotiating the cervical canal. In such a case, the possibility of the embryo coming into contact with blood, fibrin and endocervical micro-organisms when passing the tip of the catheter after being expelled into the uterus is greater. In a study by Egbase et al. (Egbase et al., 1996
), contamination of the embryo transfer catheter tip yielded lower pregnancy rates. If the two-instrument procedure is employed, i.e. the introducing cannula is fitted with an obturator during its introduction, these complications can largely be excluded. This has been reflected in our results.
In the group of patients who had embryo transfer by the Wallace catheter (Table II), bleeding occurred in 24% of them compared with 6% in the Erlangen catheter group. As we have mentioned above, a cannula with a fitted obturator probably clears the way for the insertion catheter. Therefore, there was hardly any mucus attached to the tip of the catheter upon withdrawal, while in 41% of the Wallace group, mucus was seen threading out from the tip of the catheter upon removal. Consequently, the number of embryos left at the tip of catheter that were trapped by blood or mucus was significantly higher (P < 0.007) in patients of the Wallace group than that of the Erlangen catheter group of patients. It is inevitable, therefore, that implantation is influenced by such mechanical factors that could hinder the proper placement of embryos into the uterine cavity.
The ease and difficulty of transfer procedure
Transcervical embryo transfer is the method used almost universally in human IVF programmes and has not been modified since the first report of successful attempts (Edwards, 1981). However, sometimes it is difficult or even impossible to perform transcervical embryo transfer. In a series of 876 embryo transfer procedures, 1.3% were impossible, 3.2% were very difficult (requiring manipulation for >5 min or cervical dilatation) and 5.6% were difficult (requiring manipulation) to perform (Wood et al., 1985
). To avoid or minimize difficult embryo transfer procedures, mock embryo transfer catheters have been used either before the IVF treatment cycle (Mansour et al., 1990
) or just before the real transfer (Sharif et al., 1996
). Other investigators have attempted to use ultrasound-guided embryo transfer. Hurley et al. (Hurley et al., 1991
) in a small, randomized, prospective trial failed to demonstrate any significant benefit from ultrasound-guided embryo transfer, nor did Al-Shawaf et al. (Al-Shawaf et al., 1993
) in a non-randomized study. In another study by Woolcott and Stanger (Woolcott and Stanger, 1997
), of 121 consecutive transvaginal ultrasound-guided embryo transfer, they indicated that tactile assessment of embryo transfer catheter placement was unreliable. Although the impact of the variables they observed on IVF outcome was not clearly established, the report is valuable in adding to our understanding and may be of prognostic significance.
Transmyometrial embryo transfer has been used successfully in patients with a history of difficult or impossible transfer in previous attempts (Parsons et al., 1987). In the present study, we applied this method to five patients with previous IVF failures in whom embryo transfer was impossible. We followed the `Towako' method (Kato et al., 1993
) under general anaesthesia as the patients were anxious because of their previous history and because we were in the middle of a learning curve. Two pregnancies were achieved: one is ongoing, and the other aborted at 8 weeks gestation. Our results confirm earlier reports which have related the ease or difficulty of the transfer procedure to pregnancy outcome, i.e. difficult embryo transfer was predictive of fewer pregnancies (Leeton et al., 1982
; Englert et al., 1986
). This was illustrated in Table V
where 92% of patients who became pregnant had an easy embryo transfer.
The significance of early or late expulsion of transferred embryos into the vagina
Mechanical factors including the position of the patient during embryo transfer and bed rest following the procedure have been implicated as potential causes which could influence retention or expulsion of embryos following embryo transfer. Whereas our transfers were performed in the lithotomy position, other teams recommended that the patient's position should depend on the position of the uterus. It has been suggested that women with a retroverted uterus should assume the knee-chest position, while a modified lithotomy position is performed for women with anteverted uterus (Jones et al., 1983). Others suggested the modified lithotomy position for both these situations (Englert et al., 1986; Rienthaller et al., 1986
). In a randomized study reported by Diedrich et al. (Diedrich et al., 1989
), no difference in pregnancy rate was noted depending on the position during the transfer.
Historically, bed rest following embryo transfer has been generally advised, ranging in duration from 15 min to 24 h or more (Sharif et al., 1995). In a study by Botta and Grudzinkas (Botta and Grudzinkas, 1997
), a 24 h period of bed rest following embryo transfer was not associated with a better outcome of the IVF when compared with that of a 20-min rest period.
The amount of back-tracking of embryos on withdrawal of the catheter has been a subject of debate. Woolcott and Stanger (Woolcott and Stanger, 1997) observed that embryos' associated air were expelled upon withdrawal of the catheter, in 5% of all cases. However, when this did occur it was not insignificant, being <5 mm in all cases. This is contrary to the results published by Knutzen et al. (1992) who suggested that embryos might be expelled in 3252% of embryo transfers depending on the patient's position. Their study, however, investigated mock transfers with 40 ml of radio-opaque contrast medium in non-treatment cycles. The volume and nature of the contrast media differed considerably from those that are normally used during IVF treatment cycles. In another study by Schulman (Schulman, 1986
), delayed expulsion was observed after seven transfers in 32 patients (22%); he concluded that his results were consistent with other evidence, not supported by direct observation, that expulsion of embryos may contribute to IVF failure. In the present study, 100 patients were subjected to another examination 15 min following embryo transfer. Delayed expulsion was noticed in 11 patients out of 100 transfers. However, there was no significant difference relating the type of catheter to expulsion rate. Whether we should routinely observe and examine any fluid leaking from the external os in order to establish early or late expulsion of transferred embryos needs to be addressed in larger controlled studies.
In conclusion, we have examined some of the factors related to embryo transfer conditions that may be of importance for achieving successful transfer and we have demonstrated that successful embryo transfer is not influenced by the time of transfer post-insemination. The role of the operator and his choice of embryo transfer catheter may influence catheter performance as reflected by pregnancy rate but no significant difference was observed in this study. In cases in which transcervical embryo transfer is very difficult or impossible, transvaginaltranscervical transfer is a viable option. The significance of early or late expulsion of transferred embryos into the vagina has yet to be established in large controlled studies.
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Notes |
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References |
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Submitted on April 16, 1998; accepted on November 18, 1998.