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Abstract |
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Key words: PGD cycle data/pregnancy and baby follow-up/preimplantation genetic diagnosis
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Introduction |
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Besides the prospective and retrospective collection of data on accuracy, reliability and effectiveness of PGD, the aims of the ESHRE PGD Consortium are to (ESHRE PGD Consortium Steering Committee, 1999): (i) survey availability of PGD for different conditions; (ii) initiate follow-up studies of pregnancies and children born; (iii) produce guidelines and recommended PGD protocols to promote best practice; and (iv) formulate a consensus on the use of PGD. To date, the PGD Consortium has focused on data collection on PGD cycles and pregnancies and babies, but further development of the other aims is under way.
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Materials and methods |
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Data collection
For information on the content of the different forms (referral, cycle, pregnancy, baby, biopsy protocol, FISH protocol, PCR protocol), we refer to the first PGD Consortium report (ESHRE PGD Consortium Steering Committee, 1999). Before March 2000, data were collected on hard copy forms that were then sent to ESHRE Central Office. Since then, it has been possible to send in data through the ESHRE web site. Here, referrals for each couple, each cycle, pregnancy and baby have to be filled in one by one and are then sent automatically to the Steering Committee. This method allows on-line and prospective data collection. Because this method was seen as impractical especially by larger centres with a large number of cycles, the possibility was offered for the centres to fill in the blank Excel spreadsheets used by the Steering Committee for data processing directly.
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Results |
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From Table I it is clear that the vast majority of couples have had one or more pregnancies, though healthy children have been born in <25% of them. More than one-quarter of all couples have one or more affected children. Almost the same proportion of couples suffered from spontaneous abortion or termination of pregnancy after prenatal diagnosis.
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The referrals for monogenic disorders (Table V) showed identical patterns as in the previous report. Cystic fibrosis was the most frequent reason for referral, followed by thalassaemia and spinal muscular atrophy (type I) as far as the autosomal recessive disorders were concerned. The group of autosomal dominant diseases was dominated by the trinucleotide repeat disorders myotonic dystrophy (57 couples) and Huntington's disease (44 couples). For the Fragile-X syndrome, as well as Duchenne/Becker's muscular dystrophy, 52 couples were referred for each condition. Referrals for several other X-linked diseases were noted, though in most cases the numbers were small (with the exception of haemophilia and WiskottAldrich syndrome) (Table V
).
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The data for PGD for aneuploidy screening are summarized in Table VIII. A total of 465 cycles reached the oocyte retrieval stage. All patients were infertile, and the indications included repeated IVF failure, maternal age and recurrent abortion. The majority of biopsies were performed on cleavage-stage embryos using acidic Tyrode's drilling, although 25 cycles used polar body biopsy only and one used polar body and cleavage-stage biopsy. All biopsies were performed using aspiration. All diagnoses were performed using FISH. From a total of 6025 oocytes retrieved, a fertilization rate of 62% was achieved. The biopsy was successful in 99% of cases, but this figure was not accurate as one centre did not record the number of successful biopsies (this centre reported a 99.2% successful biopsy rate). A diagnosis was obtained in 63% of embryos undergoing FISH. Only 36% of embryos were diagnosed as suitable for transfer, but this may be an underestimate as one centre did not record this information. This centre recorded the number of cells, fragmentation and multinucleation at days 2 and 3, as well as several other parameters. Depending on the age of the patient and previous IVF cycles, it was determined which embryos to transfer. It was interesting to note that this centre did not classify the embryos as normal or abnormal on the FISH result, but considered other factors. In all, 79% of cycles resulted in an embryo transfer, although for a number of cycles no embryos were diagnosed as transferable, and embryos were still transferred. This was reflected in the data by the fact that the number of embryos transferred was greater than the number transferable. Therefore the value entered here was an underestimate as it was recorded as the same as the number of embryos transferred. Again, this was caused by one centre using a special transfer policy, which can be explained by the fact that the main aim of aneuploidy screening is to increase the IVF pregnancy rate.
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The FISH and PCR diagnoses for PGD of inherited disorders are summarized in Table IX. A total of 853 cycles was started, of which 82 were cancelled before the oocyte retrieval due to a poor response, cysts or other reasons (9.6% cancellation rate). In all, 771 cycles reached the stage of oocyte retrieval. The majority of cycles had ICSI (n = 619), while two cycles had IVF and ICSI combined. A PCR diagnosis was performed in 377 cycles, FISH in 381 cycles, and nine cycles had FISH and PCR diagnosis combined. This included one cycle combining aneuploidy screening and a single gene defect (the cycle where polar body and cleavage-stage biopsy were combined). In five cycles sexing only was carried out using both PCR and FISH, and in three cycles a specific diagnosis of an X-linked disease was combined with sexing by FISH. All of these cycles were included under the PCR diagnosis. Thirteen cycles were cancelled after the oocyte retrieval, mainly due to insufficient quality of the embryos for biopsy. From 10 267 oocytes collected, a fertilization rate of 63% was obtained. The number of oocytes inseminated was not an accurate figure, as some centres did not record this information. From the 6465 fertilized oocytes, 81% were suitable for biopsy, of which 96% were successfully biopsied, this being consistent with the data for last year. The majority of cycles used acidic Tyrode's to drill the zona (n = 602), and 146 cycles used the laserwhich was an increase from last year's data. The majority of cases had cleavage-stage biopsy (755 cycles), all of which used blastomere aspiration to remove the cell. Three cycles had polar body biopsy only (all FISH diagnoses), and one cycle had polar body and cleavage-stage biopsy (PCR diagnosis).
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A positive HCG was detected in 174 cycles (23% per oocyte retrieval), and 141 were confirmed as clinical pregnancies following an ultrasound scan (16.5% per started cycle, 18% per oocyte retrieval, 22% per embryo transfer procedure).
When the cycles were separated according to the diagnostic method used, the following results were obtained: PCR diagnoses were performed for a variety of autosomal recessive and dominant disorders and for sexing or specific diagnosis for X-linked diseases. For the PCR diagnosis, 385 cycles reached oocyte retrieval. It is well documented that for PCR diagnosis, fertilization should be achieved by ICSI to reduce the risk of contamination from sperm embedded in the zona pellucida, yet IVF was still used in 35 cycles. A successful PCR diagnosis was obtained in 81% of embryos successfully biopsied, and 55% were diagnosed as transferable. A pregnancy rate of 22% per oocyte retrieval and 26% per embryo transfer procedure was obtained.
FISH was used for the diagnosis of sex for X-linked disease and patients carrying Robertsonian and reciprocal translocations (see Table X). For the FISH diagnosis, 386 cycles reached the stage of oocyte retrieval. A successful diagnosis was obtained in 90% of embryos successfully biopsied, and of these only 32% were diagnosed as suitable for transfer. This was mainly due to the high numbers of abnormal embryos detected for patients carrying translocations. Table X
shows the breakdown of the PGD cycles for chromosome analysis. This mainly involved patients carrying Robertsonian or reciprocal translocations. From a total of 196 cycles that reached the oocyte retrieval stage, ICSI was performed in most cases, some of which were probably because of poor sperm quality due to the man carrying the translocation. One cycle had IVF and ICSI. Three cycles were cancelled after the oocyte retrieval, probably due to insufficient embryo development. Acidic Tyrode's was used for drilling in 157 cycles. Polar body biopsy was used for three cycles, and cleavage-stage aspiration for 190 cycles. From the 2732 oocytes collected, 85% were fertilized, which was higher than for other types of PGD cycles. Of these, 85% of the embryos were considered suitable for biopsy. The embryo biopsy procedure was successful in 95% of cases, and a FISH result was obtained in 90% of embryos. Only 27% of the embryos diagnosed were considered suitable for transfer, which was just 13% of the oocytes collected. This reflects the high level of abnormal embryos detected in this group of patients (Conn et al., 1998
, 1999
). In 19% of cycles there were no embryos suitable for transfer. A clinical pregnancy rate of 19% per embryo transfer procedure and 15% per oocyte retrieval was obtained. Due to the low numbers of embryos diagnosed as transferable, only 13 embryos were frozen from this series.
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Confirmation of diagnosis
In total, 116 of the 236 fetal sacs (49%) were examined through prenatal diagnosis (Table XVI). Unfortunately, four cases were shown to be misdiagnosed at PGD. Two of these pregnancies (one affected with myotonic dystrophy and one with ß-thalassaemia) were terminated, while the two other [one with cystic fibrosis, and one male fetus after sexing for X-linked retinitis pigmentosa (RP)] went on to term. Whether this boy was affected with RP is not known. In Table XVI
, the obvious confirmation of PGD for sexing by the baby's sex at birth is not taken into account. After PGD for sexing, only one misdiagnosis (see above), which was discovered at prenatal examination occurred after preimplantation sex determination using PCR. In four early miscarriages a karyotype was obtained: two miscarriages showed an abnormal karyotype (one trisomy 16 and one mosaic trisomy 22). Although both abnormal karyotypes occurred in the FISH group, these cannot be classified as misdiagnoses as the chromosomes involved were not examined at PGD.
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Discussion |
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With respect to the reproductive histories of the patients requesting PGD, and the reasons for PGD, there are few differences between the two data sets: as shown above, most of these patients have a reproductive history burdened with pregnancy terminations and/or affected children.
If the broad indication groups are considered (see Table III), it is clear that a chromosomal indication is becoming an increasingly important reason for referral. This is most likely a reflection of technical improvements regarding FISH. In principle, there are now probes available for almost all structural abnormalities, and the simultaneous applications of several probes is becoming more or less routine. The number of referrals must have been biased negatively with respect to aneuploidy screening in couples having an indication for IVF or ICSI. From the literature it is known that some centres have reported a large number of treatment cycles just for this indication, and therefore it is surprising that this category of referrals amounted to <10% of the total. The majority of these screenings are related to maternal age.
With respect to the monogenic diseases, no dramatic differences compared with last year's data collection were noted. Cystic fibrosis was the first Mendelian disorder to be diagnosed (Handyside et al., 1992), and after 10 years still shows the highest number of referrals. The group of trinucleotide repeat disorders (myotonic dystrophy, Huntington's disease and Fragile-X syndrome) follows, with an average of 50 couples per disease.
In general, it might be concluded that the pattern of referral indications is more or less a reflection of the genetic disorders requiring prenatal diagnosis. One of the differences that is clearly present is the number of referrals with the combination of two genetic disorders segregating at the same time. A total of seven couples presented with this phenomenon. For the time being, it will be very difficult to help these couples, but as soon as multiple diagnoses become technically feasible it is to be expected that the number of embryos available for transfer might become the limiting factor. In contrast, prenatal diagnosis is less of a problem from a technical point of view, but the chance of finding an abnormality requiring termination is increased so much that this is not a workable alternative.
The decisions taken by the centres after referral are a reflection of the status of the group of couples from the second and thus later data collection, since in about 20% of the cases the decision-making process on the possibility and acceptability of PGD is not yet finished.
The PGD Consortium is aiming at the collection of complete and prospective referral data, which might assist in taking decisions with respect to the developments of new diagnostic procedures according to needs emerging from the data collected. Furthermore, in future some Consortium members might decide to concentrate only on the diagnosis of rare disorders in their centres, while other centres would then refer their patients to them.
Cycles
Comparing data from last year and this year, a number of interesting factors can be seen, such as the increase in the use of the laser for zona drilling and a number of polar body biopsy cases. From the data available, there appears to be no difference in pregnancy rates between cycles in which acidic Tyrode's solution or laser technology has been used. No blastocyst biopsy for PGD has yet been reported to the PGD Consortium. On the diagnosis side, unfortunately there are still centres using IVF for PCR diagnosis, and it is hoped that in the future all centres will use ICSI to avoid sperm contamination. Although comparing the number of cycles from the first and second report for each type of diagnosis is awkward (as the reports cover very different periods in time), an attempt can still be made. The total number of cycles reported has increased tremendously, mostly due to the larger number of contributing centres. This is also reflected in a clear increase in numbers of PCR cycles reported. For FISH analysis, the relative numbers of aneuploidy screening, chromosomal aberration cases and sexing cases can be compared: the number of aneuploidy screening cases has increased three-fold, the number of chromosomal aberration cases has increased by a factor of four, while the number of sexing cases has decreased slightly. This reflects the evolution in current PGD practice: while the number of centres using aneuploidy screening to improve their IVF results is steadily increasing, and while the number of patients with translocations and other chromosomal aberrations which can be helped by PGD is also increasing due to technical improvements, an increasing number of X-linked diseases can be diagnosed by a DNA-specific test which obviates the need for sexing. Another striking observation, which has been commented upon (Conn et al., 1998, 1999
), is the low number of embryos available for transfer after PGD for chromosomal aberrations. The underlying mechanisms of this phenomenon are a worthwhile research subject.
With regard to pregnancy rates, no evolution is observed between the first and second sets of data. Pregnancy rates are quite similar, and remain at ~17% fetal heart beats per cycle started. Again, the time periods which these two data collections cover cannot be used for comparison, but finer analysis of the available data is certainly a possibility which the ESHRE PGD Consortium will pursue.
Due to the complexity and the large amount of data, the steering committee decided this year to show only summarized data in this paper. However, the steering committee of the ESHRE PGD Consortium has been expanded so that more people can be involved with the analysis of this large amount of data in the future, which will hopefully lead to the reporting of more detailed information.
Pregnancies
The first fact to come to attention when examining Table XII is the high rate of multiple pregnancies (33%), in contrast to the moderate pregnancy rate per cycle (16.5%). Although several publications have now shown that careful selection of one or two viable embryos for transfer is effective in reducing multiple pregnancies (Staessen et al., 1995
; Gerris et al., 1999
), this type of selection is not easily applicable in PGD. First, it is still unclear to what extent biopsy of one or two cells from an embryo impairs the implantation potential. Second, at each PGD a cohort of embryos is diagnosed as unsuitable for transfer on genetic grounds, while this cohort could well contain the embryos with the highest implantation potential. Third, PGD embryos are transferred at day 3 or 4, while most IVF centres now transfer embryos in standard ICSI patients at day 2, or sometimes at day 5 at the blastocyst stage, which makes comparing pregnancy rates after PGD and ICSI difficult. Clearly, the PGD Consortium data collection would be an ideal tool for investigating what selection criteria apply to embryos post biopsy. Tables XIII and XIV
simply confirm the high rate of multiple pregnancies and the complication during pregnancy and at birth which this entails. The incidence of pregnancy loss [subclinical pregnancies (i.e. pregnancies with a positive HCG, but no fetal heart beat), clinical abortions and extrauterine pregnancies] was 32/163 (20%), which is comparable with a value of 22.4% referred to by others (Wisanto et al., 1995
) for ICSI with ejaculated spermatozoa. However, caution is mandatory because the retrospective nature of the data collection may lead to underestimation of chemical pregnancies. Reassuringly, no specific complication emerges which could be linked to PGD.
Babies
The cohort of 162 children described here is very similar to a cohort of 1987 children born after `regular' ICSI (Bonduelle et al., 1999): 52 and 54% were singletons, 46 and 41% were twins, and 2 and 5% were triplets respectively. Other parameters such as birth weight were also very similar: singletons weighed 3176 and 3220 g, and twins weighed 2344 and 2421 g respectively. Birth length and head circumference were equally similar. When we apply the definition of major malformation used in this publication (i.e. malformations that generally cause functional impairment or require surgical correction), we obtain a rate of 3/130 (bilateral clubfoot, exencephaly and chylothorax) or 2.3%. Again, this is very close to the 2.9% obtained by others (Bonduelle et al., 1999
). Although data on only a small number of cases are available as yet, an important message to emerge hereand which has been one of the first concerns of the ESHRE PGD Consortiumis that PGD babies are not exposed to greater risks of neonatal problems or malformation than ICSI babies.
Confirmation of diagnosis
Another important aim of the ESHRE PGD Consortium is to assess the accuracy of PGD. In this respect, it is assuring to see that >50% of the concepti were checked before or after birth. Less assuring is that four misdiagnoses for monogenic diseases occurred by PCR, which underscores the greater technical difficulties encountered with PCR than with FISH. One of these misdiagnoses was probably due to contamination during PCR; for the other three, no explanation was given or available, although it would be interesting to know why these misdiagnoses occurred in order to prevent such events in the future, possibly through guidelines issued by the PGD Consortium. Besides diagnosis based on two biopsied cells (as is already applied by a number of centres), application of recent technical developments such as multiplex PCR (Kuliev et al., 1999; Dreesen et al., 2000
) may decrease this misdiagnosis rate of 4/116 (3.4%). This emphasizes the need for the ESHRE PGD Consortium to advise a control prenatal diagnosis after PGD, which must still be regarded as an experimental procedure.
Protocols
As an alternative to the current way of collecting data concerning protocols, the steering committee has decided to set up retrospective studies in different technical areas applied in PGD. The consortium could rapidly prove valuable in the recommendation of best practice guidelines to new and existing PGD centres, using information gained from each of the participating centres. In many centres, the low number of cycles performed annually prohibits the collection of data from which meaningful generalizations can be made. Data from the consortium potentially provides power to comparisons by pooling equivalent data sets. The comparisons would mostly be performed retrospectively and should as far as possible attempt to compare like with like. These studies will be loosely divided between three main areas in line with the existing questionnaires (i.e. biopsy/culture; FISH testing; PCR testing). Each of these areas could later be further subdivided, e.g. FISH-related studies could be divided into translocations, sexing and aneuploidy screening. The Consortium has appointed task force leaders for each of these areas whose responsibilities include data collection, analysis and publication. These studies should neither interfere with clinical practice, compromise innovative work nor replace publications describing novel work. At the present time, the proposals for retrospective studies include the following:
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Conclusions |
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Appendix |
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Australia: K. De Boer, Sydney IVF, Sydney; N. Hussey, Dept of Obstetrics/Gynaecology, University of Adelaide, Adelaide; L. Wilton, Melbourne IVF, Melbourne.
Belgium: K. Sermon, Centre for Medical Genetics VUB, Brussels
Denmark: J. Hindkjaer, Centre for Preimplantation Genetic Diagnosis, Aarhus University Hospital, Aarhus
France: N. Frydman, Hopitaux Béclère et Necker, Paris; S. Viville, Institut de Génétique et de Biologie Moléculaire et Cellulaire, Strasbourg
Greece: E. Kanavakis, St Sophia's Children Hospital, University of Athens, Athens; E. Kontogianni, IVF and Genetics, Athens
Israel: D. Manor, Dept of Obstetrics/Gynaecology, Rambam Medical Centre, Haifa
Italy: M.P. Ciotti, IVF and Infertility Centre, University of Bologna; C. Magli, SISMER, Bologna
Netherlands: E. Coonen, PGD Working Group Maastricht, Stichting Klinische Genetica Zuid-Oost Nederland, Maastricht
South-Korea: I.-S. Kang, Dept of Obstetrics/Gynaecology, Samsung Cheil Hospital, Sungkyankwan University, Seoul
Spain: A. Veiga, Instituto Dexeus, Barcelona; J. Santalo, Unitat de Biologia Cellular, Univ. Autonoma, Barcelona
Sweden: E. Blennow, Dept of Clinical Genetics, Karolinska Hospital, Stockholm
UK: P. Braude, Assisted Conception Unit, St Thomas' Hospital, London; J. Harper, Dept of Obstetrics/Gynaecology, University College London, London; S. Lavery, Institute of Obstetrics/Gynaecology-RPMS, Hammersmith Hospital, London; K. Miller, School of Biology, University of Leeds, Leeds
USA: N. Agan, Dept of Obstetrics/Gynecology, Baylor College of Medicine, Houston, Texas; K. Drury, Dept of Obstetrics/Gynecology, University of Florida, Gainesville, Florida; S. Gitlin, Jones Institute for Reproductive Medicine, Norfolk, Virginia; L. Krey, New York University Medical Center, New York, New York; S. Munné, Institute of Reproductive Medicine and Science, Saint Barnabas Medical Center, West Orange, New Jersey.
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Acknowledgments |
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Notes |
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* The ESHRE PGD Consortium Steering Committee: Joep Geraedts, Department of Molecular Cell Biology and Genetics, University of Maastricht, J. Bechlaan, 113, Maastricht, The Netherlands. E-mail joep.geraedts{at}gen.unimaas.nl
Alan Handyside (Chair, SIG in Reproductive Genetics), School of Biology, University of Leeds, Leeds, UK. E-mail A.H.Handyside{at}bmb.leeds.ac.uk
Joyce Harper, Department of Obstetrics and Gynaecology, University College London, 8696 Chenies Mews, London WC1E 6HX, UK. E-mail joyce.harper{at}ucl.ac.uk
Inge Liebaers, Centre for Medical Genetics, Dutch-speaking Brussels Free University, Laarbeeklaan 101, 1090 Brussels, Belgium. E-mail lgenlsi{at}az.vub.ac.be
Karen Sermon1, Centre for Medical Genetics, Dutch-speaking Brussels Free University, Laarbeeklaan 101, 1090 Brussels, Belgium. E-mail lgensnk{at}az.vub.ac.be
Catherine Staessen, Centre for Reproductive Medicine, Dutch-speaking Brussels Free University, Laarbeeklaan 101, 1090 Brussels, Belgium. E-mail lriasnc{at}az.vub.ac.be
Alan Thornhill, Division of Reproductive Endocrinology and Infertility, Mayo Clinic, 200 First Street SW, Rochester MN 55905, USA. E-mail Thornhill.Alan{at}mayo.edu
Stéphane Viville, BP63, IGBMC, 1, Rue Laurent Fries, 67404 Illkirch-Strassbourg, France. E-mail viville{at}titus.u-strasbg.fr
Leeanda Wilton, Melbourne IVF, 320 Victoria Parade, 3002 East Melbourne VIC, Australia. E-mail Lwilton{at}mivf.com.au
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References |
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