Positive outcome after preimplantation diagnosis of aneuploidy in human embryos

Pre-implantation genetic diagnosis

Pre-implantation genetic diagnosis is an alternative to prenatal diagnosis for a select group of patients. Patients have to go through in vitro fertilization in order to produce embryos in vitro, from which one or two cells are removed at the 8-cell stage. A fluorescence in situ hybridization or polymerase chain reaction is carried out for the genetic diagnosis. Fluorescence in situ hybridization is used for the analysis of chromosomes for sexing for X-linked disease, chromosome abnormalities and aneuploidy screening. Aneuploidy screening is performed for infertile patients going through in vitro fertilization to try to improve their pregnancy rate. A polymerase chain reaction is used for the diagnosis of single-gene disorders. Since the risk of contamination and allele dropout is high with a polymerase chain reaction, linked or unlinked markers are usually used in a fluorescent multiplex polymerase chain reaction. New techniques, for example comparative genomic hybridization, allow the analysis of all of the chromosomes from one cell at one time. The ethical implications of pre-implantation genetic diagnosis are immense as the technique has already been used for social sexing and human leukocyte antigen matching.

Chromosome analysis of spontaneous abortions after in vitro fertilization (IVF) and intracytoplasmic sperm injection (ICSI)

OBJECTIVE

To verify the hypothesis that the incidence of chromosomal abnormalities significantly increases in the products of conception of males with sub-fertility, treated with assisted reproduction techniques (ART).

STUDY DESIGN

All removed products of conception tissues were analyzed with standard cytogenetic techniques. A karyotype of the abortions was possible in 35 cases of IVF and 29 of ICSI.

RESULTS

15/35 (43%) IVF abortions and 14/29 (48%) ICSI abortions, respectively, have shown a chromosomal abnormality. The most frequent abnormality was monosomy X (45,X0).

CONCLUSION

No significant difference in the incidence of embryonic anomalies was found between IVF and ICSI group. However, both IVF and ICSI allow pre-implantation diagnosis and embryo chromosomal evaluation should be considered, before transfer. Genetic counselling and consideration of prenatal diagnosis is suggested as integral part of planning of treatment strategies for 'at risk couples'.

First clinical application of comparative genomic hybridization and polar body testing for preimplantation genetic diagnosis of aneuploidy

OBJECTIVE

To develop a preimplantation genetic diagnosis (PGD) protocol that allows any form of chromosome imbalance to be detected.

DESIGN

Case report employing a method based on whole-genome amplification and comparative genomic hybridization (CGH).

SETTING

Clinical IVF laboratory.

PATIENT(S)

A 40-year-old IVF patient.

INTERVENTION(S)

Polar body and blastomere biopsy.

MAIN OUTCOME MEASURE(S)

Detection of aneuploidy.

RESULT(S)

Chromosome imbalance was detected in 9 of 10 polar bodies. A variety of chromosomes were aneuploid, but chromosomal size was found to be an important predisposing factor. In three cases, the resulting embryos could be tested using fluorescence in situ hybridization, and in each case the CGH diagnosis was confirmed. A single embryo could be recommended for transfer on the basis of the CGH data, but no pregnancy ensued.

CONCLUSION(S)

Evidence suggests that preferential transfer of chromosomally normal embryos can improve IVF outcomes. However, current PGD protocols do not allow analysis of every chromosome, and therefore a proportion of abnormal embryos remains undetected. We describe a method that allows every chromosome to be assessed in polar bodies and oocytes. The technique was accurate and allowed identification of aneuploid embryos that would have been diagnosed as normal by standard PGD techniques. As well as comprehensive cytogenetic analysis, this protocol permits simultaneous testing for multiple single-gene disorders.

Analysis of sex chromosomes in preimplantation genetic diagnosis for X-chromosome-linked disorders

Preimplantation genetic diagnosis (PGD) is diagnostic tool to avoid inheritance of genetic disease by transferring unaffected embryos. Recently, PCR and FISH have been mainly applied to the diagnosis of single gene disorders and chromosomal abnormalities, respectively. Since with PGD, only a few cells are available for genetic tests, both gene and chromosomes analysis have to be obtained from the same, limited material. Cell recycling makes it possible to obtain the information on genes as well as chromosomes from the same cells. Therefore cell recycling is an acceptable strategy where in PGD targets large proportions of embryos severe chromosomal abnormalities. The responsible genes of the X-linked disorder and numerical abnormalities of sex chromosomes should be analyzed simultaneously. Gender information is definitely useful because only male affected embryos should be avoided for transfer.

Assisted reproductive technologies: toward improving implantation rates and reducing high-order multiple gestations

Despite striking progress in reproductive medicine over the past quarter century, the number of high-order multiple gestations are unacceptably high, largely as a result of the drive to maintain pregnancy rates in a competitive range. Morphologic criteria are currently used to define the reproductive competence of individual embryos but are imperfect predictors of implantation potential. Current and potential strategies to improve the selection of embryos are described. By the use of several of these approaches, it is hoped that the overall number of embryos that are transferred will be reduced, thereby also reducing the multiple gestation rate.

Preimplantation genetic diagnosis for aneuploidy screening in early human embryos: a review

Embryonic aneuploidies may be responsible for pregnancy failure in many IVF patients. In recent years, fluorescent in situ hybridisation (FISH) for multiple chromosomes has been used to document a high frequency of chromosomal errors and aneuploidy in human preimplantation embryos and, after embryo biopsy, to select embryos that are more likely to implant. Such studies suggest that women with recurrent miscarriage and advanced maternal age may benefit most from preimplantation genetic diagnosis with aneuploidy screening (PGD-AS). The success of PGD-AS is likely to be enhanced by new technologies, such as comparative genomic hybridisation, which enable full karyotyping of single cells.

Preimplantation genetic diagnosis

Preimplantation genetic diagnosis is essentially an alternative to prenatal diagnosis, in which genetic testing is performed on embryos before a clinical pregnancy is established. Preimplantation genetic diagnosis has been applied to patients carrying chromosomal rearrangements, such as translocations, in which it has been proven to decrease the number of spontaneous abortions and prevent the birth of children affected with chromosome imbalance. Preimplantation genetic diagnosis techniques have also been applied to increase implantation rates, reduce the incidence of spontaneous abortion and prevent trisomic offspring in women of advanced maternal age undergoing fertility treatment. A third group of patients receiving preimplantation genetic diagnosis are those at risk of transmitting a single gene disorder to their children. The number of monogenic disorders that have been diagnosed in preimplantation embryos has increased each year. Recent protocols have tended to be more complex and more reliable than previous methods, making greater use of multiplex polymerase chain reaction. As well as an expansion in the variety of disorders for which preimplantation genetic diagnosis is offered, new indications have been reported including the use of human leukocyte antigen histocompatibility typing and the application of preimplantation genetic diagnosis to late onset diseases.

Blastomere fixation techniques and risk of misdiagnosis for preimplantation genetic diagnosis of aneuploidy

One of the most critical steps in preimplantation genetic diagnosis (PGD) studies is the fixation required to obtain good fluorescence in-situ hybridization (FISH) nuclear quality without losing any of the cells analysed. Different fixation techniques have been described. The aim of this study was to compare three fixation methods (1, acetic acid/methanol; 2, Tween 20; 3, Tween 20 and acetic acid/methanol) based on number of cells lost after fixation, average rate of informative cells, rate of signal overlaps and FISH errors. A total of 100, 106 and 114 blastomeres were fixed using techniques 1, 2 and 3 respectively. Technique 2 gave the poorest nuclear quality with higher cytoplasm, number of overlaps and FISH errors. Although technique 1 showed better nuclear quality in terms of greater nuclear diameter, fewer overlaps and FISH errors, it is difficult to perform correctly. However, technique 3 shows reasonably good nuclear quality and is both easier to learn and use for PGD studies than the others.

Preimplantation genetic screening and human implantation

In recent years, preimplantation genetic screening (PGS) has been used and recommended to increase the implantation rate in older women or in couples with previous assisted reproduction (ART) failures, to try to increase pregnancy rates in couples with recurrent abortions, to prevent the transmission of chromosome anomalies to the offspring of carriers of balanced chromosomal rearrangements, or even to try to decrease the incidence of trisomic births in older women. So far, PGS has contributed to increase the implantation rate in older women; however, the rate of clinical pregnancies has not increased, either in older women or in couples with previous ART failures. In couples with recurrent abortions, the pregnancy rate seems to increase, but only when the woman is young (< or =35). In carriers of balanced reorganizations, the prognosis is poor. Attempts to decrease the birth of trisomic children to older women are difficult to evaluate. This absence of relevant results is not related to the technique itself, which is quite safe, but to other still largely unknown factors.

Misleading press reports: another rebuttal

This short communication robustly defends embryologists and scientists against allegations in the lay press.

Oocyte-induced haploidization

This paper describes the technical approach to treatment of age-related oocyte aneuploidy. Although one solution can be oocyte/embryo selection, another is represented by the nuclear transplantation procedure. The efficiency of nuclear transplantation into immature oocytes is described as a way of generating embryos, and the possibility that viable female gametes can be constructed by transfer of diploid somatic cell nuclei into enucleated oocytes. Germinal vesicle (GV)-stage mouse oocytes were collected from unstimulated ovaries and somatic nuclei were obtained from mouse cumulus cells obtained after ovarian stimulation. Spare human GV-stage oocytes were donated from consenting patients undergoing intracytoplasmic sperm injection (ICSI) treatment, and human somatic cells were stromal cells coming from uterine biopsies performed on consenting patients undergoing endometrial cell co-culture. GV ooplasts, prepared by enucleation, were transplanted with either GV or somatic nuclei by micromanipulation. Grafted oocytes were electrofused and cultured to allow maturation, following which they were selected at random for insemination or cytogenetic analysis. GV transplantation was accomplished with an overall efficiency of approximately 80 and 70% in the mouse and the human respectively. The maturation rate of 96% (mouse) and 62% (human) following reconstitution was comparable to that of control oocytes, as was the incidence of aneuploidy among the reconstituted oocytes. The reconstituted human oocytes were successfully fertilized by ICSI at a rate of 52%. After the transfer of mouse cumulus or human endometrial cell nuclei into enucleated immature oocytes, a polar body was extruded in >40%. In a limited number of observations where the nucleus of an aged oocyte was transferred into a younger ooplasm, the chromosomes segregated normally at the time of polar body extrusion. The technique of nuclear transplantation itself did not increase the incidence of chromosomal anomalies in the mouse or human, since their oocytes reconstituted with homologous donor GV resumed meiosis to metaphase II and maintained a normal ploidy. In addition, immature mouse ooplasts induced haploidization of transplanted somatic cell nuclei. Although further evaluation of their genetic status is needed, the procedure may offer a realistic way of producing normal oocytes in cases of aged-related infertility. While the procedure is technically similar to cloning, it would generate a unique individual as a result of the contribution of both parental genomes.

Different probe combinations for assessment of postzygotic chromosomal imbalances in human embryos

PURPOSE

We compared three different probe combinations for detection of postzygotic mosaic imbalances in human preimplantation embryos.

METHODS

Two hundred and two spare cleavage stage embryos were hybridized with fluorescently labelled DNA probe mixtures specific to chromosomes X, Y, 18 (N = 67), chromosomes 2, 7, 18 (N = 71), or chromosomes 13, 16, 18, 21, 22 (N = 64).

RESULTS

An overall higher incidence of abnormalities was detected using probe mixture for five (69%) or three (72%) autosomes compared to one autosome and chromosomes X and Y (54%). The rate of aneuploidy detected increased with the number of autosomes hybridized from 4% (X, Y, 18) to 11% (2, 7, 18) to 19% (13, 16, 18, 21, 22). Postzygotic mosaicism comprised the most frequent abnormality detected by all probe combinations, and the percentage detected by each was similar, 48% (X, Y, 18), 56% (2, 7,18), and 50% (13,16,18, 21, 22).

CONCLUSIONS

A probe combination of five autosomes, particularly those of clinical relevance, may be more beneficial for screening embryos from patients at risk of maternal-age-related aneuploidy. However, all three probe combinations are as efficient at identifying postzygotic mosaicism, and may be used for identifying embryos with less potential of developing to term.

Preimplantation genetic diagnosis of numerical and structural chromosome abnormalities

The causes of the decline in implantation rates observed with increasing maternal age are still a matter for debate. Data from oocyte donation strongly suggest that in women of advanced reproductive age, the ability to become pregnant is largely unaffected while oocyte quality is compromised. The incidence of chromosomal abnormalities in embryos is considerably higher than that reported in spontaneous abortions, suggesting that a sizable percentage of chromosomally abnormal embryos are eliminated before any prenatal diagnosis. Such loss may partly account for the decline in implantation in older women. Because of the correlation between aneuploidy and reduced implantation, it has been postulated that selection of chromosomally normal embryos could reverse this trend. Preimplantation genetic diagnosis (PGD) for aneuploidy had three objectives relevant to the present paper: (i) to increase rates of implantation, (ii) to reduce risks of spontaneous abortion, and (iii) to avoid chromosomally abnormal births. Implantation rates did not increase when only five chromosomes were analysed in blastomeres. With eight chromosomes, a significant increase in implantation was achieved. PGD can significantly reduce the incidence of spontaneous abortion. In our clinic, a significant decrease in spontaneous abortions was found, from 23 to 11% after PGD. Currently in cases diagnosed at Saint Barnabas, 0.8% chromosomally abnormal conceptions have been observed after PGD versus an expected 3.2% in a control age-matched group. It seems clear that PGD reduces the possibility of trisomic conceptions under all conditions. If a couple's main interest is to improve their chances of conceiving (improve implantation), then one should consider maternal age and number of available embryos. Improvements in conception after PGD again increase after 37 years of age with eight or nine probes. Carriers of translocations are at a high risk of miscarriage or chromosomally unbalanced offspring, and a high proportion have secondary infertility. PGD of translocations has been approached through a variety of methods, here reviewed, and has resulted in a significant reduction in spontaneous abortions. However, implantation rates in translocation carriers are directly correlated with the proportion of normal gametes, and male patients with 70% or more unbalanced spermatozoa have great difficulty in achieving pregnancy with PGD.

High rates of embryonic loss, yet high incidence of multiple births in human ART: is this paradoxical?

Humans have low natural fecundity, as the probability of establishing a viable conception in any one menstrual cycle is 20-25% for a healthy, fertile couple. There are numerous underlying causes for this low rate of human fertility, not the least of which are intrinsic abnormalities within the oocyte and/or embryo, which likely account for greater than 50% of failed conceptions. During assisted reproduction technology (ART) interventions, controlled ovarian stimulation is used to obtain several oocytes in attempts to increase the likelihood of having at least one developmentally competent embryo available for transfer. However, current techniques for identifying the competent embryo(s) are by no means perfect. These limitations, coupled with pressures to maximize the chance of pregnancy, typically result in the transfer of multiple embryos. Not surprisingly, this practice has resulted in an unacceptably high rate of multiple pregnancies arising from ART. During the last few years, concerted efforts have focused on reducing these rates. Programs for ART are developing patient-specific policies, restricting the number of embryos to transfer. In addition, strategies are being adopted to improve the accuracy for selecting viable embryos for transfer. One such strategy involves further refinement of morphological criteria associated with improved viability by considering, for example, pronuclei disposition, nucleolar organization, and identification of the fast-cleaving embryos with only mononucleate blastomeres. Another strategy employs pre-implantation genetic diagnosis (PGD) whereby a biopsied blastomere is tested for ploidy using fluorescence in situ hybridization (FISH). A final strategy involves extending the duration of culture to the blastocyst stage, thereby allowing self-selection of those embryos capable of proceeding to blastulation and exclusion of those less viable embryos that succumb to developmental arrest. Together, these strategies are enabling fewer embryos of higher quality to be transferred. Accordingly, the overall pregnancy rate from ART continues to increase, while the rate of triplet and higher order multiple births continues to decline. Nevertheless, the high incidence of intrinsic developmental anomalies in human oocytes inevitably will continue to result in a high degree of embryonic loss in ART.

Diagnosis of trisomy 21 in preimplantation embryos by single-cell DNA fingerprinting

Many couples presenting for preimplantation genetic diagnosis (PGD) for a single gene disorder are of advanced reproductive age (>35 years) and have a greater chance of producing embryos with chromosomal aneuploidies. The most common chromosomal aneuploidy observed in newborns is trisomy 21, or Down's syndrome. Consequently, the availability of a highly reliable system that simultaneously detects the heritable gene disorder and trisomy 21 would be beneficial to couples at specific risk. A pentaplex chromosome 21 (Ch 21) single-cell DNA fingerprinting system was developed in a multiplex fluorescence polymerase chain reaction (FL-PCR) on single cells. High reliability and accuracy rates were observed, together with low allele dropout (ADO) and preferential amplification rates on diploid buccal cells, trisomy 21 buccal cells and blastomeres derived from Ch 21 aneuploid embryos. A combined multiplex FL-PCR format was optimized with the common cystic fibrosis delta F508 mutation and validated on single buccal cells from a carrier of the cystic fibrosis delta F508 mutation. This new test is a very powerful technique, which also allows confirmation of the embryo parentage and the identification of extraneous DNA contamination that could cause a misdiagnosis in PGD cases.

Double locus analysis of chromosome 21 for preimplantation genetic diagnosis of aneuploidy

Preimplantation genetic diagnosis (PGD) of numerical chromosome abnormalities significantly reduces spontaneous abortions and may increase pregnancy rates in women of advanced maternal age undergoing in vitro fertilization. However, the technique has an error rate of around 10% and trisomy 21 conceptions have occurred after PGD. To further reduce the risk of transferring trisomy 21 embryos to the patient, we designed a protocol that analyzes chromosome 21 twice by targeting two different loci. This protocol was applied to 388 embryos from 60 cycles of PGD of aneuploidy. The scoring criterion used was based on giving equal importance to both probe results. Of the 242 embryos diagnosed as abnormal, 125 were re-biopsied to assess the rate of false positives and false negatives of the protocol and their clinical relevance. The results of the present study showed no reduction in the overall fluorescent in situ hybridization (FISH) error rate for single cells. However, by using a different scoring criterion, the incidence of false negative can be reduced to 1.6% without missing any trisomy 21. In addition, the present study suggests that if two or more loci from the same chromosome could be simultaneously analyzed in single cells, errors caused by false monosomies could be reduced.

Fertility and maternal age strategies to improve pregnancy outcome

In humans, the live birth rate drops precipitously with increasing maternal age, and this decline is associated with increases in the incidence of oocyte and embryo aneuploidy. Preimplantation aneuploidy screening has improved pregnancy outcome by significantly lowering the miscarriage rate. Nevertheless, aneuploidy screening only identifies the affected embryos; it does not attempt to correct the underlying biologic problem. Anomalies in chromosome segregation can result from a dysfunctional first or second meiotic division in the egg or develop after fertilization during the first few mitoses of early embryonic development. In both instances, ooplasmic anomalies may account for the nuclear problem. Low cell levels of cytoplasmic proteins (e.g., cytoskeletal elements, enzymes, energy stores, cell cycle regulatory proteins) may lead to a dysfunctional division of chromosomes during egg maturation or following fertilization. Ooplasmic injection is a micromanipulation technique that has produced pregnancies in patients with a history of poor-quality, fragmented embryos. Germinal vesicle transfer is a research procedure used to investigate the ooplasmic-nuclear interplay regulating cell cycle, maturation, and fertilization. Both these techniques may prove to be effective in improving the quality of eggs from patients of advanced maternal age.

Aspects of biopsy procedures prior to preimplantation genetic diagnosis

Today, preimplantation genetic diagnosis (PGD) is offered in over 40 centres worldwide for an expanded range of genetic defects causing disease. This very early form of prenatal diagnosis involves the detection of affected embryos by fluorescent in situ hybridization (FISH) (sex determination or chromosomal defects) or by polymerase chain reaction (PCR) (monogenic diseases) prior to implantation. Genetic analysis of the embryos involves the removal of some cellular mass from the embryos (one or two blastomeres at cleavage-stage or some extra-embryonic trophectoderm cells at the blastocyst stage) by means of an embryo biopsy procedure. Genetic analysis can also be performed preconceptionally by removal of the first polar body. However, additional information is then often gained by removal of the second polar body and/or a blastomere from the embryo. Removal of polar bodies or cellular material from embryos requires an opening in the zona pellucida, which can be created in a mechanical way (partial zona dissection) or chemical way (acidic Tyrode's solution). However, the more recent introduction of laser technology has facilitated this step enormously. Different biopsy procedures at different preimplantation stages are reviewed here, including their pros and cons and their clinical applications. The following aspects will also be discussed: safety of zona drilling by laser, use of Ca2+/Mg2+-free medium for decompaction, and removal of one or two cells from cleavage-stage embryos.

Preliminary findings in germinal vesicle transplantation of immature human oocytes

Transplanting a germinal vesicle (GV) from an aged woman's oocyte into a younger ooplasm has been proposed as a possible way to reduce the incidence of oocyte aneuploidy which is considered to be responsible for age-related infertility. In this study, we have assessed the efficiency of each step involved in nuclear transplantation-specifically cell survival, nuclear-cytoplasmic reconstitution, and the capacity of the reconstituted oocytes for in-vitro maturation. In addition, we have evaluated the fertilizability and karyotypic status of the manipulated oocytes by intracytoplasmic sperm injection (ICSI) and fluorescent in-situ hybridization technique respectively. Nuclear transplantation was accomplished with an overall efficiency of 73%. Due to the limited availability of materials, most nuclear transplantation procedures were performed between sibling oocytes. The maturation rate of 62% following reconstitution was comparable with that of control oocytes, as was the incidence of aneuploidy among the reconstituted oocytes. The ICSI results of the reconstituted oocytes yielded a survival rate of 77%, a fertilization rate of 52%, and a satisfactory early embryonic cleavage. Furthermore, in a limited number of observations where the nucleus of an aged oocyte was transferred into a younger ooplasm, there was an appropriate chromosomal segregation. These findings demonstrate that human oocytes reconstituted with GV nuclei are able to undergo maturation, fertilization, and early embryo cleavage, and maintain a normal ploidy. Although in-vitro maturation seems to be a limiting step, this technique would allow us to investigate further the nuclear-ooplasmic relationship during meiotic maturation.

Preimplantation genetic diagnosis: applications for molecular medicine

Preimplantation genetic diagnosis is an alternative to prenatal diagnosis for the detection of genetic disorders. Tests are conducted on single cells biopsied from embryos before they are implanted, allowing the selection of unaffected embryos before a pregnancy has been established. Thus, the issue of pregnancy termination is circumvented. The use of preimplantation genetic diagnosis might have a significant impact on in vitro fertilization success rates as well as allowing the diagnosis of inherited disease.

Embryo implantation after biopsy of one or two cells from cleavage-stage embryos with a view to preimplantation genetic diagnosis

Preimplantation genetic diagnosis (PGD) can be offered as an alternative to prenatal diagnosis (PND) to couples at risk of having a child with a genetic disease. The affected embryos are detected before implantation by fluorescent in situ hybridisation (FISH) for sexing (X-linked diseases) and chromosomal disorders (numerical and structural) or by polymerase chain reaction (PCR) for monogenic disorders (including some X-linked diseases). The accuracy and reliability of the diagnosis is increased by analysing two blastomeres of the embryo. However, the removal of two blastomeres might have an effect on the implantation capacity of the embryo. We have evaluated the implantation of embryos after the removal of one, two or three cells in 188 PGD cycles where a transfer was done. The patients were divided into five groups: a first group which received only embryos from which one cell had been removed, a second group which received only embryos from which two cells had been removed, a third group which received a mixture of embryos from which one and two cells had been taken, a fourth group where two and three cells had been removed, and a fifth group where three cells had been removed. The overall ongoing pregnancy rate per transfer was 26.1%, the overall implantation rate per transfer was 15.2% and the overall birth rate was 14.2%. Although pregnancy rates between the groups cannot be compared because the second group (two cells removed) contains more rapidly developing and therefore 'better quality' embryos, an ongoing pregnancy rate of 29.1% and an implantation rate of 18.6% per transferred embryo in this group is acceptable, and we therefore advise analysing two cells from a > or =7-cell stage embryo in order to render the diagnosis more accurate and reliable.

Multilocus genetic analysis of single interphase cells by spectral imaging

Numerical chromosome aberrations are detrimental to early embryonic, fetal and perinatal development of mammals. When fetuses carrying a chromosomal imbalance survive to term, an aberrant gene dosage typically leads to stillbirth or causes a severely altered phenotype. Aneuploidy of any of the 24 chromosomes will negatively impact on human development, and a preimplantation and prenatal genetic diagnosis test should thus score as many chromosomes as possible. Since cells available for analysis are likely to be in interphase, we set out to develop a rapid enumeration procedure based on hybridization of chromosome-specific probes and spectral imaging detection. The probe set was chosen to allow the simultaneous enumeration of ten chromosome types and was expected to detect more than 70% of all numerical chromosome aberrations responsible for spontaneous abortions, i.e., human chromosomes 9, 13, 14, 15, 16, 18, 21, 22, X, and Y. Cell fixation protocols were optimized to achieve the desired detection sensitivity and reproducibility. We were able to resolve and identify ten separate chromosomal signals in interphase nuclei from different types of cells, including lymphocytes, uncultured amniocytes, and blastomeres. In summary, this study demonstrates the strength of spectral imaging, allowing us to construct partial spectral imaging karyotypes for individual interphase cells by assessing the number of each of the target chromosome types.

Preimplantation diagnosis after assisted reproduction techniques for genetically-determined male infertility

One hundred and thirty-six cycles with a poor prognosis for full-term pregnancy underwent preimplantation genetic diagnosis (PGD) of aneuploidy. The mean maternal age was 31.8 +/- 2.5 years. Only patients younger than 36 years were included in the study with the aim of evaluating whether sperm indices have an effect on the chromosomal constitution of preimplantation embryos. No differences were detected in the percentage of aneuploid embryos; however a higher incidence of monosomies and trisomies was found in MESA-TESE embryos compared to the group of normospermic patients. In addition, an increase in the proportion of gonosomal aneuploidy seemed to be associated with the severity of the male factor parameters. The rate of de-novo chromosomal abnormalities in embryos from patients with a normal karyotype suggested an increased frequency proportional to the severity of the male factor condition, the proportion of monosomic and trisomic embryos, and the percentage of gonosomal aneuploidy increased accordingly. In the case of couples with a male altered karyotype, comparable frequency of chromosomally abnormal embryos, and monosomy and trisomy were observed irrespective of semen indices, gonosomal aneuploidy was only observed in one case where the patient had a karyotype with gonosomal mosaicism. These data confirm that the severe male infertility condition determines an increase in the rate of de-novo abnormalities, as anticipate by the follow-up of the children born after ICSI.

Advances in assisted reproductive technologies

Several clinical advances in the field of assisted reproductive technology have improved the success rates of IVF. These advances include improvements in ovulation induction protocols, the introduction of recombinant gonadotropins, GnRH agonists, and, most recently, GnRH antagonists. ICSI has proved to be the most successful technique for the treatment of male infertility. The micromanipulation techniques developed in the embryology laboratory have facilitated advances in the field of preimplantation genetic diagnosis. Years of research in embryology laboratories have enabled the successful culture of embryos to the blastocyst stage. In the future, blastocyst transfer may have even more impact on overall success rates of IVF and multiple pregnancy rates. The field of assisted reproductive technologies has come a long way since the first successful IVF pregnancy. Future developments are expected to be equally dynamic as efforts continue to help couples conceive healthy pregnancies.

Preimplantation genetic diagnosis

Preimplantation genetic diagnosis (PGD) includes a variety of techniques that have been developed to detect the transmission to the offspring of genetic diseases or of chromosome abnormalities by couples at risk before a pregnancy is established, to avoid these couples the risk of recurrent abortions and/or of repeated terminations of pregnancy. Candidate couples are carriers of gene mutations or of structural chromosome rearrangements, or with recurrent spontaneous abortions of unknown origin. Diagnostic procedures include different modalities of gene amplification using the polymerase chain reaction (PCR) or of fluorescent in situ hybridization (FISH). Embryo biopsies are carried out at the 6-8 cell stage. Healthy embryos are transferred on day 4 or at the blastocyst stage. By now, several hundred healthy children have been born using PGD, and only one diagnostic error has been reported.

New molecular techniques for chromosome analysis

The advent of molecular genetic technology has significantly advanced knowledge about the structure of chromosomes and their behaviour during meiosis and mitosis, as well as delineating cytogenetic aberrations that cannot be identified by conventional chromosome analysis. Molecular cytogenetics, the visualization of genetic loci using the dynamic recombinant technology of fluorescence in situ hybridization (FISH), now provides the obstetrician and gynaecologist with increasingly important diagnostic and prognostic information heretofore unavailable. The technical principles underlying FISH are briefly discussed. Emphasis is placed on the clinical applications of FISH and technologies derived from FISH, in particular comparative genome hybridization, microdissection FISH and multiplex FISH. These technologies play increasingly significant roles in preimplantation and prenatal genetic diagnosis, in the identification of microdeletion syndromes, cryptic translocations and marker chromosomes, and in defining chromosome mosaicism. FISH and related technologies also constitute essential diagnostic modalities in follow-up of organ transplantation, in a variety of haematological disorders and in determining the amplification of oncogenes associated with specific forms of cancer and neoplasia.

Outcome of preimplantation genetic diagnosis of translocations

OBJECTIVE

To review 35 cases of preimplantation genetic diagnosis (PGD) of translocations with several methods, including telomeric probes.

DESIGN

Retrospective study.

SETTING

Clinical IVF laboratory.

PATIENT(S)

Thirty-five couples with one partner carrying a chromosomal translocation.

INTERVENTION(S)

PGD of translocation after polar-body or embryo biopsy.

MAIN OUTCOME MEASURE(S)

Pregnancy outcome.

RESULT(S)

Several trends were observed. First, PGD can achieve a statistically significant reduction in spontaneous abortion, from 95% to 13%. Second, the chances of achieving pregnancy are correlated with 50% or more of the embryos being chromosomally normal. Third, patients with robertsonian translocations produced fewer abnormal gametes and more pregnancies than did patients with reciprocal translocations. Fourth, a new fluorescence in situ hybridization protocol for PGD of translocations, which involves applying telomeric probes, has proved adequately reliable with a 6% average error rate.

CONCLUSION(S)

PGD of translocations achieves a statistically significant reduction in spontaneous abortion, both for polar-body and blastomere biopsy cases. Pregnancy outcome depended on the number of normal embryos available for transfer, with patients having <50% abnormal embryos achieving the most pregnancies. Because robertsonian translocations caused fewer abnormal embryos than reciprocal translocations, they also resulted in higher rates of implantation.

Preimplantation genetic diagnosis

Embryo biopsy for preimplantation genetic diagnosis can be performed on the oocyte/zygote, cleavage stage embryo, or blastocyst, but the majority of centres perform cleavage stage biopsy. Single-cell diagnosis is undertaken by the polymerase chain reaction or fluorescent in-situ hybridization. Technical difficulties have arisen with preimplantation genetic diagnosis, such as allele dropout and chromosomal mosaicism. However, it is hoped that these difficulties can be overcome in the future with the advent of new techniques.

Gonadal activity and chromosomal constitution of in vitro generated embryos

Chromosomal analysis of pre-implantation embryos was carried out in patients with a poor prognosis of full term pregnancy, which underwent induction of multiple follicular growth. In all, 1034 embryos generated from 191 stimulated cycles were screened for nine chromosome aneuploidy by using the multicolour fluorescence in situ hybridisation technique. Thirty-five percent of the diagnosed embryos were chromosomally normal, whereas the remaining presented with numerical abnormalities, which made them not suitable for transfer. The results obtained confirmed that the incidence of abnormalities is mostly dependent on age; however, monosomy and trisomy are more frequent in poor responders. Accordingly, the pregnancy rate per started cycle was significantly higher in women with a normal response to gonadotropic stimulation (33% vs. 8%, P<0. 001). These findings indicate that poor responder patients are physiologically exposed not only to reduced chances of implantation, but also to an increased risk of spontaneous abortion and trisomic pregnancies.