Detection of fetal cells in intrauterine lavage samples collected in the first trimester of pregnancy

Use of the Quantitative Fluorescent-PCR Assay in the Study of Fetal DNA from Micromanipulated Transcervical Samples

AIM

The purpose of this study was to evaluate the validity of the combined use of micromanipulation and quantitative fluorescent (QF)-PCR assay for the identification of fetal elements in transcervical cell (TCC) samples collected in early pregnancy.

METHODS

TCC samples were obtained by intrauterine lavage (IUL) in 113 pregnant women who were between 7 and 12 weeks pregnant before termination of pregnancy. All IUL samples were screened under an inverted microscope, at which time the isolation of fetal cells by micromanipulation was attempted. QF-PCR assay, using 9 small tandem repeat (STR) markers for chromosomes 13, 18, 21, X, and Y, was performed in all specimens to identify fetal cells in TCC samples and the corresponding placental tissue and blood specimens. TCC samples from male fetuses in which either the micromanipulation or QF-PCR analysis were unsuccessful, were studied with fluorescent in situ hybridization (FISH), using probes for X and Y chromosomes.

RESULTS

Isolation of supposed fetal material from IUL samples was carried out by means of micromanipulation in 93 cases (82.3%), where discernible chorionic villous filaments or cell clumps of probable trophoblastic origin were present. The QF-PCR analysis was performed in all 93 IUL samples and paternal peaks could be documented in 88 cases (94.6%) thus confirming the presence of fetal cells. Thirteen cases negative to micromanipulation and derived from male fetuses and four male cases not informative with QF-PCR analysis, after micromanipulation, were then tested with FISH assay using probes for sexual chromosomes. In six samples, rare (2-3%) male fetal cells were detected. Considering the combined results obtained from QF-PCR and FISH assays, the overall fetal sexing was correct in 83.2% of cases (94 of 113).

CONCLUSION

This study provides evidence that fetal cells are present in a high proportion of IUL samples. Micromanipulation appears to be an extremely efficient method for the isolation of trophoblastic elements. This study also confirms the potential of IUL as a possible alternative to the traditional prenatal diagnostic procedures for the recovery of fetal cells in precocious stage of gestation, and validates the combination of the isolation of such fetal elements by means of micromanipulation and analysis with the QF-PCR assay for the identification of the most frequent prenatal chromosomal aneuploidies.

Prenatal diagnosis of trisomy 21 through detection of trophoblasts in cervical smears

BACKGROUND

Fetal cells exfoliate in the uterine cavity during early pregnancy and are a potential source of material for NIPD.

AIMS

This study was designed to test the hypothesis that fetal cells obtained from the uterine cervix during the first trimester of pregnancy could be utilized for prenatal diagnosis of chromosomal aneuploidy.

STUDY DESIGN

Fetal cells retrieved from the distal endocervical canal during the first trimester of pregnancy were hybridized with chromosome 21 specific FISH probes and analyzed with an automated fluorescence microscope.

SUBJECTS AND OUTCOME MEASURES

Cells with 3 copies of chromosome 21 were detected in 5 out of 5 trisomy 21 pregnancies.

RESULTS

The number of trisomic cells detected ranged from 1 to 27 with a median value of 5.

CONCLUSIONS

FISH-based scanning can identify trisomy 21 pregnancies by analysis of routine cervical brushings. The approach offers the potential for non-invasive prenatal diagnosis as early as 5 weeks gestation.

Transcervical retrieval of fetal cells in the practice of modern medicine: a review of the current literature and future direction

OBJECTIVE

To review published methods for transcervical collection of fetal cells and to assess the potential of this approach for application in prenatal diagnosis.

MAIN OUTCOME MEASURE(S)

Retrospective analysis of efforts at prenatal diagnosis with trophoblast cells shed into the lower uterine pole that accumulate within the cervical mucus at the level of the internal os.

RESULT(S)

Minimally invasive techniques that include cervical mucus aspiration, cervical swabbing, and cervical or intrauterine lavage can be used to retrieve trophoblast cells during the first trimester for diagnostic purposes, including for prenatal genetic analysis. Fetal cells have been identified in these specimens with success rates that vary from 40% to 90%. The disparity in reported success rates can be a function of gestational age, collection method, operator variability, detection sensitivity, or pregnancy status. Molecular approaches have been devised to determine fetal sex and identify aneuploidies. Antibody markers have proven useful to select trophoblast cells for genetic analysis and to demonstrate that the abundance of recoverable fetal cells diminishes in abnormal gestations, such as in ectopic pregnancy or blighted ovum.

CONCLUSION(S)

Transcervical collection of fetal cells offers several avenues for prenatal diagnosis that with further refinement could one day provide valuable information for the management of ongoing pregnancies.

The presence of trophoblastic cells in intrauterine lavage samples: lack of correlation with maternal and obstetric characteristics

OBJECTIVES

To investigate the correlation between maternal, obstetric and sample characteristics and the quality (i.e. yield of trophoblastic cells) of intrauterine lavage (IUL) samples.

METHODS

We collected 202 IUL samples from women scheduled for first trimester termination of pregnancy (TOP). Trophoblastic cells were isolated from IUL samples and used for DNA analysis by a multiplex quantitative fluorescent polymerase chain reaction (QF-PCR) assay. A multivariate logistic regression analysis was performed, and a p<0.05 was considered statistically significant.

RESULTS

The presence of trophoblastic cells in IUL samples was documented in 151/202 cases (74.7%). Blood contamination of IULs was the only characteristic to positively correlate with the presence of trophoblasts (p=0.039; OR: 1.99; 95% CI: 1.03-3.82).

CONCLUSIONS

The correlation between the presence of contaminating blood and trophoblastic cells would indirectly confirm the hypothesis that IUL might act as a mini-CVS. The high yield rate of trophoblasts irrespective of maternal characteristics and past obstetric history would support the clinical use of this sampling technique, provided that its safety is clearly defined.

Prenatal diagnosis of common aneuploidies in transcervical samples using quantitative fluorescent-PCR analysis

AIM

The aim of this study was to test the feasibility of diagnosing common fetal chromosomal aneuploidies using quantitative fluorescent (QF)-PCR on transcervical cell (TCC) samples collected in the first trimester of pregnancy by means of intrauterine lavage (IUL).

METHODS

A total of 181 TCC samples were retrieved from pregnant women between 5 and 12 weeks of gestation, immediately before elective termination of pregnancy, at which time corresponding placental tissue and maternal blood specimens were also obtained. Isolation of trophoblastic cells by micromanipulation was attempted in all TCC samples. Micromanipulated specimens were analyzed by multiplex QF-PCR, including short tandem repeats for the chromosomes X, Y, 21, 18, and 13.

RESULTS

The micromanipulation was successful in 152 of 181 cases (84.8%) where chorionic villous filaments and/or cell clumps of seeming trophoblastic origin could be isolated. All 152 samples were tested by QF-PCR analysis and peaks of paternal origin could be documented in all cases. Two cases of trisomy 21 and two cases of monosomy X0 were detected by means of QF-PCR assay, in accordance with the results obtained in corresponding placental samples.

CONCLUSION

This study provides evidence that the use of multiplex QF-PCR amplification of selected microsatellites could be applied to micromanipulated TCC samples and in particular to IUL samples, which often contain trophoblastic cells, for the detection of chromosomal aneuploidies. The approach described in this study appears, therefore, a very promising tool toward non-invasive prenatal genetic diagnosis in the early stage of gestation.

Fetal cells in a transcervical cell sample collected at 5 weeks of gestation

Transcervical cell (TCC) sampling is being investigated as a promising method for obtaining fetal cells for prenatal genetic diagnosis. The present case report describes the identification of fetal cells by both fluorescent in situ hybridisation (FISH) and quantitative fluorescent polymerase chain reaction (QF-PCR) analyses in a TCC sample collected by intrauterine lavage at 5 + 0 weeks. This finding underscores the possible relevance of TCC sampling for extremely early prenatal genetic diagnosis.

[Molecular chromosomic genetics in prenatal and perinatal diagnosis of chromosomal anomalies and genetic diseases]

Prenatal and perinatal diagnosis needs a rapid, accurate and overall genome analysis. Molecular chromosomic techniques such as fluorescent in situ hybridization (FISH) with "cold" (not radioactively labeled) probes combine techniques of both conventional chromosome banding and molecular biology. FISH is a powerful tool for detecting some genetic diseases as well as microscopic or submicroscopic chromosome rearrangements, in metaphases cells or interphase nuclei.

DNA identification of fetal cells isolated from cervical mucus: potential for early non-invasive prenatal diagnosis

OBJECTIVES

To develop a reliable method to isolate fetal cells for genetic diagnosis.

DESIGN

Aspiration of cervical mucus from pregnant women in the first trimester.

SETTING

Pregnant women were recruited before an elective termination of pregnancy.

POPULATION

Sixty pregnant women (7-10 weeks of gestation).

METHODS

Fetal cells were isolated from aspirated cervical mucus of pregnant women using a combination of enzymatic digestion, fluorescent immunohistochemistry, micromanipulation and single-cell DNA allelic profiling.

MAIN OUTCOME MEASURES

The isolation and identification of fetal cells.

RESULTS

The transformation of the tenacious cervical mucus into a single-cell suspension enabled the isolation and identification of fetal cells by fluorescent immunohistochemistry. Confirmation of fetal origin was accomplished by single-cell DNA allelic profiling alongside known maternal cells.

CONCLUSIONS

This novel non-invasive method is rapid and efficient with results attainable within 24 hours as early as seven weeks of gestation. The technique would offer earlier reassurance and the option of first trimester therapeutic abortions to both high and low risk pregnant women.

Comparison of two techniques for transcervical cell sampling performed in the same study population

OBJECTIVES

The aim of this study was to evaluate and compare the presence of fetal cells in transcervical cell (TCC) samples collected in the first trimester of pregnancy by two different procedures [mucus collection and intrauterine lavage (IUL)], performed consecutively in the same subjects scheduled for elective termination of pregnancy (TOP).

METHODS

A total of 126 mucus/IUL sample pairs were retrieved from pregnant women immediately before TOP at a gestational age ranging from 7 to 12 weeks; at termination, samples of placental tissue were collected in all cases. All mucus samples were analysed by a polymerase chain reaction (PCR) assay and, in a subset of experiments involving 56 specimens, also by fluorescence in situ hybridization (FISH) procedure. IULs were divided in two aliquots, one for PCR analysis and one for the preparation of FISH slides. All placental tissue samples obtained at termination were analysed by FISH for fetal sexing. The PCR assay for fetal sex determination was performed by using, in a multiplex reaction, primers for SRY (Y chromosome sex-determining region, 738 bp) and HUMARA (human androgen receptor on the X chromosome, 280 bp) genes. The FISH analysis was carried out using direct-labelled commercial probes for X chromosome alpha-satellite (DXZ1, Xp11.1-q11.1, spectrum green) and Y chromosome alpha-satellite (DYZ3, Yp11.1-q11.1, spectrum orange) regions.

RESULTS

In samples from known male pregnancies (n = 67), full concordance between IUL and mucus results could be found in 11 cases (16.4%); in 41 cases, Y chromosome material was detected by FISH (n = 2), by PCR (n = 5) or both (n = 34) in IUL samples, but not in the corresponding mucus samples. Y chromosome material was not documented in 10 mucus/IUL sample pairs. In 5 cases, the FISH (n = 2), the PCR (n = 1) or both (n = 2) failed to detect Y chromosome material in IULs, which was detected, however, by PCR in the corresponding mucus samples. Overall, correct sex prediction was achieved in 55/67 IULs (82%) and in 16/67 (23.9%) mucus samples from male pregnancies. In samples from known female pregnancies (n = 56), full concordance between results of IUL/mucus pairs and those on placental samples could be found in 53 cases (94.6%); in 3 cases, Y chromosome material was documented by PCR in mucus samples, but not in the corresponding IULs. Correct sex prediction was therefore achieved in 56/56 IULs (100%) and in 53/56 (94.6%) mucus samples from female pregnancies.

CONCLUSION

This study provides evidence that, among TCC sampling techniques, IUL, but not mucus collection, can yield fetal cells in a constant and reliable fashion, which is a basic prerequisite for possible clinical usage. This suggestion had already emerged from some previous investigations but, owing to the study design, differences in study populations can no longer be used to explain the very different and sometimes-conflicting results reported in earlier studies.

Detection of fetal DNA in the peritoneal cavity during pregnancy

There is increasing evidence that fetal cells are commonly shed toward the cervix and in maternal circulation during pregnancy. In this study, a sample of peritoneal fluid was retrieved from a primigravida at 12 weeks' gestation undergoing urgent intervention for the torsion of an adnexal mass; the sample was then analysed by a polymerase chain reaction (PCR) assay using primers for X- and Y-chromosome specific sequences, and Y-derived sequences were identified. The course of pregnancy was then uneventful until term, when the patient delivered a male fetus, thus, supporting the hypothesis of a fetal origin for the Y-derived sequences detected in the peritoneal fluid. Further studies are required in order to confirm these findings and precisely define the origin of these sequences; however, this report seems to provide further evidence of the spreading of fetal cells during gestation and addresses relevant issues as to the possibility of collecting these cells by culdocentesis and intraperitoneal lavage for prenatal diagnosis.

Fetal cells in cervical mucus in the first trimester of pregnancy

OBJECTIVES

The aim of this study was to first evaluate the presence of fetal cells in cervical mucus samples collected in the first trimester of pregnancy and then to compare different laboratory methods for the detection of these cells.

METHODS

Mucus samples were collected by using a cytobrush before termination of pregnancy (TOP) from 143 pregnant women between 7 and 12 weeks of gestation. None of the women had undergone an invasive diagnostic procedure prior to cervical mucus sampling. Samples of placental tissue were collected from each patient at TOP. Slides from each sample were first observed under an inverted microscope to detect possible sperm contamination. In the first part of our experiments, 40 mucus samples were treated with a mucolytic solution containing N-acetylcysteine (AC) and were analysed by a polymerase chain reaction (PCR) assay. The second series, consisting of 71 mucus samples, was treated with a mucolytic solution containing dithiothreitol (DTT): all 71 samples were analysed by a PCR-based assay, and an aliquot for fluorescent in situ hybridisation (FISH) analysis was also obtained from 48 out of 71 samples. In the third part of our experiments, performed on 32 mucus samples, mucus trapped on the cytobrush was directly spread on two slides for FISH analysis without any mucolytic treatment. All placental tissue samples obtained at termination were analysed by FISH for fetal sexing.

RESULTS

Overall, the use of PCR-based or FISH analyses on 143 mucus samples resulted in correct sex prediction in 92/143 (64.3%) samples [20/66 (30.3%) cases from known male pregnancies and 72/77 (93.5%) cases from known female pregnancies]. In the AC group, Y-derived sequences were found in 7/23 samples (30.4%) from known male pregnancies and in 1/17 cases from known female pregnancies, with an overall correct sex prediction in 23/40 cases (57.5%). In the DTT group, Y-derived sequences could be amplified in 10/30 samples (33.3%) from known male pregnancies and in 4/41 cases from known female pregnancies, with an overall correct sex prediction in 47/71 cases (66.2%). In the DTT samples analysed by FISH, nuclei bearing XY signals were detected in 5/26 (19.2%) cases from known male pregnancies and in none from female pregnancies, the rate of correct sex prediction being 56.2% (27/48). On untreated mucus samples analysed by FISH, nuclei with XY signals were documented in 3/13 (23%) samples from male conceptuses and in none from known female pregnancies, with an overall correct sex prediction in 22/32 cases (68.7%).

CONCLUSION

Fetal cells were not detected in a constant and reliable fashion in cervical mucus samples collected in the first trimester of pregnancy. The detection rate was poorly influenced by the use of different laboratory methods. This sampling technique cannot be regarded as a promising tool towards minimally invasive prenatal diagnosis.

HLA-G positive trophoblastic cells in transcervical samples and their isolation and analysis by laser microdissection and QF-PCR

OBJECTIVE

To assess the frequency of cytotrophoblastic cells in endocervical samples collected by lavage at early stages of gestation using a specific anti-HLA-G McAb (G233). From a set of four selected samples, cells identified by immunostaining were collected by laser microdissection and then tested by quantitative fluorescent polymerase chain reaction (QF-PCR) for the presence of paternally derived DNA markers, in order to establish their fetal origin.

METHODS

Syncytial fragments and cytotrophoblastic cells from 23 transcervical samples were identified by immunostaining with McAb G233 reacting against HLA-G antigen and with antibodies against cytokeratin. Slides from the same samples were also tested by fluorescent in situ hybridization (FISH), while selected samples were analysed by QF-PCR. Slides from four samples retrieved from mothers with male fetuses were immunolabelled and then cytotrophoblastic cells, syncytial fragments and maternal epithelial cells were collected by laser microdissection and tested by QF-PCR.

RESULTS

All endocervical samples retrieved from mothers with male fetuses were found to contain some cells with chromosome Y-specific signals when tested by FISH. Using McAb anti- HLA-G, cytotrophoblastic cellular elements were detected in about 50% of the samples. From four samples, cellular elements identified by immunostaining as cytotrophoblast or syncytial fragments were collected by laser microdissection and shown to be of fetal origin when tested by QF-PCR for the presence of fetal DNA markers.

CONCLUSIONS

These results confirm that, during an early phase of gestation, fetal cells are released in the lower uterine cavity and that they can be isolated and analysed for prenatal diagnosis of single gene defects and aneuploidies.

Prenatal diagnosis: molecular genetics and cytogenetics

The technologies developed for the Human Genome Project, the recent surge of available DNA sequences resulting from it and the increasing pace of gene discoveries and characterization have all contributed to new technical platforms that have enhanced the spectrum of disorders that can be diagnosed prenatally. The importance of determining the disease-causing mutation or the informativeness of linked genetic markers before embarking upon a DNA-based prenatal diagnosis is, however, still emphasized. Different fluorescence in situ hybridization (FISH) technologies provide increased resolution for the elucidation of structural chromosome abnormalities that cannot be resolved by more conventional cytogenetic analyses, including microdeletion syndromes, cryptic or subtle duplications and translocations, complex rearrangements involving many chromosomes, and marker chromosomes. Interphase FISH and the quantitative fluorescence polymerase chain reaction are efficient tools for the rapid prenatal diagnosis of selected aneuploidies, the latter being considered to be most cost-effective if analyses are performed on a large scale. There is some debate surrounding whether this approach should be employed as an adjunct to karyotyping or whether it should be used as a stand-alone test in selected groups of women.