Familial X centromere variant resulting in false-positive prenatal diagnosis of monosomy X by interphase FISH.

Interphase fluorescent in situ hybridization (FISH) analysis performed on uncultured amniotic fluid cells from a female fetus revealed a single signal using an X chromosome alpha-satellite probe, and the absence of any signal using a Y chromosome alpha-satellite probe. This result was initially interpreted as monosomy for the X chromosome in the fetus. Subsequent chromosome analysis from the cultured amniotic fluid cells showed two apparently normal X chromosomes. FISH using the X alpha-satellite probe on metaphase spreads revealed hybridization to both X chromosomes, although one signal was markedly reduced compared to the other. The same hybridization pattern was observed in the mother of the fetus. This is the first report of a rare familial X centromere variant resulting in a false-positive diagnosis of monosomy X by interphase FISH analysis for prenatal diagnosis.     

Rapid detection of chromosomes X and Y aneuploidies by quantitative fluorescent PCR

Quantitative fluorescent polymerase chain reaction (QF-PCR) assays and small tandem repeat (STR) markers have been successfully employed for the rapid detection of major numerical aneuploidies affecting human autosomes. So far, the analysis of chromosomes X and Y disorders has been hampered by the rarity of highly polymorphic markers which could distinguish normal female homozygous PCR patterns from those seen in patients with Turner's syndrome. A new marker (X22) of the X/Y chromosomes has been identified which maps in the Xq/Yq pseudoautosomal region PAR2; used together with the HPRT it allows the rapid diagnosis of numerical aneuploidies of the sex chromosomes. Blood samples from normal male and female subjects and from patients with X and Y chromosome disorders (45,X and 47, XXY) have been tested by QF-PCR with the X22 polymorphic pentanucleotide (12 alleles) together with the HPRT and P39 markers. The samples were also tested by multiplex QF-PCR with STRs specific for chromosomes 21,18,13 and amelogenin (AMXY). Tested by QF-PCR, all samples from normal females were heterozygous for either the X22 or the HPRT marker with fluorescent peak ratios near 1:1, thus allowing a correct, rapid diagnosis of their chromosome complement. Turner's patients (45,X) showed only one X22 and one HPRT fluorescent peak, thus documenting the presence of a single X chromosome. Turner's patients with mosaicism showed a major fluorescent peak for the X22 and HPRT markers and a minor peak revealing the presence of a second minor population of cells. Two 47, XXY cases could also be diagnosed. Multiplex analyses can be performed using simultaneously STR markers for chromosomes 21,18,13 X and Y. The diagnostic value of a third X-linked marker (P39) was also investigated. These results suggest that rapid diagnosis of major numerical anomalies of the X and Y chromosomes can be performed using QF-PCR with a new highly polymorphic X-linked marker, X22, which maps in the Xq/Yq pseudoautosomal region PAR 2. Multiplex QF-PCR tests-using the X22 STR in association with HPRT and, in rare cases, a third P39 marker-allow the rapid diagnosis of major aneuploidies affecting chromosomes 21, 18, 13, X and Y. The X22 marker can also be employed for the detection of fetal cells present in maternal peripheral blood or the endocervical canal.     

DYZ1 copy number variation, Y chromosome polymorphism and early recurrent spontaneous abortion/early embryo growth arrest

Objectives

To find the association between recurrent spontaneous abortion (RSA)/early embryo growth arrest and Y chromosome polymorphism.

Study design

Peripheral blood samples of the male patients of big Y chromosome, small Y chromosome and other male patients whose partners suffered from unexplained RSA/early embryo growth arrest were collected. PCR and real-time fluorescent quantitative PCR were used to test the deletion and the copy number variation of DYZ1 region in Y chromosome of the patients. A total of 79 big Y chromosome patients (48 of whose partners suffered from RSA or early embryo growth arrest), 7 small Y chromosome patients, 106 other male patients whose partners had suffered from unexplained RSA or early embryo growth arrest, and 100 normal male controls were enrolled.

Results

There was no fraction deletion of DYZ1 detected both in big Y patients and in normal men. Of RSA patients, 1 case showed deletion of 266 bp from the gene locus 25–290 bp, and 2 cases showed deletion of 773 bp from 1347 to 2119 bp. Of only 7 small Y chromosome patients, 2 cases showed deletion of 266 bp from 25 to 290 bp, and 4 cases showed deletion of 773 bp from 1347 to 2119 bp and 275 bp from 3128 to 3420 bp.The mean of DYZ1 copies was 3900 in normal control men; the mean in big Y patients was 5571, in RSA patients was 2655, and in small Y patients was 1059. All of the others were significantly different (P < 0.01) compared with normal control men, which meant that DYZ1 copy number in normal control men was less than that of big Y chromosome patients, and was more than that of unexplained early RSA patients and small Y patients.

Conclusions

The integrity and copy number variation of DYZ1 are closely related to the Y chromosome length under microscope. The cause of RSA/early embryo growth arrest in some couples may be the increase (big Y patients) or decrease of DYZ1 copy number in the husbands’ Y chromosome.     

Prenatal diagnosis of 45,X and 45,X mosaicism: the need for thorough cytogenetic and clinical evaluations

OBJECTIVES: Mosaicism involving a 45,X cell line is relatively common in prenatal diagnosis. In prenatally diagnosed cases, the prognosis of non-mosaic 45,X and 45,X/46,XY mosaicism are different. Therefore, accurate identification of a cell line containing Y chromosome is critical for genetic counseling and postnatal management. METHODS: We investigated the ultrasound findings and outcomes of pregnancies with a 45,X cell line identified during mid-trimester cytogenetic analysis. RESULTS: A total of 105 cases were found to have a 45,X cell line by standard cytogenetic analysis. Seventy-four cases were found to have non-mosaic 45,X at initial diagnosis. Of these 74 cases, 68 had abnormal ultrasound findings that were characteristic of Turner syndrome. Of the six cases with normal ultrasound findings, ultrasound examination was normal with male genitalia identified in three cases. Thorough cytogenetic and fluorescent in situ hybridization (FISH) analysis identified Y chromosome material in all three cases, one with a dicentric Y;14 chromosome and the other two cases with a marker chromosome containing Sex-determining Region (SRY) material in a small portion of the cells. In contrast, in 31 cases with a mosaic 45,X karyotype, ultrasound abnormality was identified only in one case. CONCLUSIONS: The present data suggest the need for follow-up ultrasound examination and thorough cytogenetic and molecular analysis for Y chromosome material in 45,X cases with normal ultrasound findings.     

Prenatal diagnosis of common aneuploidies using quantitative fluorescent PCR

OBJECTIVE: Quantitative fluorescence-polymerase chain reaction (QF-PCR) has recently been used for the detection of common chromosomal aneuploidies in prenatal diagnosis. Here we describe our experience in prenatal diagnosis of 1100 samples. METHODS: Extraction of DNA was performed from amniotic fluid, chorionic villus samples (CVS), fetal blood and fetal tissue samples, using a simple, rapid protocol. Fluorescent multiplex PCR products of single tandem repeats (STRs) located on chromosomes 13, 18, 21, X and Y were then analyzed on an automated laser fluorescent sequencer. All samples were analyzed with at least two polymorphic markers for chromosomes 13, 18 and 21 and one for the X chromosome. The amelogenin locus was used for sexing. Analysis was performed twice on affected samples. When miscellaneous results were obtained extra markers were used. RESULTS: We evaluated the usefulness of different markers in the Greek population. In a total of 1100 samples, 25 chromosome aberrations were identified, including trisomy 13, 18 and 21, XYY, triploidies 69,XXX and 69,XXY and one Turner mosaic. All results but three were consistent with conventional cytogenetic analysis. One mosaic was missed. Most bloodstained samples were successfully analyzed. CONCLUSION: Successful analysis of a large number of prenatal samples proves QF-PCR to be an efficient adjunct in routine prenatal diagnosis.     

A normal birth following preimplantation genetic diagnosis by FISH determination in the carriers of der(15)t(Y;15)(Yq12;15p11) translocations: two case reports

Purpose To investigate the clinical application of fluorescence in situ hybridization (FISH) for assessing chromosome disorders of embryos in preimplantation diagnosis of carriers with der(15)t(Y;15)(q12;p11) translocations. Methods Multicolor FISH was performed using directly-labelled DNA probes, chromosome X with one (DXZ1, Xp11.1-q11.1), but Y with two (DYZ3, Yp11.1-q11.1 and DYZ1, Yq12). Normal embryos were transferred on day 6 at blastocyst stage. Results Couple A: Three of 6 biopsied embryos were normal. Two normal blastocysts were transferred, but no pregnancy was achieved. Couple B: Three of 6 biopsied embryos were normal. Two normal blastocysts were transferred. A normal male infant weighing 3,230 g was born by cesarean section on the 39th week of gestation. All of the remaining nonreplaced embryos showed mosaic or der(15). Conclusion Embryos from carries of der(15)t(Y;15)(q12;p11) translocation showed a high frequency of chromosome abnormalities. PGD is a valuable screen tool for those couples to treat their infertility and break the transmission of der(15) chromosome for their offspring.     

光谱核型分析技术在标记染色体诊断中的应用

目的 探讨光谱核型分析(SKY)技术在标记染色体诊断中的应用价值.方法 选取临床工作中未能确诊的6个标记染色体病例(包括外周血标本4例和羊水、脐血产前诊断标本各1例),其中4例是为诊断目的 ,2例是为产前诊断目的 .按SKY技术操作常规进行制片杂交,通过相应的计算机软件分析结果.应用荧光原位杂交(FISH)对SKY技术分析结果行进一步鉴定;并应用C显带技术对染色体的异染色质成分进行辅助诊断.结果 6个标记染色体病例均成功地进行了SKY技术分析,并明确了标记染色体的来源;除病例4外,其他5个病例的FISH鉴定结果均与SKY技术分析结果相符.在明确诊断的2例产前诊断病例中,1例属家族遗传性的标记染色体病例,因而继续妊娠,至足月顺产一女婴,产后随访至今,女婴生长发育未见异常;而另1例属新发生的标记染色体病例,因而于孕25周时终止妊娠.结论 SKY技术可以快速、直观和准确地诊断不明来源的标记染色体.     

47,XX + mar karyotype containing genes from the azoospermia factor region. A case report

BACKGROUND: Abnormal embryo development is the major cause of implantation failure and accounts for the low rate of human fertility in vitro and in vivo. Chromosome abnormalities are widely involved in this process through meiotic nondisjunction, fertilization abnormalities and mitotic nondisjunction. CASE: In our assisted reproductive technology program a couple underwent cytogenetic analysis. The woman had a 47,XX + mar karyotype. We investigated this patient by chromosome analysis, fluorescence in situ hybridization (FISH) and polymerase chain reaction (PCR) DNA analysis. The marker chromosome was found to be very similar to a Y chromosome in size and QFQ staining pattern. Therefore, it was tested by FISH using alpha- and beta-satellite DNA specific for the Y chromosome, some YACs specific for the long arm of the Y chromosome and alpha-satellite DNA specific for 15 chromosomes as probes. In order to define this marker, the next step was PCR amplification of the whole genomic DNA using specific landmarks (sequence-tagged sites) to encompass the azoospermia factor (AZF) region on the long arm of the Y chromosome. CONCLUSION: A woman had an extra chromosome containing centromeric DNA derived from the Y and 15 other chromosomes, heterochromatic regions derived from 15 chromosomes and a large heterochromatic block at the end of the long arm that definitely was not Y chromosome heterochromatin (beta-satellite). PCR showed several genes of the Y chromosome long arm that are assumed to be involved in male gametogenesis. Phenotypic effects could not be excluded because of the presence of AZF genes. Oocyte karyotyping might better explain the role of the genetic problem on female infertility.     

Evaluation of sex chromosome aneuploidies in women with Turner's syndrome by G-banding and FISH. A serial case study

OBJECTIVE: To evaluate sex chromosome aneuploidies in patients with Turner's syndrome using two cytogenetic techniques. STUDY DESIGN: A sample of 35 women with a clinical suspicion of Turner syndrome was examined in the Hospital of Obstetrics and Gynecology, Instituto Mexicano del Seguro Social, Monterrey, Mexico. They were subjected to a conventional cytogenetic technique with G-banding and to fluorescence in situ hybridization (FISH) using a specific alpha satellite X chromosome (DXZ1) and specific alpha satellite Y chromosome (DYZ1). RESULTS: Using both techniques, 17 cases (48.57%) showed the same karyotype. Using FISH: (1) in 8 cases the presence of the Y chromosome was confirmed, (2) in 18 cases (51.43%) a new cell line was identified, (3) in 2 cases (5.71%) the derivative X was clarified, and (4) in 3 cases (8.57%) the origin of the chromosome markers (1 of X chromosome and 2 of Y chromosome) was delineated. FISH highlighted the differences between the initial diagnosis, based on G-banding, and the final diagnosis, determined by specific probes for the X and Y chromosomes. CONCLUSION: FISH is a useful tool in the detection of low-frequency cell lines and identification of the nature and origin of derivative chromosomes and unknown chromosome markers that have important implications for the treatment of patients with Turner's syndrome.     

Role of mitotic control in spermatogenesis

OBJECTIVE: To study the correlation between the incidence of sex chromosome aneuploidies in the somatic cells and spermatozoa in karyotypically normal infertile men and fertile donors. DESIGN: A prospective, phase two, controlled study. SETTING: A teaching Hospital Reproductive Medicine and Medical Genetics Units. PATIENT(S): Ten patients with idiopathic oligozoospermia and 10 sperm donors with proven fertility, all with a normal karyotype 46, XY. INTERVENTION(S): Multicolor fluorescence in situ hybridization (FISH) of peripheral blood lymphocytes and spermatozoa using a probe cocktail containing the alpha satellite DXZ1 for the X centromere, DYZ1 for the heterochromatic region of the long arm of the Y, and cosmids D21S259, D21S341, and D21S342 for Down syndrome critical region of chromosome 21. MAIN OUTCOME MEASURE(S): The incidence of chromosome X, Y, and 21 aneuploidies in peripheral lymphocytes and spermatozoa in both groups. RESULT(S): The incidence of aneuploidies related to chromosomes X, Y, and 21 were significantly higher in peripheral lymphocytes and spermatozoa of infertile men compared with donors. There was a positive correlation between the incidence of chromosome aneuploidies in the somatic cells and sperm in all men. CONCLUSION(S): These findings provide suggestive evidence for the importance of mitosis in spermatogenesis and the role of mitotic instability in unexplained oligozoospermia.     

荧光原位杂交技术快速产前诊断胎儿血细胞非整倍体的价值

目的 探讨荧光原位杂交（FISH）技术在产前诊断脐血细胞非整倍体中的应用价值：方法 2004-06—2005-03，对广州市妇婴医院114例孕18～38W有产前诊断指征的孕妇进行脐血穿刺。采用X／Y染色体着丝粒探针和21q22．13-q22．2特异性探针对脐血细胞进行间期FISH检测，然后在荧光显微镜下观察，用Leica染色体核型自动分析仪QFISH软件进行图像的摄取和处理。同时所有脐血标本进行细胞培养，常规染色体G显带核型分析作为对照。结果 114例脐血标本都有FISH检测结果，107例具有正常核型染色体数目，异常7例，其中4例为唐氏综合征（3例为典型唐氏综合征，1例为嵌舍体），3例为性染色体数目异常。结论 FISH技术用于产前诊断脐血常见染色体数目异常，具有简便、快速、特异性强等优点，能为临床诊断提供依据。     

Rapid-FISH--fast and reliable method of detecting common numerical chromosomal aberrations in prenatal diagnosis

OBJECTIVE: In recent years, new possibilities of prenatal diagnosis have opened up, due to the development of techniques which guarantee shorter time of obtaining results. One of those methods, called Rapid-FISH (rapid fluorescence in situ hybridization), for detecting numerical aberrations of chromosomes 13, 18, 21, X and Y without culturing, enables to have the results in 2-5 days. The time necessary to obtain fetal karyotype result with the usage of the classical cytogenetic methods is about 2-3 weeks and depends mainly on the culture growth rate. DESIGN: The aim of the study was to evaluate the effectiveness of the Rapid-FISH technique in detecting numerical chromosome aberrations of 13, 21, 18, X and Y in amniocytes' nuclei from amniotic fluid. MATERIALS AND METHODS: Rapid-FISH and cytogenetic analysis has been performed for 161 pregnancies in the Department of Genetics at Wroclaw Medical University during years 2005 and 2006. The FISH was performed using AneuVysion kit (Vysis), according to a standard protocol. RESULTS: All normal and abnormal results were confirmed by classical cytogenetic method (GTG banding and karyotyping). Additional chromosomal aberrations, not possible to be detected in FISH, were observed in case of two patients with normal results from FISH analysis. CONCLUSIONS: Rapid-FISH is a reliable and fast method for detecting numerical chromosomal aberrations in prenatal diagnosis and should be implemented as a routine diagnostic procedure in pregnancies with high risk of fetal aneuploidy (of chromosomes 13, 18, 21, X i Y).     

改良荧光原位杂交技术在产前诊断中的应用

目的:评价改良荧光原位杂交(fluorescent in situ hybridization,FISH)技术在产前诊断中的应用。方法:用改良FISH技术检测119例孕16~24周孕妇的羊水间期细胞及10例孕25~32周胎儿脐血间期细胞,5例孕9~12周绒毛间期细胞,每例均行常规染色体核型分析。结果:应用改良FISH法,所有样本均在6h内获得检测结果,除2例羊水培养失败外,其余样本均在3周内获得细胞遗传学诊断。两种方法均检出特氏综合征、18-三体综合征、21-三体综合征各1例,另5例常规染色体核型分析异常,因超出检测范围,FISH法未能检出,所有样本的两种方法检测结果均一致。结论:经改良后的FISH技术缩短了诊断时间,缓解了孕妇及家属的焦虑心情,且可用于多种不同样本的检测,因其高效、省时、取材多样等优点在产前诊断具有重要的临床价值。     

A case of XY pure gonadal dysgenesis with 46,XYp-/47,XXYp- karyotype whose gonadoblastoma was removed laparoscopically

A case of pure gonadal dysgenesis was investigated. The patient was an 18-year-old Japanese woman with a history of primary amenorrhea. She had poorly developed breasts, a hypoplastic uterus, a normal vagina and infantile genitalia. The patient's karyotype was 46,XYp-/ 47,XXYp-. Microsatellite analysis revealed that the X chromosomes of this patient originated from one of the two maternal X chromosomes. DNA analysis of the Y chromosome revealed that she had a deletion of SRY (the sex-determining region on the Y chromosome). She underwent laparoscopic gonadectomies with a final pathology consistent with gonadoblastoma. Laparoscopic surgery is recommended as it is much less invasive and associated with rapid postoperative recovery.     

Turner综合征Y染色体物质嵌合分子遗传学研究

摘要：目的　分析Turner综合征（TS）患儿Y染色体物质及衍生物嵌合发生的情况，为TS患儿诊断后的监测提供科学建议，改善国内TS监测和保健管理的现状。方法　选取2006年2月至2007年8月在重庆医科大学附属儿童医院诊断为TS患儿30例，进行基因组DNA 的Y编码睾丸特异性蛋白基因（TSPY）、 Y染色体中心着丝粒DYZ3重复序列（DYZ3 ）和Y性别决定区域（SRY）3个Y染色体特异序列多聚酶链反应（PCR）检测，反应结果阳性的病例补充SRY探针原位荧光杂交（FISH）分析。结果　基因组DNA 的PCR结果显示，3例患儿的TSPY、 DYZ3扩增均为阳性（10.00%），其中只有1例 SRY 扩增阳性（3.33%）；3例Y染色体物质阳性病例进一步进行FISH研究，结果显示3例SRY杂交信号均为阳性。结论　运用3个Y染色体特异序列的分子遗传学研究，证实Y染色体物质嵌合在TS不少见，每一个TS患儿都应在诊断后进行Y染色体物质的分子遗传学监测。     

Effectiveness of prenatal chromosomal analysis using multicolor fluorescent in situ hybridisation

Objective To evaluate the clinical effectiveness of multicolour fluorescent in situ hybridisation (FISH) analysis in routine prenatal diagnosis.
Design Prospective study.
Sample 3203 amniotic fluid samples.
Methods Unique DNA (chromosomes 13 and 21) and α satellite centromeric-specific (chromosomes X, Y and 18) probes were used in two mixes to permit the simultaneous analysis of several chromosomes. The performance of multicolour FISH and conventional cytogenetic analysis was compared.
Results Conventional cytogenetic analysis identified 111 chromosomal abnormalities, of which 94 were potentially detectable by the FISH technique and 97 would be typically associated with neonatal phenotypic abnormalities. Multicolour FISH analysis detected 84% (93/111) of all chromosome abnormalities and 99% (93/94) of abnormalities where there was a specific probe. The sensitivity of multicolour FISH analysis was 95% (92/97) for chromosomal abnormalities likely to result in an abnormal postnatal outcome. Multiple ultrasound abnormalities were detected in all five cases of clinically relevant chromosomal abnormalities missed by multicolour FISH. FISH results were available within 48 hours and the sample failure rate was 0.1% (3/3202).
Conclusion Multicolour FISH analysis is a sensitive and reliable technique for the rapid prenatal diagnosis of chromosomal abnormalities. Examining only five chromosomes allowed 95% of clinically relevant chromosomal abnormalities to be diagnosed correctly. As routine antenatal screening is targeted at the major autosomal trisomies and sex chromosome aneuploidies, multicolour FISH analysis may potentially replace conventional cytogenetic analysis in routine prenatal diagnosis.     

应用荧光原位杂交技术诊断羊水细胞染色体异常

探讨荧光源位杂交技术于产前诊断羊水细胞染色体异常的实验方法的应用价值。方法对３４例孕１６－２３周有产前认旨征者经腹部抽取羊水,用Ｃｈａｎｇ培养液传代培养,常规制备羊水细胞分裂中期染色体,应用生物素及地高辛标记的人类全着线粒探针和Ｘ、Ｙ、１３、２１、１８号染色体     

Detection of chromosome abnormalities by quantitative fluorescent PCR in ectopic pregnancies

OBJECTIVE: To evaluate the potential value of quantitative fluorescent polymerase chain reaction (QF-PCR) in the detection of chromosome abnormalities in ectopic pregnancies. METHODS: Seventy chorionic villi samples of ectopic pregnancies were studied by QF-PCR. Primers for chromosomes 16, 21, X and Y in chorionic villi were evaluated. Fluorescence in situ hybridization (FISH) was performed when results of QF-PCR showed aneuploidy, in case of unexplicable QF-PCR peaks, and in 10 cases with normal QF-PCR results. RESULTS: QF-PCR produced a result for chromosomes X and Y in 66 cases (94%), for chromosome 16 in 62 cases (89%) and for chromosome 21 in 55 cases (79%). Overall, QF-PCR produced a result for the chromosomes tested in 54 ectopic pregnancy cases (77%). Fifty-two of these results were normal disomic (96%) and two were abnormal, one trisomy 16 (2%) and one triploidy (2%). In 16 cases (23%) no definite QF-PCR results could be obtained for all chromosomes, 11 due to amplification failure, and 5 due to unexplicable QF-PCR peaks. In 10 cases with normal QF-PCR results, disomy was confirmed by FISH. The trisomy 16 was also confirmed by FISH. Furthermore, a result was obtained with FISH in 5 of the cases without definite QF-PCR results. CONCLUSION: Although QF-PCR can establish the chromosomal status in ectopic pregnancies for chromosomes 16, 21, X and Y in the majority of cases, the technical failure rate is still considerable and does not improve results when compared to cytogenetic techniques.     

Prenatal diagnosis of trisomy 21 without the Down syndrome phenotype

OBJECTIVE: To report a patient with the prenatal diagnosis of trisomy 21 without the clinical Down syndrome (DS) phenotype secondary to the absence of the Down syndrome chromosomal region (DSCR) in a derivative chromosome 21. CASE REPORT AND METHODS: A newborn patient with prenatal diagnosis of duodenal atresia. Cytogenetic studies revealed a regular trisomy 21. At birth, she did not present the clinical features of DS. FISH analysis was performed in the patient with the LSI spectrum probe for the DSCR and in the mother with FISH multicolor analysis using painting probes for chromosomes 20 and 21. RESULTS: FISH analysis in the patient showed two hybridization signals suggesting that the third chromosome 21 did not have the DSCR region explaining the absence of the DS phenotype. FISH multicolor analysis in the mother showed three hybridization signals for chromosomes 20 and 21, concluding a maternal karyotype, 46,XX,t(20;21)(p11.2;q22.1). CONCLUSIONS: The patient was found to have a derivative chromosome 21 secondary to a nondisjunction error in meiosis II without the DS critical region and the phenotype was mostly secondary to the combination of the two partial trisomies.     

应用引物原位标记快速产前诊断20例胎儿染色体非整倍体

目的：探讨引物原位标记（PRINS）应用于脐血间期细胞进行快速产前诊断染色体非整倍体的准确性及可行性。方法：采用18，21，13，X，Y染色体特异性引物，检测20例脐血间期细胞染色体数目，并与染色体G带分析结果比较。结果：采用PRINS方法检测20例脐血标本，检出1例13－三体，1例18－三体，2例21－三体，与染色体G带分析结果一致，准确率达100％。结论：PRINS产前诊断染色体数目异常，具有准确性高、快速、简便、价廉的特点，值得进一步研究与推广。