Fetal blood chromosome analysis: some new indications for prenatal karyotyping

Summary. Prenatal karyotyping using stimulated fetal blood lymphocytes was undertaken in 170 pregnancies between 16 and 36 weeks gestation for the following reasons-(1) mosaicism or marker chromo somes found in amniotic fluid culture; (2) a family history of X-linked mental retardation with fragile Xq28; (3) fetal abnormalities detected ultrasonographically; (4) late booking or amniotic fluid culture failure in patients with advanced age or balanced translocations; and ( 5 ) twin pregnancies discordant for a chromosomal anomaly. Forty-one karyotypic abnormalities were detected (24%). These were: 45,X (7 cases). trisomy 13 ( 5 cases), trisomy 18 (6 cases), trisomy 21 (4 cases), twin pregnancy where one twin had trisomy 21 (1 case), supernumerary marker chromosome (3 cases, one of which occurred in a twin pregnancy). triploidy (3 cases), X-linked mental retardation with fragile site at Xq28 in males (6 cases), fetal erythroleukaemia (3 cases including 2 cases with Turner's), Fanconi's anaemia (1 case), unbalanced chromosome translocation 47,XY+der22,t(l1;22) mat (1 case), mos 46,XXI8p-/46,XX.-18,+i(l8q) (1 case), 46,XXde1(2q) (1 case), and 46,XYt(5;17) de novo (1 case). In fetuses at high risk of a chromosome aberration. a rapidly obtaincd karyotype is helpful and fetoscopy and fetal blood sampling are justified in the second or third trimester.     

Prenatal diagnosis of X-linked mental retardation with fragile (X) using fetoscopy and fetal blood sampling

Pure fetal blood, (uncontaminated with maternal blood), was obtained from two male fetuses at risk for X-linked mental retardation with fragile(X) at Xq27-28 by direct vision fetoscopy and fetal blood sampling. Both were shown to have this fragile site on the X chromosome while nine other fetal blood samples from pregnancies at risk for other X-linked diseases, or haemoglobinopathies did not show fragile sites at Xq27-28, and a blood sample from an abortus showed only 1 fragile site in 95 mitoses. Both pregnancies were terminated, cultures established from fetal tissues, and the diagnosis confirmed in each case. The problems of demonstrating the fragile site in tissues other than fetal blood in these pregnancies (such as amniotic fluid cells or fibroblasts from fetal tissues) are discussed.     

9例多胎妊娠合并胎儿染色体异常患者的产前诊断和治疗

目的探讨多胎妊娠合并胎儿染色体异常的产前诊断方法及选择性减胎术定位方法。 方法选取2012年1月至2013年12月就诊于广州医科大学附属第三医院9例多胎妊娠合并胎儿染色体异常患者的临床资料,采用回顾性研究方法对其产前诊断方法、染色体异常情况、选择性减胎术的方法及妊娠结局进行分析。 结果9例患者中3例为三胎妊娠,6例为双胎妊娠。(1)产前诊断：①超声检查：9例患者早孕期行超声检查,均提示存在胎儿颈项透明层(nuchal translucency, NT)增厚,孕中期超声检查提示有6例患者存在胎儿结构异常,包括颈部囊肿、心脏异常、外生殖器畸形、足内翻、全身水肿等;②染色体检查：5例胎儿21-三体综合征,1例Turner综合征,1例染色体微缺失,1例染色体重复,1例双胎染色体异常。(2)治疗及妊娠结局：9例患者中7例患者行选择性减胎术治疗,1例流产,3例早产(新生儿均存在并发症),3例足月分娩(新生儿均未见异常);2例患者拒绝减胎,1例于孕中期自然流产,1例于孕35^＋周剖宫产分娩(1胎儿为21-三体综合征,另一胎儿为健康儿)。 结论多胎妊娠应注重早孕期染色体筛查,确诊宫内胎儿染色体异常的患者可在超声引导下行选择性减胎术治疗。     

单纯性染色体18p部分三体综合征患儿的产前遗传学诊断和文献回顾

目的探讨单纯性染色体18P部分三体综合征患者的产前诊断特点。方法联合运用传统染色体核型分析和染色体微阵列(chromosome microarray analysis,CMA)基因芯片技术对家系成员行染色体核型分析和基因组拷贝数变异检测。结果胎儿羊水染色体核型结果为46,XY,der(18),父母双方染色体核型均未见异常;胎儿基因芯片检测结果为arr[hg19]18p11.31p11.21(3,521,718-15,099,116)×3,即胎儿基因组18号染色体短臂p11.31p11.21区域存在11.58 Mb的片段重复,父母双方基因芯片结果均为阴性,提示该胎儿的18号染色体结构重排为新发生的。结论在一个有不良生育史家系的胎儿中检出一个罕见新发的单纯性染色体18p部分三体变异,这是世界少见的单纯性染色体18p部分三体综合征的产前病例报道。联合运用传统染色体核型分析和C M A基因芯片技术在预防不良产史家系中胎儿出生缺陷的产前诊断中具有重要的临床应用价值。     

Rapid karyotyping in fetuses with abnormal sonogram

Prenatal karyotyping of fetuses having an abnormal sonogram was undertaken in 27 pregnancies between 17 and 39 weeks, using fetal blood obtained by percutaneous umbilical cord blood sampling under ultrasound guidance. Eight chromosomal abnormalities (29.7%) were detected, including 45, X (2 cases), trisomy 21(1 case), 46, XY,-13,+t(13,13) (1 case), 47, XX,+18(3 cases), 47, XXY (1 case). Nineteen fetuses had a normal karyotype (46,XX:9 cases, 46,XY:10 cases). The fetal karyotype was available within 72 h and fetal management was planned accordingly. We concluded that in fetuses with an abnormal sonogram, rapid karyotyping using fetal blood obtained under ultrasound guidance had important implications in obstetric and neonatal management and would facilitate genetic counselling.     

Uncommon chromosomal mosaicism in chorionic villi.

Three cases of unusual chromosomal mosaicism are reported for which the cytogenetic data show inconsistent findings between CVS and AC or fetal tissue, and which cannot be explained simply by non-disjunction. For case 1, in CVS the karyotype was 46,XY, whereas lymphocytes and fibroblasts revealed 69,XXY. DNA fingerprinting indicated one paternal and two maternal chromosome sets, the latter most probably due to omission of maternal meiosis II. For case 2, in CVS mos 46,XX/47,XX,+ mar de novo was observed. Amniotic fluid cells had the karyotype 46,XX. The origin of the marker chromosome might be explained by at least two events of unknown order (a somatic chromosome/chromatid deletion and non-disjunction of the homologous chromosome). In case 3 (CVS: mos 46,XY/46,XY,19q+ de novo; amniotic fluid cells, lymphocytes, and fibroblasts: 46,XY), the surplus of chromosome material in 19q+ might be explained on the basis of a somatic translocation. The idea of a chimera is less convincing, as the mosaic finding is restricted to one tissue. Furthermore, there was no hint of a vanishing twin. Hitherto, no case of structural chromosome mosaicism in CVS has been reconfirmed in fetal tissues.     

Prenatal diagnosis of a fetus with distal 10q trisomy.

Distal 10q trisomy is a well-defined but rare syndrome. Most cases are diagnosed in infancy or in childhood and rarely include prenatal findings. We present a case of fetal distal 10q trisomy with abnormal prenatal sonographic findings. A 19-year-old primigravida was referred for genetic counselling at 18 gestational weeks because her husband had a familial history of congenital anomalies. Genetic amniocentesis was thus performed and showed fetal distal 10q trisomy (10q24.1-->qter), 46,XX,der(22)t(10;22)(q24.1;p11.2)pat, resulting from paternal t(10;22) reciprocal translocation. Level II ultrasonograms further demonstrated bilateral hydronephrosis, ventricular septal defect and facial dysmorphism ascertained by three-dimensional ultrasound. The pregnancy was terminated at 22 gestational weeks. Post-mortem autopsy confirmed the sonographic findings. We suggest that abnormal prenatal sonographic findings such as cardio-vascular, renal and facial malformations should alert cytogeneticists to search for subtle chromosomal abnormalities.     

Prenatal diagnosis of the fragile X syndrome using fetal blood and amniotic fluid

Nineteen pregnancies at risk for the Martin-Bell syndrome have been monitored during the second trimester for the presence of the fragile Xq27. Of the 19 potential carrier mothers, 14 showed the presence of the fragile X in their lymphocytes at a level of 4 per cent or above. As one was a twin pregnancy, fetal blood was obtained at fetoscopy from 20 fetuses and amniotic fluid obtained simultaneously from 19 of them. Of the 20 fetuses, 18 were males (including both of the twins) and two were females. Of these 18 males, seven were found to carry the fragile Xq27 in lymphocytes and subsequently six of the seven were terminated. The diagnosis was confirmed in five of the six terminated fetuses (the sixth case was a patient whose pregnancy was terminated abroad) and also in a full-term male baby. Five of the seven males without the marker X who came to term had their karyotypes confirmed post natally. Of the two female fetuses one was found to be a carrier of the fragile X and the other was not. Both babies had full-term deliveries and both had their karyotypes confirmed post natally. In some cases the diagnosis made in fetal lymphocytes was confirmed later in amniocytes.     

Array-CGH analysis of cell-free fetal DNA in 10 mL of amniotic fluid supernatant

BACKGROUND: Previously, we showed that analysis of amniotic fluid (AF) supernatant cell-free fetal (cff) DNA using DNA microarrays (array-CGH) allows for detection of whole chromosome differences between test and reference DNA. Subsequent technical advances have increased both the yield and quality of extracted cffDNA. Here we determined whether array-CGH using smaller volumes of both fresh and frozen AF cffDNA could identify fetal aneuploidy. METHODS: CffDNA was extracted from 10 mL of residual AF supernatant. The test AF samples (n = 10) included one with a normal karyotype, and nine with the following fetal aneuploidies: trisomies 13 (n = 1), 18 (n = 3), 21 (n = 2), trisomy 9 mosaicism (47,XX,+ 9[18]/46,XX[2]), triploidy (69,XXY) and Turner syndrome (45,X). RESULTS: Array-CGH using AF cffDNA from aneuploid fetuses, compared to euploid reference AF cffDNA, detected whole chromosome aneuploidy in 8 of 9 cases tested, including the case of trisomy 9 mosaicism. The case of triploidy was not detected. CONCLUSIONS: CffDNA extracted from 10 mL AF supernatant can be analyzed using array-CGH to correctly identify human chromosome abnormalities. This technology allows for rapid screening of AF samples for whole chromosomal changes by using routinely discarded supernatant, and may augment standard prenatal karyotyping techniques by providing additional molecular information.     

Monozygotic twins with trisomy 18 of paternal origin: prenatal diagnosis and molecular cytogenetic characterization in a pregnancy with one structurally abnormal living fetus and one intrauterine fetal demise

ObjectiveTo present prenatal diagnosis and molecular cytogenetic characterization of trisomy 18 in a monozygotic twin pregnancy, with one structurally abnormal living fetus and one intrauterine fetal demise.Case ReportA 38-year-old woman was referred for amniocentesis at 16 weeks of gestation because of advanced maternal age. Prenatal ultrasound revealed a monozygotic twin pregnancy, with one structurally abnormal living fetus, and one fetal demise. The body structure details of the dead fetus could not be identified, whereas holoprosencephaly and omphalocele were identified in the living fetus on prenatal ultrasound. Quantitative fluorescent polymerase chain reaction assays using polymorphic DNA markers specific for chromosome 21 and chromosome 18, were applied to the uncultured amniocytes in the amniotic cavity of the living fetus and the cultured amniocytes in the amniotic cavity of the fetus with intrauterine fetal demise. The specimen showed a dosage ratio of 2:1 (paternal:maternal) for chromosome 18-specific markers in both twins. The result was consistent with monozygosity and trisomy 18, and the trisomy 18 was possibly caused by a paternal second meiotic division non-disjunction error or a postzygotic mitotic error. Conventional cytogenetic analysis revealed a karyotype of 47,XY,+18 in both twins. The pregnancy was terminated at 19 weeks of gestation, and a 2 g small-for-date macerated twin A and a 166 g malformed twin B were delivered. Twin A manifested cebocephaly and omphalocele, and twin B manifested premaxillary agenesis and omphalocele.ConclusionThe present case provides evidence that fetal wastage may occur in one of the co-twins in monozygotic twins associated with trisomy 18, and this may in part explain the very rare occurrence of living monozygotic twins with trisomy 18.     

Management of twin pregnancies with fetal trisomies

Objective To examine options of management and outcome of twin pregnancies affected by fetal trisomies.
Design Retrospective study.
Setting Research Centre for Fetal Medicine.
Population Twenty-seven twin pregnancies affected by fetal trisomy.
Methods A computer search was made of our database for twin pregnancies concordant or discordant for trisomies. The data were reviewed for gestation at diagnosis of the chromosomal abnormality, management and pregnancy outcome.
Main outcome measures Pregnancy management and outcome in relation to type and gestation at diagnosis of the trisomies.
Results There were seven cases where both fetuses were trisomies and in these the parents opted for termination of pregnancy; termination was also performed in another pregnancy where one fetus had trisomy 18 and the chromosomally normal co-twin had a major facial cleft. In 19 cases one fetus had either trisomy 21 (   n = 14  ) or trisomy 18 (   n = 5  ) and the other was normal. Selective fetocide was carried out in 13 of 14 pregnancies discordant for trisomy 21 and in one of the five with trisomy 18. In the four cases discordant for trisomy 18 that were managed expectantly, the trisomic baby died in utero or in the neonatal period, whereas the normal co-twin was liveborn at 33 to 40 weeks (median 37). In the 14 cases of selective fetocide, the chromosomally normal co-twin was live born at 24 to 41 weeks of gestation (median 38), and there was a nonsignificant inverse correlation between the gestation at fetocide and gestation at delivery.
Conclusions In twin pregnancies discordant for fetal trisomies the main determinant in deciding whether to perform selective fetocide or adopt expectant management is the degree of lethality of the chromosomal defect.     

Prenatal diagnosis and fetal pathology of partial trisomy 20P-monosomy 4P resulting from paternal translocation

Amniocentesis was performed in view of a paternal balanced chromosomal rearrangement t(4;20)(p16;p12), inv(18)(p11q11). The pregnancy was complicated by severe oligohydramnios. The fetal karyotype was unbalanced: 46XX, der(4), t(4;20)(p16;p12), inv(18) (p11q11)pat., thus resulting in partial trisomy 20p and monosomy 4p. In addition, the amniotic fluid alpha-fetoprotein (AFP) became increasingly elevated with gestational age. The pregnancy was terminated at 25 weeks. The fetus presented with typical facial dysmorphic features, unilateral cleft lip and palate, severe renal hypoplasia, consistent with the 4p-(Wolf-Hirschhorn) syndrome.     

Prenatal diagnoses in a family with pericentric inversion of chromosome no. 5

A hereditary pericentric inversion of chromosome 5(p13 leads to q35) was detected in a family after the birth of a child with Cri-du-Chat-syndrome [46,XY,del(5)(p13)]. Prenatal diagnoses were carried out in three pregnancies in this family. The following results were found in the amniotic fluid cells: first pregnancy 46,XX; second 46,XY, inv(5)(p13 leads to q35) and the third 46,XX,der (5)(pter leads to q35::p13 leads to pter). The first two pregnancies ended with the birth of phenotypically normal children; the third one however was interrupted. Fetal kidney tissue cultures confirmed the result of the amniotic fluid cell culture.     

Prenatal diagnosis and molecular cytogenetic analysis of partial monosomy 10q (10q25.3-->qter) and partial trisomy 18q (18q23-->qter) in a fetus associated with cystic hygroma and ambiguous genitalia

OBJECTIVES: To present the prenatal diagnosis and molecular cytogenetic analysis of a fetus with nuchal cystic hygroma and ambiguous genitalia. CASE AND METHODS: Amniocentesis was performed at 16 weeks' gestation because of the abnormal fetal sonographic finding of a large septated nuchal cystic hygroma. Genetic amniocentesis revealed a terminal deletion in the long arm of chromosome 10. The paternal karyotype was subsequently found to be 46,XY,t(10;18)(q25.3;q23). The maternal karyotype was normal. The pregnancy was terminated. A hydropic fetus was delivered with a septated nuchal cystic hygroma and ambiguous genitalia. Fluorescence in situ hybridization (FISH), microarray-based comparative genomic hybridization (CGH), and polymorphic DNA markers were used to investigate the involved chromosomal segments. RESULTS: FISH study showed absence of the 10q telomeric probe and presence of the 18q telomeric probe in the derivative chromosome 10. Microarray-based CGH analysis showed loss of distal 10q and gain of distal 18q. Polymorphic DNA marker analysis determined the breakpoints. The fetal karyotype was 46,XY,der(10)t(10;18)(q25.3;q23)pat. The chromosome aberration resulted in partial monosomy 10q (10q25.3-->qter) and partial trisomy 18q (18q23-->qter). CONCLUSIONS: The present case provides evidence that partial monosomy 10q (10q25.3-->qter) with partial trisomy 18q (18q23-->qter) can be a genetic cause of fetal cystic hygroma and ambiguous genitalia. Cytogenetic analysis for prenatally detected structural abnormalities may detect unexpected inherited chromosome aberrations.     

Two unusual chromosome aberrations ascertained by sonographic anomalies

We describe two cases of sonographic abnormalities associated with unusual chromosomal aberrations. Case 1 presented with a cystic hygroma at 12 weeks' gestation. Cytogenetic analysis revealed an unbalanced complex chromosome rearrangement implicating chromosomes 6, 13 and 21 (karyotype: 47,XX,t(6;21;14)(q14;q21;q21)mat,+21) and corresponding to a complete trisomy 21. This anomaly resulted from malsegregation of a maternal balanced three-way translocation. For case 2, an alobar holoprosencephaly was identified by ultrasonography at 23 weeks' gestation. Chromosomal analysis showed a recombinant rec (13), dup q chromosome, secondary to unequal crossing-over of a paternal pericentric inversion of chromosome 13, giving rise to partial trisomy 13q (karyotype: 46,XX,rec(13)dup(13q)inv(13)(p11q21)pat). These two cases illustrate the role of ultrasound in leading to detection not only of foetal chromosomal aberrations but also of rare balanced chromosomal rearrangements presented by one of the two parents.     

'Identical' twins with discordant karyotypes

A chromosomal abnormality in one of the fetuses of a monozygotic twin pregnancy is a rare phenomenon. In the prenatal unit of our cytogenetics laboratory we have recently come across two such heterokaryotypic twin pregnancies. In both cases ultrasound abnormalities were detected in one fetus of each twin pair. Chromosomal analysis showed that one twin pregnancy was discordant for trisomy 21 and the other for 45,X. Ultrasonographic examination suggested a monochorionic twin pregnancy in each case and DNA studies confirmed that both sets of twins were monozygotic. Both pregnancies were terminated. Biopsies taken from different sites of the placentas showed chromosomal mosaicism in both cases. There was no clear correlation between the karyotype found close to the site of the umbilical cord insertion in the placenta and the karyotype of the fetus. Sampling of amniotic fluid from both sacs is recommended in diamniotic twin pregnancies if one (or both) of the fetuses has ultrasound abnormalities, even if the twins are apparently monochorionic.     

Prenatal diagnosis of trisomy 3 mosaicism

OBJECTIVES: To present the clinical, cytogenetic, and molecular cytogenetic findings of prenatally diagnosed trisomy 3 mosaicism. CASE AND METHODS: Trisomy 3 mosaicism is rare, and only two cases of prenatally diagnosed trisomy 3 mosaicism have been reported. Amniocentesis, performed for AMA, revealed a karyotype of 47,XX, + 3[8]/46,XX[27]. Periumbilical blood sampling (PUBS) showed 46,XX in 100 cells. Fluorescence in situ hybridization (FISH) analysis using an alpha satellite chromosome 3 probe confirmed the cytogenetic findings. A repeat amniocentesis confirmed mosaicism for trisomy 3 (47,XX, + 3[1]/46,XX[18]). The infant was delivered by elective C-section because of the presence of IUGR and oligohydramnios. The baby had normal physical findings at birth except for symmetric IUGR, apparently resulting from the placental trisomic cell lines. At delivery, chromosome analysis of 50 cells each from blood, placenta, and umbilical cord revealed 46,XX in all cells. FISH analysis of amniotic fluid cells (54 nuclei), peripheral blood (50 nuclei), umbilical cord fibroblasts (57 nuclei), and placental tissue (52 nuclei) demonstrated two signals in 200 nuclei (i.e., 46,XX) and three signals in 13 nuclei (i.e., 47,XX, + 3). At 11 months of age, the baby was progressing normally. CONCLUSION: A diagnosis of trisomy 3 mosaicism is problematic for patients and clinicians. This is only the third case of trisomy 3 mosaicism identified at amniocentesis. Ultrasound, PUBS, and evaluation of placental tissues and postnatal peripheral blood, were useful in providing information regarding the fetal involvement of trisomy 3. Additional cases of prenatally diagnosed mosaicism for rare trisomies are necessary to more accurately assess the significance of these findings.     

Clinical, cytogenetic, and molecular findings of prenatally diagnosed mosaic trisomy 4

OBJECTIVES: To present the clinical, cytogenetic, and molecular findings of prenatally diagnosed mosaic trisomy 4. CASE: An amniocentesis was performed at 21 weeks' gestation because of maternal anxiety. Cytogenetic analysis revealed mosaicism for trisomy 4, 47,XX,+4[4]/46,XX[16]. Level II ultrasound demonstrated tetralogy of Fallot. Repeated amniocentesis at 23 weeks' gestation revealed 47,XX,+4[4]/46,XX[19]. The pregnancy was terminated. Phenotypic findings included tetralogy of Fallot, hypertelorism, micrognathia, abnormal ears, duplicated phalanges of the left thumb, clinodactyly, and overlapping of the toes. The karyotype of the cord blood was 46,XX. Cytogenetic analyses of the multiple tissue samplings showed a karyotype of 47,XX,+4 in 40/40 cells of the amniotic membrane (amnion), and 47,XX,+4/46,XX with various levels of trisomy 4 in the cells of the liver, lungs, placenta, skin, and umbilical cord. The levels of trisomy 4 were 11/40 in the liver, 8/40 in the lungs, 31/40 in the placenta, 9/40 in the skin, and 8/40 in the umbilical cord. METHOD: The parental origin and meiotic origin of trisomy 4 were determined by examining the amniotic membrane using quantitative fluorescent polymerase chain reaction assays with polymorphic markers specific for chromosome 4. The result was consistent with a paternal meiosis I nondisjunction error. The cord blood showed a biparental inheritance. An extra paternal heterozygous allele with partial dosage increase was noted in other fetal and extraembryonic tissues studied. CONCLUSION: A diagnosis of trisomy 4 mosaicism in amniocytes indicates an increased risk for fetal abnormalities. Associated abnormal findings include congenital heart defects and anomalies of the digits and thumb. A confirmatory placental sampling may be helpful, whereas a fetal blood sampling is of a very limited value. A postnatal amnion sampling may provide additional clues to the fetal involvement of trisomy 4.     

双胎妊娠中结构异常胎儿染色体核型异常的临床特征

目的：探讨双胎妊娠中结构异常胎儿的染色体核型异常的临床特征。方法2000年1月-2010年9月,中山大学附属第一医院就诊的双胎妊娠孕妇181例（共362个胎儿）,对其中介入性产前诊断的308个胎儿按不同因素分组如下。(1)按孕妇年龄分组：≥35岁孕妇（105个胎儿）为高龄孕妇组;＜35岁孕妇（203个胎儿）为适龄孕妇组。(2)按受孕方式分组：辅助生育孕妇（81个胎儿）为辅助生育组,自然受孕（227个胎儿）为自然受孕组。(3)按绒毛膜性质分组：单绒毛膜双胎（MCT,123个胎儿）为MCT组,双绒毛膜双胎（DCT,185个胎儿）为DCT组。(4)按结构异常分组：205个结构异常胎儿为异常胎儿组,103个正常胎儿为正常胎儿组。对362个胎儿进行超声检查并对其中的308个双胎胎儿行染色体核型分析。结果(1)胎儿染色体核型分析结果：181例双胎孕妇中检出胎儿核型异常23例(12.7％,23/181),核型异常的23例双胎孕妇中,20例检查了两个胎儿的核型。308个胎儿中检出异常核型的胎儿26个(8.4％,26/308),以非整倍体最多见,占异常核型的53.8％ (14/26)。205个异常胎儿中21个有染色体核型异常(10.2％,21/205);103个正常胎儿中5个有染色体异常(4.9％,5/103),两者比较,差异无统计学意义(P＞0.05)。(2)MCT组和DCT组胎儿染色体核型异常发生率比较：MCT组123个胎儿中7个有染色体异常,发生率为5.7％ (7/123);DCT组185个胎儿中19个有染色体异常,发生率为10.3％( 19/185),两组胎儿的染色体异常发生率比较,差异无统计学意义(P＞0.05)。在染色体异常类别中,DCT组有14个胎儿为非整倍体异常,非整倍体率为7.6％(14/185),而MCT组无一例发生,两组比较,差异有统计学意义(P＜0.05)。DCT组中,两例双胎中因l胎死亡仅检查有结构异常的另一个活胎,分别为21三体和18三体;其余17例均分别检查了两个胎儿,两个胎儿的染色体核型不相同。DCT组19个核型异常的胎儿中,15个胎儿超声检查提示为结构异常(15/19)。MCT组中,4例双胎中有7个胎儿检出染色体异常。(3)高龄孕妇组和适龄孕妇组胎儿染色体异常发生率比较：高龄孕妇组胎儿的染色体异常发生率为7.6％(8/105),适龄孕妇组为8.9％( 18/203),两组比较,差异无统计学意义(P＞0.05);在染色体异常类别中,高龄孕妇组6个胎儿为非整倍体异常(5.7％,6/105),适龄孕妇组仅8个胎儿(3.9％,8/203),高龄孕妇组胎儿的非整倍体率显著高于适龄孕妇组,差异有统计学意义(P＜0.05)。(4)辅助生育组和自然受孕组胎儿染色体异常发生率比较：辅助生育组81个胎儿中有l1个染色体异常(13.6％,11/81),自然受孕组227个胎儿中有15个染色体异常(6.6％,15/227),差异有统计学意义(P＜0.05)。在染色体异常类别中,辅助生育组7个胎儿为非整倍体异常(8.6％,7/81),自然受孕组也为7个胎儿(3.1％,7/227),差异无统计学意义(P＞0.05)。(5)异常胎儿组和正常胎儿组染色体异常发生率比较：异常胎儿组205个胎儿中有21个染色体异常(l0.2％,21/205),正常胎儿组103个胎儿中有5个染色体异常(4.9％,5/103),两组比较,差异无统计学意义(P＞0.05);在染色体异常类别中,异常胎儿组13个胎儿为非整倍体异常(6.3％,13/205),正常胎儿组仅1个胎儿(1.0％,1/103),两组比较,差异有统计学意义(P＜0.05)。结论非整倍体是双胎合并胎儿结构异常时最常出现的染色体异常,以21三体最为常见。双胎之间的核型不一致和双胎之一出现非整倍体的情况常见于DCT,而MCT时两个胎儿核型往往一致,但两个胎儿发生相同的染色体异常可能出现不同的表型;双胎之一合并胎儿结构异常时,建议分别对两个胎儿同时行染色体核型分析。     

Elevated second-trimester maternal serum inhibin A levels in Asian pregnancies with fetal down syndrome and other chromosomal abnormalities

SUBJECTS: To evaluate second-trimester maternal serum inhibin A levels in Asian pregnancies with fetal Down syndrome and other chromosomal abnormalities. METHODS: Inhibin A level was measured from the serum samples of 25 chromosomally abnormal pregnancies, including 15 cases of Down syndrome, 4 cases of trisomy 18, 1 case of trisomy 13, and 5 cases of sex chromosome aneuploidies (4 cases of 47,XXY and 1 case of 45,X) and in a cohort of 150 controls during the second trimester of pregnancy. RESULTS: The multiple of median levels of Down syndrome (1.74) and other chromosomally abnormal pregnancies (2.03) are significantly higher than that of normal pregnancies (p = 0.002 and p = 0.024, respectively). Only 3 of 15 (20%) Down syndrome cases had inhibin A levels at or above the 95th centile of the control values. CONCLUSIONS: Inhibin A levels are raised in Asian women affected with fetal Down syndrome and sex chromosome abnormality. In spite of the poor discrepancy of inhibin A, it might be a potential marker for Down syndrome screening in Asians.