T. Stojilkovic-Mikic scite author profile

Both the techniques appear to offer an accurate means of assessing fetal gender, giving parents the option of avoiding invasive testing in the 50% of cases where the fetus would not be affected. The molecular technique is performed at an earlier gestation, but female fetal status is predicted by a negative test result. Ultrasound cannot be applied until 11 weeks' gestation but diagnostic signs are sought in both sexes. Combining these approaches offers a highly sensitive method of non-invasive determination of gender in high-risk pregnancies. Health professionals, clinical geneticists and genetics associates, in particular, who refer women at high risk should be aware of these non-invasive options for prenatal sex determination.

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Maternal cell contamination of prenatal samples assessed by QF-PCR genotyping

Stojilkovic-Mikic

Mann

Docherty

et al. 2005

Prenat. Diagn.

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For heavily bloodstained amniotic fluid samples, a maternal blood specimen may help interpret the results of rapid trisomy testing, followed by confirmation of the fetal origin of cultured cells. QF-PCR analysis has established a higher incidence of maternal cell contamination of cultured amniocytes than previous reports; the presence of MCC (maternal cell contamination) in cultured cells from samples with no bloodstaining underlines the need for karyotype analysis of more than one XX culture.

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Abnormal folate metabolism in foetuses affected by neural tube defects

Dunlevy

Chitty

Burren

et al. 2006

Brain

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Folic acid supplementation can prevent many cases of neural tube defects (NTDs), whereas suboptimal maternal folate status is a risk factor, suggesting that folate metabolism is a key determinant of susceptibility to NTDs. Despite extensive genetic analysis of folate cycle enzymes, and quantification of metabolites in maternal blood, neither the protective mechanism nor the relationship between maternal folate status and susceptibility are understood in most cases. In order to investigate potential abnormalities in folate metabolism in the embryo itself, we derived primary fibroblastic cell lines from foetuses affected by NTDs and subjected them to the dU suppression test, a sensitive metabolic test of folate metabolism. Significantly, a subset of NTD cases exhibited low scores in this test, indicative of abnormalities in folate cycling that may be causally linked to the defect. Susceptibility to NTDs may be increased by suppression of the methylation cycle, which is interlinked with the folate cycle. However, reduced efficacy in the dU suppression test was not associated with altered abundance of the methylation cycle intermediates, s-adenosylmethionine and s-adenosylhomocysteine, suggesting that a methylation cycle defect is unlikely to be responsible for the observed abnormality of folate metabolism. Genotyping of samples for known polymorphisms in genes encoding folate-associated enzymes did not reveal any correlation between specific genotypes and the observed abnormalities in folate metabolism. These data suggest that as yet unrecognized genetic variants result in embryonic abnormalities of folate cycling that may be causally related to NTDs.

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