Background Thalassemias are inherited blood disorders and by far one of the most common monogenic diseases globally. Beta-thalassemia has a particularly high prevalence in Cyprus, with the IVSI-110 G>A (HBB:c.93-21G>A) pathogenic variation representing almost 79% of the total carriers. The discovery that 3% to 20% of cell-free fetal DNA (cffDNA) is present in the maternal plasma allowed the development of non-invasive prenatal diagnosis (NIPD) of monogenic diseases, like beta-thalassemia, avoiding the risks of invasive procedures. However, the development of NIPD holds major technical challenges and has not yet reached the clinical setting. Methods In this study, we apply droplet digital PCR (ddPCR) coupled with the relative variant dosage approach to develop a NIPD assay for IVSI-110 G>A beta-thalassemia. We have implemented an optimization process for ddPCR to address the challenges of ddPCR assays such as inconclusive rain droplets and thus increase the sensitivity and specificity of the assay. The established protocol was evaluated on 40 maternal plasma samples with a median gestational age of 10 weeks where both parents carried the same pathogenic variation. Results Thirty-three samples were correctly classified, 6 remained inconclusive, and 1 was misclassified. Our assay exhibited 97.06% accuracy (95% CI, 82.46–99.68), 100% sensitivity (95% CI, 76.84–100), and 95% specificity (95% CI, 75.13–99.87), demonstrating its efficiency for the non-invasive detection of both maternal and paternal alleles. Conclusions We have developed an efficient, simple, and cost-effective ddPCR assay for the non-invasive determination of fetal genotype in couples at risk of IVSI-110 G>A beta-thalassemia, bringing NIPD of monogenic diseases closer to the diagnostic setting.
BackgroundAfter the discovery that cell-free fetal DNA (cffDNA) is circulating in the maternal plasma of pregnant women, non-invasive prenatal diagnosis for fetal RhD in maternal plasma in RhD negative women at risk for haemolytic disease of the newborn (HDN) was clinically established and used by many laboratories. The objectives of this study are: (a) to assess the feasibility and report our experiences of the routine implementation of fetal RHD genotyping by analysis of cffDNA extracted from maternal plasma of RhD negative women at risk of HDN, and (b) to estimate the RhD phenotype frequencies, the RHD genotype frequencies and the RhD zygosity in the Cypriot population.MethodscffDNA was extracted from maternal plasma of 73 RhD negative pregnant women. Real-Time Multiplex-PCR was used to amplify regions of RHD gene in exons 4, 5 and 10. RhD phenotypes were determined on 445 random samples using conventional agglutination slide test.ResultsThe fetus was predicted to be positive in 53 cases and negative in 18 cases. Two of cases were identified as D-variants, weak D type-1 and 11. The frequency of RhD negative homozygosity in the Cypriot population was estimated to be 7.2 %, while the frequencies of RHD hemizygosity and RhD positive homozygosity was calculated to be 39.2 and 53.6 %, respectively.ConclusionFetal RHD genotyping can be accurately determined using cffDNA from maternal plasma. The implementation of the test has eliminated all use of unnecessary anti-D and reduced the total use of anti-D by 25.3 % while achieving appropriate management of the RhD negative pregnancies.
ObjectiveTo develop a sensitive, specific, simple, cost-effective and reproducible platform for the non-invasive prenatal detection of paternally inherited alleles for β-thalassaemia. The development of such an assay is of major significance in order to replace currently-applied invasive methods containing inherent fetal loss risks.MethodsWe present a fast Temperature-Gradient Co-amplification at Lower Denaturation Temperature Polymerase Chain Reaction (fast TG COLD PCR) methodology for the detection of the paternally-inherited fetal alleles in maternal plasma. Two single-nucleotide polymorphisms (SNPs), rs7480526 (G/T) and rs968857 (G/A) that are located on the β-globin gene cluster and exhibit a high degree of heterozygosity in the Cypriot population were selected for evaluation. Seventeen maternal plasma samples from pregnancies at risk for β-thalassemia were analysed for the selected SNPs using the novel fast TG COLD PCR assay.ResultsUsing fast TG COLD PCR, the paternally inherited allele in cell free fetal DNA was correctly determined for all the 17 maternal plasma samples tested, showing full agreement with the Chorionic Villus Sampling (CVS) analysis.ConclusionsOur findings are encouraging and demonstrate the efficiency and sensitivity of fast TG COLD PCR in detecting the minor paternally-inherited fetal alleles in maternal plasma for the development of a NIPD assay for β-thalassaemia.
The assignment of alleles to haplotypes in prenatal diagnostic assays has traditionally depended on family study analyses. However, this prevents the wide application of prenatal diagnosis based on haplotype analysis, especially in countries with dispersed populations. Here, we present an easy and fast approach using Droplet Digital PCR for the direct determination of haplotype blocks, overcoming the necessity for acquiring other family members’ genetic samples. We demonstrate this approach on nine families that were referred to our center for a prenatal diagnosis of β-thalassaemia using four highly polymorphic single nucleotide variations and the most common pathogenic β-thalassaemia variation in our population. Our approach resulted in the successful direct chromosomal phasing and haplotyping for all nine of the families analyzed, demonstrating a complete agreement with the haplotypes that are ascertained based on family trios. The clinical utility of this approach is envisaged to open the application of prenatal diagnosis for β-thalassaemia to all cases, while simultaneously providing a model for extending the prenatal diagnostic application of other monogenic diseases as well.
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