Noninvasive Prenatal Diagnosis of Fetal Trisomy 18 and Trisomy 13 by Maternal Plasma DNA Sequencing

Chen, Eric Z.; Chiu, Rossa W.̉K.; Sun, Hao; Akolekar, Ranjit; Chan, K. C. Allen; Leung, Tak Yeung; Jiang, Peiyong; Zheng, Yama W. L.; Lun, Fiona M.F.; Chan, Lisa; Jin, Yuanliang; Go, Attie T.J.I.; Lau, Esther Yuet Ying; To, William W. K.; Leung, Wing Cheong; Tang, Rebecca; Au-Yeung, Sidney K. C.; Lam, Helena; Kung, Y. Y.; Zhang, Xiuqing; Vugt, J.M.G. van; Minekawa, Ryoko; Tang, Mary Hoi Yin; Wang, Jun; Oudejans, Cees B.M.; Lau, Tze Kin; Nicolaides, Kypros H.; Lo, Y.M. Dennis

doi:10.1371/journal.pone.0021791

Cited by 256 publications

(278 citation statements)

References 30 publications

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“…9,10,15, 16 Palomaki et al 16 and Chiu et al 10 reported false-positive rates of 1.4% and 2.1%, respectively, which were improved in a subsequent study. 9 False-positive SNP calls could be derived from erroneous alignments of short reads. 30 Therefore, different bioinformatics parameters, as well as improvements, in statistical analysis have been investigated by these teams in order to eliminate the erroneous calls and decrease the observed false-positive rate.…”

Section: Discussionmentioning

confidence: 99%

“…7,8 As the advent of next generation sequencing (NGS), a lot of effort has been concentrated on exploiting this technology for the measurement of aneuploidies in maternal plasma. [9][10][11][12][13][14] Using this technology, non-invasive prenatal diagnostic (NIPD) for trisomy 21, 18 and 13 has recently reached the clinical setting by analysing the relative amount of chromosomes in circulating cell-free DNA from maternal plasma. 15,16 However, approaches permitting reliable detection of single-gene mutations or single-nucleotide polymorphisms (SNPs) using cell-free fetal DNA in maternal plasma are still under development.…”

Section: Introductionmentioning

confidence: 99%

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Next generation sequencing of SNPs for non-invasive prenatal diagnosis: challenges and feasibility as illustrated by an application to β-thalassaemia

et al. 2013

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b-Thalassaemia is one of the most common autosomal recessive single-gene disorder worldwide, with a carrier frequency of 12% in Cyprus. Prenatal tests for at risk pregnancies use invasive methods and development of a non-invasive prenatal diagnostic (NIPD) method is of paramount importance to prevent unnecessary risks inherent to invasive methods. Here, we describe such a method by assessing a modified version of next generation sequencing (NGS) using the Illumina platform, called 'targeted sequencing', based on the detection of paternally inherited fetal alleles in maternal plasma. We selected four single-nucleotide polymorphisms (SNPs) located in the b-globin locus with a high degree of heterozygosity in the Cypriot population. Spiked genomic samples were used to determine the specificity of the platform. We could detect the minor alleles in the expected ratio, showing the specificity of the platform. We then developed a multiplexed format for the selected SNPs and analysed ten maternal plasma samples from pregnancies at risk. The presence or absence of the paternal mutant allele was correctly determined in 27 out of 34 samples analysed. With haplotype analysis, NIPD was possible on eight out of ten families. This is the first study carried out for the NIPD of b-thalassaemia using targeted NGS and haplotype analysis. Preliminary results show that NGS is effective in detecting paternally inherited alleles in the maternal plasma.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Next generation sequencing of SNPs for non-invasive prenatal diagnosis: challenges and feasibility as illustrated by an application to β-thalassaemia

et al. 2013

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“…This is particularly important at early gestational ages, because the fetal fractions rise with increasing gestational age, and in women with high BMI, as fetal fractions are inversely proportional to weight [7,24,25]. To distinguish these minor differences with high confidence a large number of reads is required; because MPSS sequences all chromosomes, approximately 6.3 million uniquely-mapped reads from the entire genome are required to ensure sufficient, e.g., chromosome 21 counts for accurate copy number calls [27,[38][39][40]. Additionally, as only approximately 25% of MPSS-generated reads are uniquely mapped, approximately 25 million raw sequencing reads are required per sample to generate sufficient data for accurate analysis [9].…”

Section: Ngs Nipt Approaches Quantitative Massively Parallel Shotgun mentioning

confidence: 99%

Non-invasive prenatal testing (NIPT): limitations on the way to become diagnosis

Kotsopoulou¹,

Tsoplou²,

Mavrommatis

et al. 2015

Diagnosis

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With the discovery of existing circulating cellfree fetal DNA (ccffDNA) in maternal plasma and the advent of next-generation sequencing (NGS) technology, there is substantial hope that prenatal diagnosis will become a predominately non-invasive process in the future. At the moment, non-invasive prenatal testing (NIPT) is available for high-risk pregnancies with significant better sensitivity and specificity than the other existing non-invasive methods (biochemical and ultrasonographical). Mainly it is performed by NGS methods in a few commercial labs worldwide. However, it is expected that many other labs will offer analogous services in the future in this fastgrowing field with a multiplicity of in-house methods (e.g., epigenetic, etc.). Due to various limitations of the available methods and technologies that are explained in detail in this manuscript, NIPT has not become diagnostic yet and women may still need to undergo risky invasive procedures to verify a positive finding or to secure (or even expand) a negative one. Efforts have already started to make the NIPT technologies more accurate (even at the level of a complete fetal genome) and cheaper and thus more affordable, in order to become diagnostic screening tests for all pregnancies in the near future.

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“…We refer to this predetermined set of chromosomes as the " reference chromosomes " , and they are used in the denominator for the ratio calculations. This approach mitigates the need to perform additional corrections on the data [e.g., correction for guanine-cytosine (GC) content used by others] (Figure 1 ) [20,21] . The optimal set of reference chromosomes for each chromosome of interest is determined from results of data on a training set that includes only euploid samples (diploid karyotype).…”

Section: Optimized Chromosome Quantificationmentioning

confidence: 99%

Non-invasive prenatal testing for fetal aneuploidy by massively parallel DNA sequencing of maternal plasma: the future has arrived today/Nicht-invasiver Pränatal-Test auf fetale Aneuploidie mittels massiv-paralleler DNA-Sequenzanalyse im mütterlichen Plasma: in der Zukunft angekommen

Swanson

Coffeen

Sehnert

2012

LaboratoriumsMedizin

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: After decades of research, non-invasive prenatal testing (NIPT) using maternal blood to determine fetal chromosome status has found its way from the research laboratory into clinical practice, triggering a long-awaited paradigm shift in prenatal care. A variety of methods using sequencing of maternal cell-free DNA (cfDNA) have now been studied, primarily demonstrating their ability to detect the most common fetal aneuploidy, trisomy 21 (T21). The focus of this article is on massively parallel sequencing (MPS) with optimized sequence tag mapping and chromosome quantification, which accurately detects T21 as well as multiple other aneuploidies across the genome. The power of this technique resides in its high precision and reduction of variation within and between sequencing runs. Using MPS, classification of aneuploidy status for a given sample can be reliably assigned from the genetic information alone without the need to factor in other maternal pre-test risk or other clinical variables. Performance of this method has been prospectively demonstrated in a rigorous, blinded, multi-center study in the United States. The findings suggest that MPS can be incorporated into existing prenatal screening algorithms to reduce unnecessary invasive procedures. This technology and key considerations for clinical implementation are discussed.Keywords: cell-free DNA (cfDNA); fetal aneuploidy; massively parallel sequencing (MPS); maternal plasma; noninvasive prenatal testing (NIPT) .Zusammenfassung : Nach jahrzehntelanger Forschung hat der Nicht-invasive Pr ä natal-Test (NIPT) des fetalen Chromosomenstatus im m ü tterlichen Plasma seinen Weg aus den Forschungslaboren in die klinische Praxis gefunden und l ö st einen lange herbeigesehnten Paradigmenwechsel in der pr ä natalen Diagnostik aus. Es wurde bereits eine Vielzahl von Methoden, welche die Sequenzanalyse von m ü tterlicher zell-freier DNA (cfDNA) verwenden, untersucht. Dabei zeigte sich, dass dieser Ansatz f ü r den Nachweis der h ä ufigsten fetalen Aneuploidie, der Trisomie 21 (T21) genutzt werden kann. Der Fokus dieses Artikels liegt auf der massiv-parallelen Sequenzanalyse (MPS) mit optimiertem "Sequence Tag Mapping " und Chromosomenquantifizierung, wodurch T21 und zahlreiche andere Aneuploidie im Genom exakt nachgewiesen werden k ö nnen. Der Vorteil dieser Methode liegt in ihrer hohen Pr ä zision und der Reduzierung der Variation innerhalb eines sowie zwischen mehreren Sequenzierungsl ä ufen. Durch die Verwendung von MPS kann der Aneuploidie-Status einer Probe zuverl ä ssig allein aus der genetischen Information ohne die Fakturierung in anderen m ü tterlichen Pr ä test-Risiko oder anderen klinischen Variablen ermittelt werden. Die Eignung dieser Methode konnte prospektiv in einer streng verblindeten, multizentrischen Studie in den USA demonstriert werden. Die Ergebnisse deuten darauf hin, dass MPS in existierende pr ä natale Screening-Algorithmen integriert werden kann und somit unn ö tige invasive Eingriffe reduziert werden k ö nnen. Die Technologie und ih...

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Noninvasive Prenatal Diagnosis of Fetal Trisomy 18 and Trisomy 13 by Maternal Plasma DNA Sequencing

Cited by 256 publications

References 30 publications

Next generation sequencing of SNPs for non-invasive prenatal diagnosis: challenges and feasibility as illustrated by an application to β-thalassaemia

Next generation sequencing of SNPs for non-invasive prenatal diagnosis: challenges and feasibility as illustrated by an application to β-thalassaemia

Non-invasive prenatal testing (NIPT): limitations on the way to become diagnosis

Non-invasive prenatal testing for fetal aneuploidy by massively parallel DNA sequencing of maternal plasma: the future has arrived today/Nicht-invasiver Pränatal-Test auf fetale Aneuploidie mittels massiv-paralleler DNA-Sequenzanalyse im mütterlichen Plasma: in der Zukunft angekommen

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