Clinician-reported chorionicity and zygosity assignment using single-nucleotide polymorphism-based cell-free DNA: Lessons learned from 55,344 twin pregnancies.

OBJECTIVE: Prenatal chorionicity assessment relies on ultrasound, which can be confounded by many factors. Noninvasive assessment of zygosity is possible using single nucleotide polymorphism (SNP)-based cell-free DNA testing. Our objective was to determine the relationship between provider-reported chorionicity and SNP-cfDNA assignment of twin zygosity. METHODS: All twin pregnancy blood samples received by a reference laboratory between September 27, 2017 and September 8, 2021 were included. Chorionicity assignment was requested on the requisition, recorded as; monochorionic (MC), dichorionic, or "don't know". SNP-cfDNA zygosity results, monozygotic (MZ) or dizygotic (DZ), were correlated with chorionicity assignment. RESULTS: 59,471 twin samples (median gestational age = 12.0 weeks at draw) were received and analyzed; 55,344 (93.1%) received zygosity assignment. SNP-cfDNA reported 16,673 (30.1%) MZ and 38,671 (69.9%) as DZ. Provider-reported chorionicity was compared to the zygosity assignment for each case. Of 6283 provider-reported MC twins, 318 (5.1%) were reported as DZ using SNP-cfDNA. CONCLUSION(S): One in 20 suspected MC twin pregnancies were reported as DZ using SNP-cfDNA. Approximately 30% of 55,344 twin pregnancies were found to be MZ, including cases where chorionicity was unknown. SNP-cfDNA zygosity assessment is a useful adjunct assessment for twin pregnancies, particularly those reported as MC or without determined chorionicity.

Detection of maternal X chromosome abnormalities using single nucleotide polymorphism-based noninvasive prenatal testing.

BACKGROUND: Maternal X chromosome abnormalities may cause discordant results between noninvasive prenatal screening tests and diagnostic evaluation of the fetus/newborn, leading to unnecessary invasive testing. Women with X chromosome abnormalities are at increased risk for reproductive, pregnancy, or other health complications, which may be reduced or ameliorated by early diagnosis, monitoring, and intervention. OBJECTIVE: This study aimed to validate a single nucleotide polymorphism-based noninvasive prenatal test to identify X chromosome abnormalities of maternal origin. STUDY DESIGN: All tests unable to evaluate fetal risk for aneuploidy because of uninformative algorithm results were eligible for inclusion. Two groups of cases were prospectively identified: Group A (n=106) where a maternal X chromosome abnormality was suspected and Group B (control group, n=107) where a fetal chromosome abnormality involving chromosome 13, 18, 21, or X was suspected but did not meet criteria for reporting. Maternal DNA was isolated from the plasma-depleted cellular pellet and sent to a reference laboratory for blinded analysis using chromosomal microarray. A chromosome abnormality involving chromosomes 13, 18, 21, or X was reported by the reference laboratory if ≥5 Mb in size and present in ≥20% of the DNA. RESULTS: A maternal X chromosome abnormality was suspected in 1/1305 tests (149/194,385; 0.08%). In Group A, a maternal X chromosome abnormality was confirmed in 100/106 cases (94.3% positive predictive value, 1-sided 97.5% confidence interval, 88.1%-100.0%). Turner syndrome was the most commonly suspected maternal abnormality (58/106, 54.7%), with confirmation of mosaic or nonmosaic 45,X by microarray in 38/58 (65.5%) cases. Noninvasive prenatal screening tests suspected the presence of maternal 47,XXX with or without mosaicism in 40/106 (37.7%) cases, confirmed by microarray in 38/40 (95.0%). In Group B (n=107), no maternal microarray abnormalities were reported, providing a negative predictive value of 100% (1-sided 97.5% confidence interval, 96.6%-100.0%). CONCLUSION: When noninvasive prenatal testing suspected a maternal X chromosome abnormality, maternal microarray confirmed an X chromosome abnormality with 94.3% positive predictive value. Of the maternal X chromosome abnormalities detected by array, >50% were 45,X. When fetal chromosome abnormalities involving chromosomes 13, 18, 21, or X were suspected, no maternal chromosome abnormalities were reported, yielding a negative predictive value of 100%. Women with maternal X abnormalities suspected with noninvasive prenatal testing may be at increased risk for reproductive and health complications; early evaluation and treatment may prevent long-term consequences or disability.

Fetal Sex Results of Noninvasive Prenatal Testing and Differences With Ultrasonography.

OBJECTIVE: To assess the causes of reported discordance between noninvasive prenatal testing (NIPT) and ultrasound or other clinical information. METHODS: In this retrospective, observational study, all cases in which single-nucleotide polymorphism (SNP)-based NIPT reported normal sex chromosomes and the laboratory was notified by the patient or health care provider of discordance between NIPT and observed or expected fetal sex from clinical information were reviewed. When discordances were unresolved after internal and external laboratory clerical data review or repeat ultrasound imaging, additional clinical records, genetic testing results and pregnancy outcomes were reviewed. RESULTS: Of the 1,301,117 eligible NIPT cases, fetal sex discordances were reported in 91 (0.007%; 1:14,300; 95% CI 1:11,600-1:17,800); partial or complete outcome information was available for 83 of 91 cases. In 30 of 83 (36%) cases, karyotyping was performed, and sufficient clinical information was provided to establish the diagnosis of disorders of sexual development. The disorders of sexual development were classified into three categories: 46,XY disorders of sexual development (n=19), 46,XX disorders of sexual development (n=4), and sex chromosome disorders of sexual development (n=7). In 28 of 83 (34%) cases, the cause of the apparent discrepancy was attributable to human error, predominantly phlebotomy labeling or ultrasound misassignment. In 25 of 83 cases, a diagnosis was not possible; the outcome reported was either abnormal (18/83, 22%) or no abnormalities were reported (7/83, 8%). When normal sex chromosomes were predicted by SNP-based NIPT and clinical information was discordant, disorders of sexual development were common. Internal laboratory clerical data review and re-imaging confirmed the NIPT fetal sex reports in 34% cases, providing reassurance that no further evaluation was necessary. CONCLUSION: Identification of apparent fetal sex discordances with NIPT results, and reporting this suspicion to the laboratory, provides an opportunity for further evaluation to identify the cause of apparent discordances and the involvement of a multi-disciplinary team, as necessary to prepare for postnatal care. We propose a protocol for evaluation of these cases. FUNDING SOURCE: This study was funded by Natera, Inc.

Validation of a Single-Nucleotide Polymorphism-Based Non-Invasive Prenatal Test in Twin Gestations: Determination of Zygosity, Individual Fetal Sex, and Fetal Aneuploidy.

We analyzed maternal plasma cell-free DNA samples from twin pregnancies in a prospective blinded study to validate a single-nucleotide polymorphism (SNP)-based non-invasive prenatal test (NIPT) for zygosity, fetal sex, and aneuploidy. Zygosity was evaluated by looking for either one or two fetal genome complements, fetal sex was evaluated by evaluating Y-chromosome loci, and aneuploidy was assessed through SNP ratios. Zygosity was correctly predicted in 100% of cases (93/93; 95% confidence interval (CI) 96.1%-100%). Individual fetal sex for both twins was also called with 100% accuracy (102/102; 95% weighted CI 95.2%-100%). All cases with copy number truth were also correctly identified. The dizygotic aneuploidy sensitivity was 100% (10/10; 95% CI 69.2%-100%), and overall specificity was 100% (96/96; 95% weighted CI, 94.8%-100%). The mean fetal fraction (FF) of monozygotic twins (n = 43) was 13.0% (standard deviation (SD), 4.5%); for dizygotic twins (n = 79), the mean lower FF was 6.5% (SD, 3.1%) and the mean higher FF was 8.1% (SD, 3.5%). We conclude SNP-based NIPT for zygosity is of value when chorionicity is uncertain or anomalies are identified. Zygosity, fetal sex, and aneuploidy are complementary evaluations that can be carried out on the same specimen as early as 9 weeks' gestation.

Incidence of the 22q11.2 deletion in a large cohort of miscarriage samples.

BACKGROUND: The 22q11.2 deletion syndrome is the most common microdeletion syndrome in livebirths, but data regarding its incidence in other populations is limited and also include ascertainment bias. This study was designed to determine the incidence of the 22q11.2 deletion in miscarriage samples sent for clinical molecular cytogenetic testing. RESULTS: Twenty-six thousand one hundred one fresh product of conception (POC) samples were sent to a CLIA- certified, CAP-accredited laboratory from April 2010--May 2016 for molecular cytogenetic miscarriage testing using a single-nucleotide polymorphism (SNP)-based microarray platform. A retrospective review determined the incidence of the 22q11.2 deletion in this sample set. Fetal results were obtained in 22,451 (86%) cases, of which, 15 (0.07%) had a microdeletion in the 22q11.2 region (incidence, 1/1497). Of those, 12 (80%) cases were found in samples that were normal at the resolution of traditional karyotyping (i.e., had no chromosome abnormalities above 10 Mb in size) and three (20%) cases had additional findings (Trisomy 15, Trisomy 16, XXY). Ten (67%) cases with a 22q11.2 deletion had the common ~3 Mb deletion; the remaining 5 cases had deletions ranging in size from 0.65 to 1.5 Mb. A majority (12/15) of cases had a deletion on the maternally inherited chromosome. No significant relationship between maternal age and presence of a fetal 22q11.2 deletion was observed. CONCLUSIONS: The observed incidence of 1/1497 for the 22q11.2 deletion in miscarriage samples is higher than the reported general population prevalence (1/4000-1/6000). Further research is needed to determine whether the 22q11.2 deletion is a causal factor for miscarriage.

A lab-on-chip for malaria diagnosis and surveillance.

BACKGROUND: Access to timely and accurate diagnostic tests has a significant impact in the management of diseases of global concern such as malaria. While molecular diagnostics satisfy this need effectively in developed countries, barriers in technology, reagent storage, cost and expertise have hampered the introduction of these methods in developing countries. In this study a simple, lab-on-chip PCR diagnostic was created for malaria that overcomes these challenges. METHODS: The platform consists of a disposable plastic chip and a low-cost, portable, real-time PCR machine. The chip contains a desiccated hydrogel with reagents needed for Plasmodium specific PCR. Chips can be stored at room temperature and used on demand by rehydrating the gel with unprocessed blood, avoiding the need for sample preparation. These chips were run on a custom-built instrument containing a Peltier element for thermal cycling and a laser/camera setup for amplicon detection. RESULTS: This diagnostic was capable of detecting all Plasmodium species with a limit of detection for Plasmodium falciparum of 2 parasites/µL of blood. This exceeds the sensitivity of microscopy, the current standard for diagnosis in the field, by ten to fifty-fold. In a blind panel of 188 patient samples from a hyper-endemic region of malaria transmission in Uganda, the diagnostic had high sensitivity (97.4%) and specificity (93.8%) versus conventional real-time PCR. The test also distinguished the two most prevalent malaria species in mixed infections, P. falciparum and Plasmodium vivax. A second blind panel of 38 patient samples was tested on a streamlined instrument with LED-based excitation, achieving a sensitivity of 96.7% and a specificity of 100%. CONCLUSIONS: These results describe the development of a lab-on-chip PCR diagnostic from initial concept to ready-for-manufacture design. This platform will be useful in front-line malaria diagnosis, elimination programmes, and clinical trials. Furthermore, test chips can be adapted to detect other pathogens for a differential diagnosis in the field. The flexibility, reliability, and robustness of this technology hold much promise for its use as a novel molecular diagnostic platform in developing countries.

Retrotransposon insertion in the T-cell acute lymphocytic leukemia 1 (Tal1) gene is associated with severe renal disease and patchy alopecia in Hairpatches (Hpt) mice.

"Hairpatches" (Hpt) is a naturally occurring, autosomal semi-dominant mouse mutation. Hpt/Hpt homozygotes die in utero, while Hpt/+ heterozygotes exhibit progressive renal failure accompanied by patchy alopecia. This mutation is a model for the rare human disorder "glomerulonephritis with sparse hair and telangiectases" (OMIM 137940). Fine mapping localized the Hpt locus to a 6.7 Mb region of Chromosome 4 containing 62 known genes. Quantitative real time PCR revealed differential expression for only one gene in the interval, T-cell acute lymphocytic leukemia 1 (Tal1), which was highly upregulated in the kidney and skin of Hpt/+ mice. Southern blot analysis of Hpt mutant DNA indicated a new EcoRI site in the Tal1 gene. High throughput sequencing identified an endogenous retroviral class II intracisternal A particle insertion in Tal1 intron 4. Our data suggests that the IAP insertion in Tal1 underlies the histopathological changes in the kidney by three weeks of age, and that glomerulosclerosis is a consequence of an initial developmental defect, progressing in severity over time. The Hairpatches mouse model allows an investigation into the effects of Tal1, a transcription factor characterized by complex regulation patterns, and its effects on renal disease.

Real-time PCR detection of Plasmodium directly from whole blood and filter paper samples.

BACKGROUND: Real-time PCR is a sensitive and specific method for the analysis of Plasmodium DNA. However, prior purification of genomic DNA from blood is necessary since PCR inhibitors and quenching of fluorophores from blood prevent efficient amplification and detection of PCR products. METHODS: Reagents designed to specifically overcome PCR inhibition and quenching of fluorescence were evaluated for real-time PCR amplification of Plasmodium DNA directly from blood. Whole blood from clinical samples and dried blood spots collected in the field in Colombia were tested. RESULTS: Amplification and fluorescence detection by real-time PCR were optimal with 40× SYBR® Green dye and 5% blood volume in the PCR reaction. Plasmodium DNA was detected directly from both whole blood and dried blood spots from clinical samples. The sensitivity and specificity ranged from 93-100% compared with PCR performed on purified Plasmodium DNA. CONCLUSIONS: The methodology described facilitates high-throughput testing of blood samples collected in the field by fluorescence-based real-time PCR. This method can be applied to a broad range of clinical studies with the advantages of immediate sample testing, lower experimental costs and time-savings.

Intracranial hemorrhage progressing to porencephaly as a result of congenitally acquired cytomegalovirus infection--an illustrative report.

OBJECTIVE: To report ultrasound and magnetic resonance imaging (MRI) findings in a fetus with intracranial hemorrhage and porencephaly, presumed secondary to intrauterine cytomegalovirus (CMV) infection. METHODS: A 20-year-old, G2, P1 woman presented at 28.6 weeks' gestation after ultrasound examination demonstrated apparently isolated fetal ascites. Evaluation included maternal serology, amniocentesis, and repeated ultrasound examinations. Fetal MRI evaluation was also performed. The infant was born at 35 weeks' gestational age. RESULTS: Maternal serology was positive for CMV IgG. Intrauterine CMV infection was confirmed using polymerase chain reaction (PCR). At 31.6 weeks' gestation, ultrasound demonstrated borderline lateral cerebral ventriculomegaly. MRI of the fetal brain on the same day demonstrated parenchymal hemorrhage in the right posterior temporal and parietal regions along with mild ventricular enlargement. Sonography one day before delivery revealed brain parenchymal cystic change consistent with porencephaly of the right posterior temporal and parietal region. Postnatal ultrasound, computed tomography (CT), and MRI confirmed the diagnosis of a porencephalic cyst communicating with the posterior body of the right lateral ventricle. Placental pathology was consistent with CMV infection. CONCLUSION: This case report illustrates that fetal MRI is a useful adjunct in the evaluation of intrauterine infection with CMV.