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ORIGINAL RESEARCH article

Front. Genet., 29 August 2022
Sec. Genetics of Common and Rare Diseases
This article is part of the Research Topic Unravelling the Basis of Non-Invasive Prenatal Screening Results View all 11 articles

Multisite assessment of the impact of cell-free DNA-based screening for rare autosomal aneuploidies on pregnancy management and outcomes

Tamara Mossfield
&#x;Tamara Mossfield1*Erica Soster&#x;Erica Soster2Melody MenezesMelody Menezes3Gloudi AgenbagGloudi Agenbag4Marie-Line DuboisMarie-Line Dubois5Jean GekasJean Gekas6Tristan HardyTristan Hardy3Monika JurkowskaMonika Jurkowska7Pascale KleinfingerPascale Kleinfinger8Kelly LoggenbergKelly Loggenberg4Pablo MarchiliPablo Marchili9Roberto SiricaRoberto Sirica10 on behalf of the Global Expanded NIPT Consortium
  • 1Genea, Sydney, NSW, Australia
  • 2Labcorp Women’s Health and Genetics, Laboratory Corporation of America, San Diego, CA, United States
  • 3Monash IVF Genetics, Monash IVF Group, Richmond, VIC, Australia
  • 4Next Biosciences, Johannesburg, South Africa
  • 5Faculty of Medicine, Laval University, Quebec City, QC, Canada
  • 6CHU de Quebec Research and Mother and Child Center, Department of Medical Genetics, University Hospital of Quebec, Laval University, Quebec City, QC, Canada
  • 7Genomed SA, Warsaw, Poland
  • 8Laboratory CERBA, Saint-Ouen-l’Aumône, France
  • 9Veragen, Buenos Aires, Argentina
  • 10AMES, Centro Polidiagnostico Strumentale, Srl, Naples, Italy

Cell-free (cf) DNA screening is a noninvasive prenatal screening approach that is typically used to screen for common fetal trisomies, with optional screening for sex chromosomal aneuploidies and fetal sex. Genome-wide cfDNA screening can screen for a wide variety of additional anomalies, including rare autosomal aneuploidies (RAAs) and copy number variants. Here, we describe a multi-cohort, global retrospective study that looked at the clinical outcomes of cases with a high-risk cfDNA screening result for a RAA. Our study cohort included a total of 109 cases from five different sites, with diagnostic outcome information available for 68% (74/109) of patients. Based on confirmatory diagnostic testing, we found a concordance rate of 20.3% for presence of a RAA (15/74) in our study population. Pregnancy outcome was also available for 77% (84/109) of cases in our cohort. Many of the patients experienced adverse pregnancy outcomes, including intrauterine fetal demise, fetal growth restriction, and preterm birth. These adverse outcomes were observed both in patients with fetal or placental confirmation of the presence of a RAA, as well as patients that did not undergo fetal and/or placental diagnostic testing. In addition, we have proposed some suggestions for pregnancy management and counseling considerations for situations where a RAA is noted on a cfDNA screen. In conclusion, our study has shown that genome-wide cfDNA screening for the presence of rare autosomal aneuploidies can be beneficial for both patients and their healthcare practitioners. This can provide a possible explanation for an adverse pregnancy outcome or result in a change in pregnancy management, such as increased monitoring for adverse outcomes.

Introduction

Clinical availability of cell-free (cf) DNA screening (also known as noninvasive prenatal testing [NIPT] or noninvasive prenatal screening [NIPS]) has resulted in a paradigm shift in chromosomal prenatal screening, with testing options quickly expanding from trisomy 21 screening only to the inclusion of screening for trisomies 13 and 18 (Nicolaides et al., 2012; Palomaki et al., 2012; Nicolaides et al., 2013), as well as optional screening for fetal sex and sex chromosomal aneuploidies (Mazloom et al., 2013; Samango-Sprouse et al., 2013). However, this cfDNA screening approach will still miss about 17% of clinically relevant fetal chromosomal abnormalities (Wellesley et al., 2012). In more recent years, the scope of cfDNA screening has broadened to encompass genome-wide screening for rare autosomal aneuploidies (RAAs) and partial deletions and duplications (i.e., copy number variants, including select microdeletion syndromes) as an option for some clinicians and their patients. Several studies have shown strong test performance for the detection of these additional anomalies by genome-wide cfDNA screening (Pescia et al., 2017; Pertile et al., 2021; Soster et al., 2021).

The screen-positive rate for RAAs in large genome-wide cfDNA screening studies has been shown to range from 0.12% (Scott et al., 2018) to 1.1% (Van Opstal et al., 2018). Benn et al. (Benn et al., 2019) pooled data from a number of studies and found that rare autosomal trisomies (RATs; i.e., an autosomal trisomy other than trisomy 21, 18, or 13) were present in 0.32% of cfDNA samples compared to 0.41% of trophoblast samples from chorionic villus sampling (CVS). Rare autosomal aneuploidies can be associated with a number of adverse pregnancy outcomes, including early miscarriage, intrauterine fetal demise (IUFD), fetal growth restriction (FGR), structural fetal anomalies, and preterm birth (Pertile et al., 2017; Eggenhuizen et al., 2021); as well as a proportion of cases in which there are no adverse pregnancy outcomes and birth of a healthy child. As cfDNA screening analyzes DNA released by apoptotic placental trophoblasts present in maternal plasma, a high-risk call for a RAA may be indicative of confined placental mosaicism (CPM) and not true fetal aneuploidy. A recent study (Van Opstal et al., 2020) found that cell-free DNA screening may be more sensitive than CVS for detection of CPM involving the cytotrophoblast. Although CPM cases are typically called as false positives for cfDNA screening, some studies have shown that CPM for autosomal aneuploidies can lead to adverse pregnancy outcomes, particularly for CPM involving chromosome 16 (Vaughan et al., 1994; Zimmermann et al., 1995; Sánchez et al., 1997; Van Opstal et al., 1998; Eggenhuizen et al., 2021), as well as chromosomes 2, 3, 7, 13, 15, and 22 (Eggenhuizen et al., 2021). In addition, a high-risk cfDNA result can be a marker for uniparental disomy (UPD, i.e., two copies of a whole chromosome derived from one parent (Benn, 2021)), especially if the CPM involves chromosomes that carry imprinted genes associated with defined syndromes (Mardy and Wapner, 2016; Grati et al., 2020).

With the increasing availability and uptake of genome-wide cfDNA screening, information on the clinical impact of rare autosomal aneuploidies will help guide pregnancy management and counseling. The majority of studies to date have had either small data sets or have not detailed the pregnancy and birth outcomes of patients in their study cohort. Here, we describe a global multi-site study that looked at the pregnancy and clinical outcomes following a high-risk RAA call in a large number of cases. We also wanted to determine if having a high-risk screening result for a rare autosomal aneuploidy was beneficial for management of the pregnancy in our cohort, and whether this was useful information for the healthcare provider and the pregnant patient. Results from our study, together with the experience of our Consortium members, were considered in an attempt to provide suggestions for pregnancy management and appropriate counselling of pregnant patients when these aneuploidies are detected.

Materials and methods

Study and patient details

All members of the Global Expanded NIPT Consortium were invited to submit details from their laboratory/clinic of cases reported as a rare autosomal aneuploidy following genome-wide cfDNA screening. Cases had to involve RAAs on a single whole chromosome only. All known cases from the time each site commenced genome-wide cfDNA screening, up to and including cases reported in 2021, were considered for inclusion in the study. The end date for cases reported in 2021 varied by contributing sites from May 2021 to October 2021, with one site not contributing any cases for 2021. The patient samples in this retrospective data analysis study were collected as part of routine cfDNA screening in either general or high-risk populations, dependent on the protocols and standards of care of each contributing site. The study included both singleton and twin pregnancies; however, not all sites performed genome-wide cfDNA screening for twin pregnancies. Referral indications for cfDNA screening were collected as noted on the Test Requisition Form (TRF).

Information on human chorionic gonadotropin levels, PAPP-A levels, inhibin levels, and nuchal translucency (NT) were available for some of the patients in our study cohort. These were collected either as part of conventional screening, as part of the first trimester anatomy scan, or as part of preeclampsia screening.

All data was de-identified before analysis was carried out. The study received an IRB exemption from WCBIRB as it does not meet the definition of human subject research as defined in 45 CFR 46.102; specifically, the research involves analysis of retrospectively collected de-identified data only.

Genome-wide cfDNA screening

Genome-wide cfDNA screening and analysis was carried out at each site following site-specific routine laboratory procedures. All of the sites used a massively parallel whole-genome next-generation sequencing approach. Four of the five sites used the VeriSeqTM NIPT Solution v2 assay (Illumina, Inc.) (Pertile et al., 2021); the other site used the TruSeqTM Nano 16 sample protocol (Illumina, Inc.) for sequencing of the cfDNA (Illumina, 2017).

Where available, the fetal fraction (FF) was provided for each RAA case that was included in the study. A subset of cases at one of the sites had non-interpretable FF results. Presence of a RAA was thought to be the underlying etiology for interference with the bioinformatics analysis. In these cases, the result was considered non-interpretable, and FF was not reported. However, this was considered an indication that a RAA was present, and another bioinformatic software was then utilized to establish which chromosome was involved. These non-interpretable FF cases were denoted as “FF unavailable” in the Results section of the manuscript.

Clinical outcomes collection

Follow-up was attempted for all cases and was carried out according to the individual procedures of each laboratory or clinic. Clinical outcome information included diagnostic procedures, namely chorionic villus sampling (CVS) and amniocentesis, products of conception (POC) testing, findings from ultrasound examinations, newborn physical exam information, and/or any testing performed on the newborn. Desired clinical outcome data included baseline demographic details, adverse pregnancy outcomes, birth weight, or outcomes from the ongoing pregnancy (such as serial growth and any newborn complications). Cases were considered to have had confirmatory fetal testing if amniocentesis, POC testing, or newborn testing (blood test or umbilical cord test) had been carried out. Cases were considered to have undergone confirmatory placental testing if CVS or placental testing at birth had been carried out. Cases were deemed to be concordant if they involved a full or mosaic RAA or UPD on the chromosome of interest.

Results

Patient and sample details

In our study, a total of five sites provided details on 109 patients that received a high-risk screening result for a rare autosomal aneuploidy following genome-wide cfDNA screening, including 20 cases from Site A, 6 from Site B, 66 from Site C, 12 from Site D, and 5 cases from Site E. The five study sites were from multiple geographical regions, namely Australia, Canada, Argentina, and South Africa. Patients that underwent cfDNA screening from 2015 to 2021 were included, with 2020 having the highest percentage of cases included in the study cohort (23.9%; Supplementary Figure S1). Patient demographics are shown in Table 1; mean maternal age was 36.1 years, and mean gestational age was 11.9 weeks. The vast majority of patients (107, 98.2%) had a singleton pregnancy; both ongoing twin cases were dichorionic twin pregnancies. As can be seen from Table 1, maternal age was the most common referral indication (58.7%) followed by patient preference (32.1%). For a number of cases, we reassigned the referral indication based on additional information as detailed in Table 1 footnotes. Information on whether conventional screening was performed was available for 95 (87.2%) patients in the study cohort; of these, 19 (17.4%) had conventional screening and 76 (69.7%) did not. Of the 76 cases where conventional screening was not carried out, PAPP-A results were provided for 17 cases and NT results were provided for 20 cases. Overall, NT results were available for 29 (26.6%) patients in our cohort, with 27 (93.1%) of these cases having a normal NT result (<3.5 mm).

TABLE 1
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TABLE 1. Demographics of the study cohort (n = 109).

Genome-wide cfDNA screening results

Figure 1 shows the distribution of RAAs (i.e., aneuploidies that were not trisomy 21, 18, or 13) across chromosomes in our patient population; no RAAs were found for chromosomes 1, 12, 17, and 19. There was only one monosomy case in our cohort (monosomy 18); the rest were all trisomy cases. Trisomy 7 was the most common RAA (n = 20; 18.3%), followed by trisomy 22 (n = 17; 15.6%) and trisomy 16 (n = 14; 12.8%). For the twin pregnancies, a trisomy 15 and a trisomy 22 were reported. There were four cases that were listed as singleton pregnancies that had a demised twin prior to the first cfDNA screening blood draw. All four of these cases (2x T15, 1x T22, and 1x T16) had a repeat blood draw with resolution of the aneuploidy, and normal pregnancy/birth outcomes. Diagnostic testing was only performed in one case and was normal for the ongoing twin. For additional details on these four cases, please see Appendix A (Data Sheet 1) in the Supplementary Materials. It is therefore reasonable to assume that in all four cases, the initial RAA noted on cfDNA screening may be attributed to the demised twin.

FIGURE 1
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FIGURE 1. Detected rare autosomal aneuploidies in the study cohort. There were no rare autosomal aneuploidies observed on chromosomes 1, 12, 17, or 19; trisomies observed on chromosomes 13, 18, or 21 were not included.

The fetal fraction (FF) was available for 67 (61.5%) cases in our study cohort and ranged from 3% to 27%, with both an average and a median of 9%. The fetal fraction distribution for these 67 cases across each of the affected chromosomes is shown in Supplementary Figure S2. We have categorized these 67 cases into cases that were concordant with the confirmatory fetal testing, concordant with the confirmatory placental testing, and the unconfirmed cases (includes cases where the RAA was not detected in the fetus but the placenta was not tested). We also highlighted the two discordant cases that underwent both confirmatory fetal and placental testing; further information on diagnostic outcomes is provided in the following section. There were seven chromosomes that had at least three RAA cases with FF information (Figure 2). Although the range of FF varied between these chromosomes, all cases reported a FF between 3% and 15% (except for the outlier of 27% for one of the trisomy 7 cases). It should be noted that all cases included in Figure 2 were singleton cases that underwent cfDNA screening in the first trimester. When we looked at these seven affected chromosomes only (chromosomes 7, 8, 9, 15, 16, 20, and 22), we found that there were also five RAA cases with known FFs from patients with singleton pregnancies that had undergone cfDNA screening in the second trimester (not shown in Figure 2). These included two trisomy 7 cases (13% FF; 15% FF), one case of trisomy 8 (9% FF), one case of trisomy 16 (14% FF), and one case of trisomy 22 (7%).

FIGURE 2
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FIGURE 2. Relationship between fetal fraction and RAAs per chromosome. The box plots represent the first and third quartile (upper and lower margins of the box, respectively), the minimum and maximum FF values (lower and upper whiskers, respectively), the median FF (horizontal line within the box), and the mean FF (X within the box). The dots are outliers.

Diagnostic outcome data

Figure 3 shows a flowchart of the outcomes for all 109 RAA cases, with details in Supplementary Table S1. Overall, 74/109 patients (67.9%) underwent some type of diagnostic testing, with most undergoing amniocentesis (Supplementary Table S2). The RAA was confirmed in 10/72 (13.9%) patients where fetal testing was performed. Six patients had both fetal and placental testing, and an additional two patients had placental testing only. The RAA was confirmed in five of these eight patients (62.5%), indicating CPM as the underlying etiology for positive NIPT. Thus, based on these findings, fifteen cases could be considered to be concordant (either fetal or placental) with the diagnostic testing; the diagnostic yield was therefore 20.3% (15/74; see Table 2 for details of these cases). There were no cases in our cohort where the RAA was found to be present in both the fetus and the placenta following diagnostic testing.

FIGURE 3
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FIGURE 3. Flowchart of outcomes for the study cohort (n = 109). IUFD, intrauterine fetal demise; PX, pregnancy; SAB, spontaneous abortion; TOP, termination of pregnancy. aSix cases underwent both fetal and placental testing. bIn two cases the cfDNA screening result was discordant with both fetus and placenta. cThe cfDNA screening result was confirmed in placental tissue in four of these cases: three liveborn (trisomy 8 case with FGR and premature birth; trisomy 16 case with spontaneous premature birth; trisomy 16 case with induced premature birth for preeclampsia) and one selective TOP (trisomy 15 with severe FGR). dThe other two TOP cases were a trisomy 20 case with multiple abnormalities noted on autopsy and a trisomy 7 case with cleft lip/palate identified on ultrasound following the cfDNA screen. eOne case (trisomy 7) had a mutation in SLC12A6; the other case (trisomy 8) had abnormalities but no further details are available.

TABLE 2
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TABLE 2. Details of concordant cases.

In addition, UPD testing was carried out for 18 cases in our study cohort, including eight trisomy 7 cases, one trisomy 14 case, six trisomy 15 cases, two trisomy 16 cases, and one trisomy 20 case. There was one case of maternal UPD 15 and one case of maternal UPD 16 reported; these two cases are included in the 15 confirmed concordant cases.

Moreover, there are a number of other cases in the total cohort (109 cases) where it is possible that a RAA was present in either the fetus or the placenta (see Figure 4). This includes the four demised twin cases [see Appendix A (Data Sheet 1) of the Supplementary Materials], where the initial cfDNA screen reported a RAA but follow-up cfDNA screening was normal. In one of the dichorionic twin cases, which reported a trisomy 22 by cfDNA screening, there was a selective termination of one of the twins following cfDNA screening but prior to diagnostic testing. That twin had cystic hygroma on ultrasound at 13 weeks as well as delayed growth and possible brain anomalies. Amniocentesis was carried out on the surviving twin only, which was found to be normal and there was a normal birth outcome. Amongst the singleton cases with no diagnostic testing, there were three cases of a spontaneous miscarriage (one trisomy 9 and two trisomy 22), twelve cases with an IUFD (one trisomy 7, three trisomy 15, two trisomy 16, one trisomy 20, and five trisomy 22 cases), and one case of an elective termination of pregnancy (TOP) due to fetal anomalies. If we include these additional 21 cases (Figure 4, category 2), then the concordance would increase to 33.0% (36/109). There were also 17 singleton cases that underwent diagnostic fetal testing (RAA not detected in the fetus), but not placental testing, that experienced adverse pregnancy outcomes (such as FGR, preeclampsia, or preterm birth) or that ended with a termination of the pregnancy. Both of the elective TOP cases had anomalies noted on ultrasound (Figure 4, category 3). If we include these additional 17 cases, then the concordance could be as high as 53/109 (48.6%).

FIGURE 4
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FIGURE 4. Estimation of concordance in the study cohort.

Pregnancy outcomes

Pregnancy outcome data was available for 84 cases in our cohort (Supplementary Table S1 and Figure 5). This included eight of the ten fetal concordant cases; further details of these cases are provided in Table 2. There were also 52 cases with pregnancy outcomes where the cfDNA screening result was not confirmed in the fetus. Of these 52 cases, three patients had preeclampsia, ten experienced FGR, and in one other case the placenta was reported as being “grossly abnormal.” Although the majority of these cases delivered at term, there were a number of cases that underwent an induced preterm delivery (Supplementary Table S1), and three of these patients had an elective termination of pregnancy. All three cases that underwent an elective TOP had anomalies noted on ultrasound or autopsy. The vast majority of these cases (46/52; 88.5%) had not undergone confirmatory placental testing.

FIGURE 5
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FIGURE 5. Pregnancy outcomes for the study cohort (n = 84).

In addition, there were 24 cases with pregnancy outcomes where fetal confirmatory testing had not been carried out. Of these 24 cases, 12 (50%) experienced IUFD (one trisomy 7, three trisomy 15, two trisomy 16, one trisomy 20, and five trisomy 22 cases), three cases (13%) experienced a spontaneous miscarriage (one trisomy 9 and two trisomy 22 cases), and two cases had an elective termination of pregnancy (one case had anomalies noted on ultrasound and the other case had a mutation in the SLC12A6 gene on prenatal diagnosis). The remaining seven cases were liveborn; of these seven liveborn cases, three were co-twin demise cases (discussed previously), one was an induced premature case with FGR, and another was a spontaneous premature case. Therefore, only two of the cases in this subcohort had no confirmed pregnancy complications.

Relationship between RAAs, low PAPP-A, and pregnancy outcomes

PAPP-A results were available for 29 patients in our cohort, of which 10 (34.5%) had low (<0.5 MoM) or very low (<0.2 MoM) PAPP-A values (Table 3). Two of these cases had a confirmed RAA (trisomy 16) in the fetus, with both reporting very low PAPP-A values (0.04 and 0.12). None of the 10 cases had placental testing for presence of aneuploidy. Fetal growth restriction was observed in four of these patients (one trisomy 2, one trisomy 7, one trisomy 15, and one trisomy 16). Overall, six of the ten cases noted pregnancy complications and one other case was an elective TOP (confirmed trisomy 16) which may have had complications that were not noted for the study. Of the 19 cases with normal PAPP-A values, fifteen underwent diagnostic testing—fourteen had amniocentesis with one case of confirmed RAA in the fetus (mosaic trisomy 16 [20%–30%]). The other case had postnatal testing of newborn blood (no aneuploidy detected) and placental tissue (which confirmed mosaic Trisomy 16 in the placenta). Two of these 19 cases experienced IUFD, one had a low-lying placenta, two had preeclampsia, and one had presence of fibroma.

TABLE 3
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TABLE 3. Relationship between RAAs, low PAPP-A, and Pregnancy Outcomes.

Discussion

Here, we discuss a multi-site global study looking at the clinical implications of prenatal screening for RAAs by genome-wide cfDNA screening. Our study showed the wide array of situations and outcomes that can occur when a patient receives a high-risk call for a RAA following cfDNA screening, reflecting the real-world experiences of prenatal screening. We found that early identification of these aneuploidies by genome-wide cfDNA screening was beneficial in a variety of clinical situations. It allowed for a change in pregnancy management in a number of cases (e.g., alteration of pregnancy monitoring for fetal growth and adverse pregnancy outcomes) and also provided a possible explanation for cases of miscarriage, co-twin demise, and fetal death as well as other pregnancy complications.

Trisomies 7, 22, and 16 were the most commonly observed trisomies in our study cohort. Trisomy 7 was also found to be the most commonly observed RAA in several other studies (Pertile et al., 2017; Scott et al., 2018; van der Meij et al., 2019; Van Den Bogaert et al., 2021). Trisomy 16 was the most common trisomy to be confirmed in either the fetus or the placenta (40% of all cases) in our cohort, with one case confirmed as UPD and the rest confirmed as mosaic trisomy 16. This is not surprising given that trisomy 16 is believed to be the most common trisomy, occurring in at least 1% of clinically recognized pregnancies (Hassold et al., 1995). Trisomy 16 is associated with a high probability of fetal death, fetal growth restriction, fetal anomalies, and preterm delivery (Benn, 1998; Peng et al., 2021). A study by Yong et al. (Yong et al., 2003) found that the level of trisomy in the different fetal or placental tissues was an indicator of the severity of outcomes. Unfortunately, we did not have complete outcomes for a number of our confirmed trisomy 16 cases.

In our study, ten of the 72 cases (14%) that underwent fetal diagnostic testing had a confirmed fetal RAA, with the majority of these cases ending in either an elective termination of pregnancy or fetal demise, highlighting the importance of this knowledge to the patient. As noted above, the true concordance could not be determined due to the fact that approximately a third of patients did not undergo confirmatory fetal testing and over 90% of patients did not have confirmatory placental testing. However, based on adverse pregnancy outcomes observed in many of the patients, there were many other cases where the RAA may have been present in either the fetus or the placenta. When we included the placental concordant cases, our overall rate of concordance was 20.3%. A recent study by Soster et al. (Soster et al., 2021) noted a positive predictive value of 22.4% for rare autosomal trisomies in a large cohort of genome-wide cfDNA screening samples. Although the PPV for rare autosomal aneuploidies is not as high as that for common trisomies, it is still approximately four-fold higher than the PPV observed (3.4%) using conventional screening for trisomies 21 and 18 (Gregg et al., 2016). Of the five confirmed CPM cases in our cohort, two had severe FGR and one had a spontaneous premature birth (outcomes for the remaining two cases are unknown), illustrating the impact that a placental RAA can have on pregnancy outcomes. A recent literature review by Eggenhuizen et al. (Eggenhuizen et al., 2021) looking at the association between CPM and adverse pregnancy outcomes found that CPM was associated with fetal growth restriction, preterm birth, structural fetal anomalies, and pregnancy complications such as preeclampsia. A number of these adverse outcomes were also noted in many of our study patients.

Our study clearly illustrates there can be value in genome-wide cfDNA screening for many patients, particularly in cases of pregnancy loss. Even in cases where diagnostic testing is not carried out, having a high-risk assessment for a RAA based on cfDNA screening may provide some explanation in the event of a pregnancy loss, which could be of value to patients. In our study cohort, we reported four cases of a co-twin demise, three cases of spontaneous miscarriage, and fourteen cases of IUFD. As noted above, in all four of the co-twin demise cases a follow-up cfDNA screen at a later gestational date did not show presence of a RAA, providing a likely explanation to the patient for loss of that twin. None of the spontaneous miscarriage cases underwent diagnostic testing. Although none of the IUFD cases had diagnostic testing prior to loss of the fetus, two of these 14 cases had follow-up POC analysis which showed presence of the RAA (trisomy 14 and trisomy 22, respectively) in the fetus. Genome-wide cfDNA screening can also be beneficial in altering the pregnancy management of the patient with the potential to offer increased and earlier ultrasounds and diagnostic procedures. In addition, a high-risk call for a RAA on a cfDNA screen can provide a possible explanation for pregnancy complications such as fetal growth restriction and preeclampsia.

Detailing outcomes for RAA cases can be very challenging in a study such as this one. This is due to the varying number of RAA cases per affected chromosome, the different approaches taken for pregnancy management of these patients, the differences in the outcome data collected and available at each of the contributing sites, and the low prevalence of RAAs in general. This has also been reported in single site studies of RAAs identified by cfDNA screening, with studies frequently reporting incomplete outcomes and varied clinical management practices (Liang et al., 2018; Kleinfinger et al., 2020; Soster et al., 2021). Whilst there is a myriad of ways that these outcomes could be grouped and analyzed, we chose to group patients into three different tiers as noted in Figure 4. The first tier (category 1) in our system represents patients where diagnostic testing found presence of the RAA in the fetus and/or placenta. The second tier (category 2) denotes cases where the high-risk RAA cfDNA screening result provided potentially valuable information for the patient, with outcomes that include pregnancy loss and elective termination of pregnancy following the identification of ultrasound anomalies. The final third tier (category 3) represents cases where the cfDNA screening result could be beneficial for the healthcare professional, as it indicated the need to monitor the pregnancy closely for complications such as fetal growth restriction and preeclampsia. Although our approach is subjective, this tiered system could be a useful framework for healthcare professionals in determining the clinical utility of screening for RAAs.

One of the strengths of our study is that it is a global multi-centre study where a broad spectrum of care was received by patients undergoing cfDNA screening. This includes the use of different patient protocols and techniques for follow-up testing and analysis, as well as varying clinical practices for pregnancy management in these patients. We also had a large number of patients with clinical outcome information, including diagnostic outcomes and/or pregnancy outcomes. A limitation of our study is that we only had a small number of rare autosomal aneuploidies on some chromosomes and no aneuploidies observed on other chromosomes, preventing us from drawing conclusions regarding the clinical impact of RAAs on individual chromosomes. Due to the low prevalence of RAAs, this will be a limitation of all studies looking at RAAs. As our study was a retrospective analysis and full outcomes were not available for all of the cases, we were also not able to make an accurate determination of the true rate of pregnancy complications and adverse pregnancy outcomes in our study population. Both of these limitations could be addressed in future studies that focus on either a particular rare autosomal aneuploidy or a particular type of outcome observed in these patients such as FGR or IUFD. In addition, there may have been ascertainment bias regarding which cases had placental testing, which may have also been influenced by the clinical protocols in place at each site. Due to the small number of cases that did undergo placental testing, it was not possible to make any statistical comparisons between known CPM cases and suspected CPM cases, or cases where CPM was ruled out. Finally, a large number of patients were of a slightly higher maternal age than would be observed in a general pregnancy cohort, with over 60% of study participants listing maternal age as the referral indication for genome-wide cfDNA screening.

A large number of studies have been published in recent years looking at the identification of RAAs by genome-wide cfDNA screening. There is a lot of variation in these studies, including type of patient population, number of samples tested, and availability of outcome information (such as diagnostic testing for presence of RAAs, UPD testing, and adverse pregnancy outcomes). We attempted to capture the large amount of data that currently exists in the literature by compiling a table (Supplementary Table S3) that provides an overview of many of these recent studies. We carried out this multi-site global study to not only add to this growing body of evidence, but also to provide more information on the pregnancy and birth outcomes experienced by patients with a high-risk call for a RAA following genome-wide cfDNA screening, as these outcomes are not provided in many of the other studies to date.

Based on the results of our study, information from previous publications identified through the literature review that we carried out, and the experiences of members of our Consortium, some options for pregnancy management and patient counseling have been considered, with recognition that further research in this area is required to confidently establish an appropriate approach. These considerations are outlined in Figure 6.

FIGURE 6
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FIGURE 6. Pregnancy management and patient counselling options for consideration. *NIPT is a screening test. No irreversible clinical decisions should be made based on these screening results alone.

In conclusion, our study has shown that genome-wide screening for presence of rare autosomal aneuploidies can be beneficial in a number of clinical situations, such as providing a possible explanation for an adverse pregnancy outcome or resulting in a change in pregnancy management. These interventions and possible explanations for pregnancy outcomes are of great benefit to pregnant patients, allowing for increased monitoring throughout the pregnancy or potentially alleviating any feelings of perceived personal responsibility for adverse outcomes. It can also be valuable for future pregnancies to determine if there is a recurrence risk for the anomaly in question. The recurrence risk may be low in many cases, which in itself can be valuable information in terms of the patient’s anxiety and future pregnancy planning. This multi-site global study adds to the growing body of evidence regarding genome-wide cfDNA screening, and also adds valuable information regarding the clinical outcomes of patients that receive a high-risk screening call for a rare autosomal aneuploidy.

Data availability statement

The data that support the findings of this study are available upon reasonable request from the corresponding author. The clinical outcome data in this study was obtained from patient records and therefore will not be made available through a database because of privacy concerns as well as ethical restrictions. However, deidentified data that underlie the results reported in this article (text, figures, tables, and appendices) are available by reasonable request within 12 months of publication. Proposals must include a detailed and sound methodological approach, including a statistical analysis plan, as would be reasonably required for the purposes of publication in a peer-reviewed scientific journal.

Ethics statement

The studies involving human participants were reviewed and approved by WCBIRB. Written informed consent for participation was not required for this study in accordance with the national legislation and the institutional requirements.

Author contributions

All authors contributed to the initial conception of the study. TM, MM, GA, MLD, JG, TH, KL, and PM contributed to data collection and entry or curation. ES assisted in data curation. TM, ES, and MM performed data analysis. ES, GA, MJ, PK, KL, and RS contributed to the background literature review. TM, ES, JG, and TH contributed to writing of the original draft of the manuscript. All authors contributed to review and editing of the manuscript, and all authors have read and approved the manuscript.

Acknowledgments

The authors would like to acknowledge and thank all members of the Global Expanded NIPT Consortium: Vivian Weinblatt (Labcorp Women’s Health and Genetics, Laboratory Corporation of America, San Diego, CA, United States); Thomas Westover (Dept of Maternal Fetal Medicine, Capital Health, Trenton, NJ, United States; Dept of OB/GYN, Cooper Medical School, Camden, NJ, United States); Summer Pierson (Myriad Genetics, San Francisco Bay Area, CA, United States); Simon Meagher (Monash Ultrasound for Women, Monash IVF Group, Victoria, Australia); Rebecca Dickson and Michael Bonifacio (Genea, Sydney, New South Wales, Australia); Katie Ellis (Genea, Sydney New South Wales, Australia; Illumina, Inc. San Diego, CA, United States); Armelle Luscan, Laurence Lohmann, and Fernando Martin (Laboratory CERBA, 7/11 Rue de l’Équerre, 95310 Saint-Ouen-l’Aumône, France); Luigia De Falco and Giovanni Savarese (AMES, Centro Polidiagnostico Strumentale, Srl, Naples, Italy); Anna Boguszewska-Chachulska (Genomed SA, Warsaw, Poland); Thomas Harasim (Medical Genetics Center, Munich, Germany); and Yvonne Holt and Renee Briers (Next Biosciences, Johannesburg, South Africa). The authors would also like to thank all of the team members at each of their respective institutes that are involved in the cfDNA screening process. Finally, the authors would like to thank Kristine Jinnett, Christin Coffeen, Kirsten Curnow, and Sucheta Bhatt (Illumina, Inc.) for their assistance in the preparation and critical review of the manuscript.

Conflict of interest

TM is an employee of Genea and has been a paid speaker for Illumina. ES is an employee of Laboratory Corporation of America with option to hold stock and has also been a paid speaker for Illumina. MM and TH are employees of Monash IVF Group. GA and KL are employed by Next Biosciences. JG previously received a research grant from Illumina, Inc. MJ is employed by Genomed SA. PK is employed by Laboratory CERBA. PM is employed by Veragen. RS is employed by AMES, Centro Polidiagnostico Strumentale, Srl.

The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fgene.2022.975987/full#supplementary-material

References

Benn, P., Malvestiti, F., Grimi, B., Maggi, F., Simoni, G., and Grati, F. R. (2019). Rare autosomal trisomies: comparison of detection through cell-free DNA analysis and direct chromosome preparation of chorionic villus samples. Ultrasound Obstet. Gynecol. 54 (4), 458–467. doi:10.1002/uog.20383

PubMed Abstract | CrossRef Full Text | Google Scholar

Benn, P. (1998). Trisomy 16 and trisomy 16 mosaicism: a review. Am. J. Med. Genet. 79 (2), 121–133. doi:10.1002/(sici)1096-8628(19980901)79:2<121:aid-ajmg8>3.0.co;2-t

PubMed Abstract | CrossRef Full Text | Google Scholar

Benn, P. (2021). Uniparental disomy: Origin, frequency, and clinical significance. Prenat. Diagn. 41 (5), 564–572. doi:10.1002/pd.5837

PubMed Abstract | CrossRef Full Text | Google Scholar

Eggenhuizen, G. M., Go, A., Koster, M. P. H., Baart, E. B., and Galjaard, R. J. (2021). Confined placental mosaicism and the association with pregnancy outcome and fetal growth: a review of the literature. Hum. Reprod. Update 27 (5), 885–903. doi:10.1093/humupd/dmab009

PubMed Abstract | CrossRef Full Text | Google Scholar

Grati, F. R., Ferreira, J., Benn, P., Izzi, C., Verdi, F., Vercellotti, E., et al. (2020). Outcomes in pregnancies with a confined placental mosaicism and implications for prenatal screening using cell-free DNA. Genet. Med. 22 (2), 309–316. doi:10.1038/s41436-019-0630-y

PubMed Abstract | CrossRef Full Text | Google Scholar

Gregg, A. R., Skotko, B. G., Benkendorf, J. L., Monaghan, K. G., Bajaj, K., Best, R. G., et al. (2016). Noninvasive prenatal screening for fetal aneuploidy, 2016 update: a position statement of the American college of medical genetics and genomics. Genet. Med. 18 (10), 1056–1065. doi:10.1038/gim.2016.97

PubMed Abstract | CrossRef Full Text | Google Scholar

Hassold, T., Merrill, M., Adkins, K., Freeman, S., and Sherman, S. (1995). Recombination and maternal age-dependent nondisjunction: molecular studies of trisomy 16. Am. J. Hum. Genet. 57 (4), 867–874.

PubMed Abstract | Google Scholar

Kleinfinger, P., Lohmann, L., Luscan, A., Trost, D., Bidat, L., Debarge, V., et al. (2020). Strategy for use of genome-wide non-invasive prenatal testing for rare autosomal aneuploidies and unbalanced structural chromosomal anomalies. J. Clin. Med. 9 (8), E2466. doi:10.3390/jcm9082466

PubMed Abstract | CrossRef Full Text | Google Scholar

Liang, D., Lin, Y., Qiao, F., Li, H., Wang, Y., Zhang, J., et al. (2018). Perinatal outcomes following cell-free DNA screening in >32 000 women: Clinical follow-up data from a single tertiary center. Prenat. Diagn. 38 (10), 755–764. doi:10.1002/pd.5328

PubMed Abstract | CrossRef Full Text | Google Scholar

Mardy, A., and Wapner, R. J. (2016). Confined placental mosaicism and its impact on confirmation of NIPT results. Am. J. Med. Genet. C Semin. Med. Genet. 172 (2), 118–122. doi:10.1002/ajmg.c.31505

PubMed Abstract | CrossRef Full Text | Google Scholar

Mazloom, A. R., Dzakula, Z., Oeth, P., Wang, H., Jensen, T., Tynan, J., et al. (2013). Noninvasive prenatal detection of sex chromosomal aneuploidies by sequencing circulating cell-free DNA from maternal plasma. Prenat. Diagn. 33 (6), 591–597. doi:10.1002/pd.4127

PubMed Abstract | CrossRef Full Text | Google Scholar

Nicolaides, K. H., Syngelaki, A., Ashoor, G., Birdir, C., and Touzet, G. (2012). Noninvasive prenatal testing for fetal trisomies in a routinely screened first-trimester population. Am. J. Obstet. Gynecol. 207 (5), 374.e371–e6. doi:10.1016/j.ajog.2012.08.033

PubMed Abstract | CrossRef Full Text | Google Scholar

Nicolaides, K. H., Syngelaki, A., Gil, M., Atanasova, V., and Markova, D. (2013). Validation of targeted sequencing of single-nucleotide polymorphisms for non-invasive prenatal detection of aneuploidy of chromosomes 13, 18, 21, X, and Y. Prenat. Diagn. 33 (6), 575–579. doi:10.1002/pd.4103

PubMed Abstract | CrossRef Full Text | Google Scholar

Palomaki, G. E., Deciu, C., Kloza, E. M., Lambert-Messerlian, G. M., Haddow, J. E., Neveux, L. M., et al. (2012). DNA sequencing of maternal plasma reliably identifies trisomy 18 and trisomy 13 as well as down syndrome: an international collaborative study. Genet. Med. 14 (3), 296–305. doi:10.1038/gim.2011.73

PubMed Abstract | CrossRef Full Text | Google Scholar

Peng, H., Yang, J., Wang, D., Guo, F., Hou, Y., and Yin, A. (2021). Outcomes of pregnancies with trisomy 16 mosaicism detected by NIPT: a series of case reports. Mol. Cytogenet. 14 (1), 44. doi:10.1186/s13039-021-00559-w

PubMed Abstract | CrossRef Full Text | Google Scholar

Pertile, M. D., Flowers, N., Vavrek, D., Andrews, D., Kalista, T., Craig, A., et al. (2021). Performance of a paired-end sequencing-based noninvasive prenatal screening test in the detection of genome-wide fetal chromosomal anomalies. Clin. Chem. 67, 1210–1219. doi:10.1093/clinchem/hvab067

PubMed Abstract | CrossRef Full Text | Google Scholar

Pertile, M. D., Halks-Miller, M., Flowers, N., Barbacioru, C., Kinnings, S. L., Vavrek, D., et al. (2017). Rare autosomal trisomies, revealed by maternal plasma DNA sequencing, suggest increased risk of feto-placental disease. Sci. Transl. Med. 9 (405), eaan1240. doi:10.1126/scitranslmed.aan1240

PubMed Abstract | CrossRef Full Text | Google Scholar

Pescia, G., Guex, N., Iseli, C., Brennan, L., Osteras, M., Xenarios, I., et al. (2017). Cell-free DNA testing of an extended range of chromosomal anomalies: clinical experience with 6, 388 consecutive cases. Genet. Med. 19 (2), 169–175. doi:10.1038/gim.2016.72

PubMed Abstract | CrossRef Full Text | Google Scholar

Samango-Sprouse, C., Banjevic, M., Ryan, A., Sigurjonsson, S., Zimmermann, B., Hill, M., et al. (2013). SNP-based non-invasive prenatal testing detects sex chromosome aneuploidies with high accuracy. Prenat. Diagn. 33 (7), 643–649. doi:10.1002/pd.4159

PubMed Abstract | CrossRef Full Text | Google Scholar

Sánchez, J. M., López De Díaz, S., Panal, M. J., Moya, G., Kenny, A., Iglesias, D., et al. (1997). Severe fetal malformations associated with trisomy 16 confined to the placenta. Prenat. Diagn. 17 (8), 777–779. doi:10.1002/(sici)1097-0223(199708)17:8<777:aid-pd128>3.0.co;2-h

PubMed Abstract | CrossRef Full Text | Google Scholar

Scott, F., Bonifacio, M., Sandow, R., Ellis, K., Smet, M. E., and McLennan, A. (2018). Rare autosomal trisomies: Important and not so rare. Prenat. Diagn. 38 (10), 765–771. doi:10.1002/pd.5325

PubMed Abstract | CrossRef Full Text | Google Scholar

Soster, E., Boomer, T., Hicks, S., Caldwell, S., Dyr, B., Chibuk, J., et al. (2021). Three years of clinical experience with a genome-wide cfDNA screening test for aneuploidies and copy-number variants. Genet. Med. 23 (7), 1349–1355. doi:10.1038/s41436-021-01135-8

PubMed Abstract | CrossRef Full Text | Google Scholar

Van Den Bogaert, K., Lannoo, L., Brison, N., Gatinois, V., Baetens, M., Blaumeiser, B., et al. (2021). Outcome of publicly funded nationwide first-tier noninvasive prenatal screening. Genet. Med. 23 (6), 1137–1142. doi:10.1038/s41436-021-01101-4

PubMed Abstract | CrossRef Full Text | Google Scholar

van der Meij, K. R. M., Sistermans, E. A., Macville, M. V. E., Stevens, S. J. C., Bax, C. J., Bekker, M. N., et al. (2019). TRIDENT-2: National implementation of genome-wide non-invasive prenatal testing as a first-tier screening test in the Netherlands. Am. J. Hum. Genet. 105 (6), 1091–1101. doi:10.1016/j.ajhg.2019.10.005

PubMed Abstract | CrossRef Full Text | Google Scholar

Van Opstal, D., Eggenhuizen, G. M., Joosten, M., Diderich, K., Govaerts, L., Galjaard, R. J., et al. (2020). Noninvasive prenatal testing as compared to chorionic villus sampling is more sensitive for the detection of confined placental mosaicism involving the cytotrophoblast. Prenat. Diagn. 40 (10), 1338–1342. doi:10.1002/pd.5766

PubMed Abstract | CrossRef Full Text | Google Scholar

Van Opstal, D., Van den Berg, C., Deelen, W. H., Brandenburg, H., Cohen-Overbeek, T. E., Halley, D. J., et al. (1998). Prospective prenatal investigations on potential uniparental disomy in cases of confined placental trisomy. Prenat. Diagn. 18 (1), 35–44. doi:10.1002/(sici)1097-0223(199801)18:1<35:aid-pd214>3.0.co;2-l

PubMed Abstract | CrossRef Full Text | Google Scholar

Van Opstal, D., van Maarle, M. C., Lichtenbelt, K., Weiss, M. M., Schuring-Blom, H., Bhola, S. L., et al. (2018). Origin and clinical relevance of chromosomal aberrations other than the common trisomies detected by genome-wide NIPS: results of the TRIDENT study. Genet. Med. 20 (5), 480–485. doi:10.1038/gim.2017.132

PubMed Abstract | CrossRef Full Text | Google Scholar

Vaughan, J., Ali, Z., Bower, S., Bennett, P., Chard, T., and Moore, G. (1994). Human maternal uniparental disomy for chromosome 16 and fetal development. Prenat. Diagn. 14 (8), 751–756. doi:10.1002/pd.1970140817

PubMed Abstract | CrossRef Full Text | Google Scholar

Wellesley, D., Dolk, H., Boyd, P. A., Greenlees, R., Haeusler, M., Nelen, V., et al. (2012). Rare chromosome abnormalities, prevalence and prenatal diagnosis rates from population-based congenital anomaly registers in Europe. Eur. J. Hum. Genet. 20 (5), 521–526. doi:10.1038/ejhg.2011.246

PubMed Abstract | CrossRef Full Text | Google Scholar

Yong, P. J., Barrett, I. J., Kalousek, D. K., and Robinson, W. P. (2003). Clinical aspects, prenatal diagnosis, and pathogenesis of trisomy 16 mosaicism. J. Med. Genet. 40 (3), 175–182. doi:10.1136/jmg.40.3.175

PubMed Abstract | CrossRef Full Text | Google Scholar

Zimmermann, R., Lauper, U., Streicher, A., Huch, R., and Huch, A. (1995). Elevated alpha-fetoprotein and human chorionic gonadotropin as a marker for placental trisomy 16 in the second trimester? Prenat. Diagn. 15 (12), 1121–1124. doi:10.1002/pd.1970151207

PubMed Abstract | CrossRef Full Text | Google Scholar

Keywords: noninvasive prenatal testing, rare autosomal aneuploidy, pregnancy outcome, mosaicism, genetic counseling, genome-wide

Citation: Mossfield T, Soster E, Menezes M, Agenbag G, Dubois M-L, Gekas J, Hardy T, Jurkowska M, Kleinfinger P, Loggenberg K, Marchili P and Sirica R (2022) Multisite assessment of the impact of cell-free DNA-based screening for rare autosomal aneuploidies on pregnancy management and outcomes. Front. Genet. 13:975987. doi: 10.3389/fgene.2022.975987

Received: 22 June 2022; Accepted: 21 July 2022;
Published: 29 August 2022.

Edited by:

Elisabetta Pelo, Azienda Ospedaliero Universitaria Careggi, Italy

Reviewed by:

Irene Madrigal, Hospital Clinic of Barcelona, Spain
Celia Badenas, Hospital Clinic of Barcelona, Spain

Copyright © 2022 Mossfield, Soster, Menezes, Agenbag, Dubois, Gekas, Hardy, Jurkowska, Kleinfinger, Loggenberg, Marchili and Sirica. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Tamara Mossfield, tamara.mossfield@genea.com.au

These authors share first authorship

Additional members of the Global Expanded NIPT Consortium and their respective affiliations are listed in the Acknowledgments section

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.