A total of 756 cases of PRUV were identified from 435,428 pregnancies, obtaining an incidence rate of 0.17%. Most of the cases (n=654, 86.5%) were of isolated PRUV, in which no additional anomalies (excluding isolated SUA) were found on prenatal ultrasound examination. However, 102 cases were complicated PRUV (13.5%) in which additional anomalies were found on prenatal ultrasound examination. The demographic characteristics of these fetuses with PRUV are summarized in Table 1. The pregnant women were 17–45 years old, and gestational age at diagnosis ranged from 16.0 to 40.4 weeks.
Concomitant anomalies in 102 fetuses with complicated PRUV are listed in Table 2. These included 41 cardiovascular (40.2%), 22 nervous (21.6%), 17 urinary (16.7%), 15 skeletal (14.7%), five digestive (4.9%), and four respiratory anomalies (3.9%) and 29 other anomalies (some fetuses had multiple concomitant anomalies). The positive predictive values of a PRUV for any fetal anomalies and cardiovascular anomalies were 13.5% (95% confidence interval [CI], 11.2%–16.2%) and 5.4% (95%CI, 4.0%–7.3%), respectively.
PRUV was associated with a higher incidence of any fetal anomalies (odds ratio [OR], 5.42; 95% CI, 4.32–6.82). When fetal anomalies were classified by systems, PRUV was associated with a higher incidence of anomalies in the cardiovascular system (OR, 9.15; 95%CI, 6.3–13.29), nervous system (OR, 6.76; 95%CI, 4.16–11.0), urinary system (OR, 7.7; 95%CI, 4.39–13.49), skeletal system (OR, 8.41; 95%CI, 4.6–15.4), digestive system (OR, 12.82; 95%CI, 4.18–39.28) and respiratory system (OR, 3.72; 95%CI, 1.28–10.82).
A total of 41 PRUV fetuses in this group had concomitant cardiac malformations. Among them, cardiac malformations were detected by obstetric ultrasound in 29 cases, which were consistent with results from fetal echocardiography. In 10 cases, cardiac malformations were detected with obstetric ultrasound; however, the malformation types could not be determined and were therefore confirmed using fetal echocardiography with the following results: 1case of single ventricle (SV), complete transposition of the great arteries (TGA) and total anomalous pulmonary venous; 1 case of interrupted aortic arch, hypoplastic left heart and persistent left superior vena cava (PLSVC); 1 case of atrial septal defect and common arterial trunk (CAT); 1 case of double outlet right ventricle, ventricular septal defect (VSD) and pulmonary artery stenosis (PAS); 1 case of right-sided aortic arch and aberrant left subclavian artery; 1 case of CAT and VSD; 1 case of SV and pulmonary artery valve stenosis; 1 case of complete atrioventricular canal defect (ACD) and PAS; 1 case of complete ACD and CAT; and 1 case of tetralogy of Fallot. Cardiac malformations could not be detected in 2 cases by obstetric ultrasound, but were later confirmed with fetal echocardiography, including 1 case of perimembranous VSD and 1 case of PLSVC.
In 756 PRUV fetuses, 31 developed SUA, of which 16 had other anomalies (10 had cardiovascular anomalies). In PRUV fetuses, SUA was associated with a higher incidence of any concomitant anomalies (OR, 7.93; 95%CI, 3.78–16.6) and a higher incidence of cardiovascular anomalies (OR, 10.66; 95%CI, 4.63–24.56). Moreover, the sensitivity and positive predictive values of SUA for any concomitant anomalies were 15.7% (95%CI, 9.5%–24.5%) and 51.6% (95%CI, 33.4%–69.4%) and those for cardiovascular anomalies were 24.3% (95%CI, 12.9%–40.6%) and 32.3% (95%CI, 17.3%–51.5%), respectively. Among the 31 PRUV fetuses with concomitant SUA, 9 underwent prenatal chromosomal examinations. Of those, 5 had concomitant SUA without other anomalies and chromosomal examination results that were normal. The remaining 4 fetuses had concomitant SUA and other malformations, including 2 with trisomy 18 and 2 that were normal (Table 3).
A total of 189 PRUV fetuses underwent chromosomal examinations, including 2 aneuploid fetuses with multiple congenital anomalies (both were trisomy 18) (Table 3), and 187 PRUV fetuses with normal karyotypes (40 with complicated PRUV, and 147 with isolated PRUV). In addition, we found three cases of chromosome variation: 1 case of isolated PRUV with 46, XN, inv(9) (p12q13), 1 case of complicated PRUV with 46, XN, inv(9)(p11q13) presenting with spina bifida, and one case of complicated PRUV with 46, XN (15pslk+) (16qh+) presenting with cerebellar vermis agenesis, mandibular hypoplasia, acromphalus, bilateral club hands, a VSD, and TGA. (Chromosome tests in China do not report sex, so N represented chromosome X or Y.)
Of the 639 fetuses with isolated PRUV, 93 were lost to follow-up and 546 did not present any anomalies at birth. Of the 102 cases of complicated PRUV, 12 were lost to follow-up, including one intrauterine death with concomitant acromphalus, SUA, and umbilical cyst; 38 cases of termination of pregnancy (TOP); 1 neonatal death with diaphragmatic hernia and left lung dysplasia, eight postnatal surgeries, and 42 did not receive special treatment after birth. Among the 38 cases of TOP, we identified 2 trisomy 18 fetuses with multiple malformations (Table 3). The remaining 36 fetuses included 18 cardiac, 10 nervous, 8 skeletal, five urinary, and three digestive malformations. In addition, we found 8 cases of SUA, two cases of cleft lip and cleft palate, one case of acromphalus, one case of diaphragmatic hernia, and one case of left lung agenesis. (Some cases had multiple concomitant malformations.)