2.1 Disease types
In total, 420 fetuses with RA dilation were included in the current study. RA dilatation may present in many cardiac malformations, or, in some cases, appear in normal fetuses in late pregnancy as a result of increasing blood volume in the right heart system. These fetuses with dilated RAs were then classified into three types: physiological RA dilatation (physiological group, n=202), the increasing of RA volume (volume overload group, n=142), and the increasing of right heart pressure (pressure overload group, n=76). Hemodynamics in normal fetuses and in those with RA dilatation were illustrated in a sketch map (Figure 1).
Among the reasons for RA dilation, physiological enlargement was undoubtedly the most common, especially in late pregnancy. For these 202 fetuses, 184 cases showed a normal RA/LA within the first 2 weeks of life by postnatal echocardiogram, 133 of which had an opening foramen ovale (FO), 7 had a patent ductus arteriosus (DA). Another 18 neonates showed an enlarged RA with a large-in-sized interatrial left-to-right shunting suspected as atrial septal defect.
For fetuses in the last two groups, RA dilatation is a manifestation of abnormal hemodynamics for associated cardiac anomalies, the clinical relevance of which are summarized in Table 1 in the current case series. For these fetuses, the most common reason for RA dilatation is the increasing RA volume, in which the restrictive FO (R-FO) has the highest incidence (n=51). In this malformation, the 4CV can only show an enlarged RA (Figure 2a). A sagittal view may show the small gap between a fixed FO valves and the septum secundum, which is the real entrance of FO to the LA (Figure 2b). An additional movie file shows this in more detail [See Additional file 1: Video]. For these R-FO fetuses without CHDs in our study, most cases showed a normal RA/LA within the first 2 weeks of life by postnatal echocardiogram. Only 8 neonates with an enlarged RA showed different degrees of TR without other significant cardiac anomalies.
Table 1. The clinical relevance of fetuses with right atrium dilatation in our case series.
Diagnosis
|
GW
|
Associated cardiac anomaly
|
Outcome
|
19-31
|
32-36
|
TOP
|
IFUD
|
NNA
|
Physiological
|
52
|
150
|
TR (101)
|
0
|
0
|
202
|
Volume overload
|
|
|
|
|
|
|
R-FO
|
3
|
48
|
HLHS (9); PV-S (5)*; TR (21)
|
9
|
0
|
42
|
Tricuspid dysplasia
|
28
|
15
|
VSD (3); PE (14); TR (43)
|
2
|
0
|
41
|
Ebstein’s anomaly
|
13
|
3
|
PV-S (4)*; PV-A(3)#; VSD(4); TCA(2); PE(2); TR(16)
|
5
|
0
|
11
|
Tricuspid atresia
|
9
|
0
|
VSD (5); PV-S (5)*; HRHS(7); PE(3)
|
6
|
0
|
3
|
TAPVC
|
16
|
3
|
VSD (5); PLSVC (3)
|
2
|
1
|
16
|
Galen aneurysm
|
2
|
2
|
Ascites (4); SUA (2)
|
0
|
0
|
4
|
Pressure overload
|
|
|
|
|
|
|
Pulmonary stenosis
|
32
|
12
|
VSD (8); PE (6); PLSVC (2); TR (35)
|
2
|
0
|
42
|
Pulmonary atresia
|
13
|
0
|
VSD (5); DORV (2); HRHS (4); PE (2); TR (8)
|
4
|
0
|
9
|
Ductus closure
|
2
|
7
|
VSD (3); RAA (2); PE (3); TR(9)
|
2
|
0
|
7
|
Ductus contraction
|
3
|
7
|
TR (10)
|
0
|
0
|
10
|
*Cases not repeatedly recorded in the pulmonary valve stenosis group
# Cases not repeatedly recorded in the pulmonary valve atresia group
DORV: double outlet right ventricle; GW: gestational weeks; HLHS: hypoplastic left heart syndrome; HRHS: hypoplastic right heart syndrome;IFUD: intrauterine fetal death; NNA: neonatal alive; PE: pericardial effusion; PLSVC: persistent left superior vena cava; PV-A: pulmonary valve atresia; PV-S: pulmonary valve stenosis; RAA: right aortic arch; R-FO: restrictive foramen ovale; TAPVC: total anomalous pulmonary venous connection; TCA: truncus arteriosus; TOP: termination of pregnancy; TR: tricuspid regurgitation; VSD: ventricular septal defect.
Pulmonary abnormalities, including pulmonary valve stenosis and atresia, are common reasons for RA dilatation with an increasing right heart pressure. In a case of pulmonary valve atresia, the 4CV shows an enlarged RA and a hypertrophic right ventricle (RV), together with a severe TR (Figure 3a). The pulmonary valve is presented as a thick echo dense membrane with no blood visualized going through the pulmonary valve during systole. In addition, the blood flow direction in the ductus is from the descending aorta (DAO) to the pulmonary artery, instead of the normal PA-DAO direction (Figure 3b). An additional movie file shows this in more detail [See Additional file 2: Video].
2.2 Ratio of right atrium to left atrium
In normal circumstances, the size of RA is larger than LA in late pregnancy, especially after 32 gestational weeks (GW). The fetuses were then divided into two subgroups according to gestational age (19-31GW, and 32-36 GW) when assessing the ratio of RA/LA and making comparisons among different groups (Figure 4). For both subgroups, the RA/LA ratio in the volume overload group is significantly higher than the pressure overload group (both P=0.000) and the physiological group (both P=0.000). However, there is no difference between the pressure overload group and the physiological group for fetuses in both subgroups (P=0.694 for 19-31 GW, and P=0.974 for 32-36 GW, respectively).
2.3 The peak velocity of tricuspid regurgitation in different diseases
As RA dilation is always accompanied by TR and the peak velocity of TR (VTR) is easy to obtain during echocardiographic examinations, we made an analysis in fetuses complicated with TR in our case series. The mean VTR for the physiological group, volume overload group and the pressure overload group are (0.88±0.45) m/s, (1.85±0.45) m/s and (3.29±0.58) m/s, respectively. These records showed that VTR in the pressure overload group is significantly higher than both the volume overload group (P=0.000) and the physiological group (P=0.000). In addition, the volume overload group shows a significantly higher VTR than the physiological group (P=0.000).
As the pressure overload group shows a highest value of VTR, we further conducted a separate analysis to find the difference between the pulmonary anomalies (including pulmonary valve atresia and stenosis) and the ductal abnormalities (including closure and contraction of DA). The result shows that the latter has a significantly higher value of VTR (3.98±0.41 m/s vs. 3.03±0.38 m/s, P=0.000) than the former.