Sociodemographic parameters and perinatal outcomes
Women enrolled in the study had a mean age of 33.0 (±4.4) years and a median gestational age of 36.4 (35.3–37.4) weeks of gestation at study entry. Demographics of the excluded participants did not differ from those with all measures. Statistical comparison of SG and CG showed no differences in the used matching criteria (Table S1).
Maternal and fetal iron homeostasis
10.4% of the included women were anemic prior to delivery (Hb < 11mg/dL). However, we found no differences in fetal iron parameters, maternal intake of iron supplements, fetal and maternal hemoglobin, RBC indices and anemia status between SG and CG (Table S2).
FSI
MHR and fHR coupling analysis revealed a higher FSI among SG than among CG (0.38 ((–0.22)–0.75) versus –0.01 ((–0.36)–0.34); p = 0.024) (Table S1). FSI showed no correlation to any measured fetal iron biomarker for either sex (Table S3).
However, within the automatically binned ranges of cord blood serum iron biomarker values, we observed FSI differences. FSI was higher in SG than in CG for ferritin levels between 153 and 279 μg/L ((n=42; 24 CG; 18 SG); 0.40 (±0.57) versus 0.01 (±0.47); p = 0.03, transferrin saturation of 32%–47% ((n=24; 12 CG; 12 SG); 0.30 (±0.66) versus –0.24 (±0.27); p = 0.045), and hepcidin values between 0 and 57 ng/mL ((n=92; 47 CG; 45 SG) (0.34 (±0.68) versus –0.01 (±0.56); p = 0.01). Using current newborn guidelines and validated ranges the above-mentioned values of iron markers would be normal15-17. Overall, FSI at ~36 weeks of gestation was higher in SG fetuses averaging 0.34 compared with –0.10 in CG fetuses within these cord blood iron biomarker ranges.
Sex-specific differences
We identified sex-specific differences in iron homeostasis among male infants and showed that the PS effect on iron homeostasis depends on the neonates’ sex.
Cord blood transferrin saturation was lower in SG male neonates compared with those in male CG, regardless of iron supplementation. For ferritin levels, we observed a trend towards lower values in male SG (Table 1).
The GEE model revealed that sex is a significant effect modifier that exhibited differences for ferritin (p = 0.038, Fig 2), and a trend for transferrin saturation (p = 0.070, Fig S1). For hepcidin, we found no significant sex-driven differences.
Interestingly, maternal hair cortisol tended to increase in SG mothers of female neonates (Table 1). FSI group differences were explained by male neonates only.
Table 1. Sex-specific effect of PS on biomarkers.
Characteristics
Male newborns
|
CG
n=26
|
SG
n=32
|
p
|
FSI (n=35 CG, n=43 SG)
Maternal hair cortisol
[pg/mg] (n=35 CG, n=36 SG)
Cord blood ferritin [μg/L]*
|
–0.13 ((–0.45)–0.31)
115 (14–146)
229.7 (113.9–429.6)
|
0.30 ((–0.18)–0.61)
124 (40–161)
149.6 (96.8–234.0)
|
0.050
0.466
0.069
|
Cord blood transferrin saturation [%]
|
63.4 (±17.7)
|
52.9 (±20.2)
|
0.041
|
Cord blood hepcidin [ng/dL]
|
26.1 (11.8–41.8)
|
17.0 (10.5–30.7)
|
0.184
|
Female newborns
|
n=28
|
n=21
|
p
|
FSI (n=39 CG, n=22 SG)
Maternal hair cortisol
[pg/mg] (n=32 CG, n=21 SG)
Cord blood ferritin [μg/L]
Cord blood transferrin saturation [%]
|
0.10 (±0.55)
88 (46–119)
218.2 (±84.8)
55.9 (±17.0)
|
0.27 (±0.84)
122 (67–180)
243.1 (±130.0)
57.8 (±17.8)
|
0.394
0.073
0.423
0.703
|
Cord blood hepcidin [ng/dL]
|
22.7 (14.1–37.7)
|
20.9 (6.0–37.1)
|
0.599
|
Data are mean (SD) using t-test or median (interquartile range) using Mann-Whitney U test. Sample size is indicated as applicable. Differences with p-value < 0.1 are in bold.
*missing values for 1 SG
Estimated causal effect
We conducted causal inference to investigate the effects of the aforementioned relationships more explicitly. We identified certain variables as adjustment sets in blocking all non-causal paths between the treatment and outcome variables while leaving all causal paths unblocked (Fig. 3). Examination of the causal model on the PS → Cord Blood Ferritin and PS → Bayley Score pathway demonstrated two minimum adjustment sets: “Maternal Age” and “SES” or “Maternal Age” and “Education.” Either set could be used to obtain an estimate for the causal effect. Our SES data are represented by “Household income>5000€/month,” and maternal education by “University Degree.'' Controlling for the minimum adjustment set “University Degree” and “Maternal Age” revealed an estimated average exposure effect of lowered cord blood ferritin at the alpha = 0.10 level at –38.06 μg/L (95% CI: –79.91 to 3.78) in SG compared with that in CG (Table S4). This average exposure effect became obscured when fetal sex was included (p-value increased from 0.07 to 0.19) demonstrating that sex is a strong effect modifier on the causal pathway between PS → Fetal Iron Biomarker.
ML for group classification
First, we considered iron biomarkers and FSI, which predicted the groups at an AUROC = 0.706 (±0.194). Next, we added the salient clinical and demographic data (gestational and maternal age, BMI at study entry, pre-pregnancy BMI, planned/non-planned pregnancy, higher education yes/no, income over 5000€ yes/no). These are the features that we also used in the DAG approach and that were available at the time of the taECG measurement at study entry. Doing so, we achieved an AUROC=0.759 (±0.082). The corresponding feature importance ranking is shown in the supplement (Fig. S2). Use of clinical and demographic data reduced the classification performance to AUROC = 0.688 (±0.142), similar to using FSI (AUROC = 0.665 ± 0.126) or iron parameters (AUROC = 0.587 ± 0.183) alone. In general, sex ranked in the lower 5% of variable importance, yielding only a slight improvement.