Cardiometabolic Function in Offspring, Mother and Placenta After Assisted Reproductive Technology

The overall objective is to establish the first-of-its-kind longitudinal cohort of pregnant women, biological fathers/partners and offspring from pregnancies achieved by frozen embryo transfer (FET), fresh-embryo transfer (fresh ET) and naturally conceived (NC) to investigate maternal cardiometabolic profiles, fetal growth patterns and placental function during pregnancy as well as metabolic and endocrine health in the offspring. Additionally, the aim is to explore genetic and epigenetic patterns in placenta, fetus and parents. As secondary objectives, the investigator group will examine telomere length and minipuberty hormones in children born after FET, fresh-ET and NC.

Background and research gap: Increasing use of assisted reproductive technology (ART) necessitates vigilance on the health of the offspring. The use of frozen embryo transfer (FET) in ART increases the risk of the children being born large-for-gestational-age (LGA) compared to conventional fresh embryo transfer (fresh ET) and naturally conceived children (NC). In general, children born LGA are predisposed to childhood obesity and later metabolic syndrome, thus FET may increase the societal burden of this. The mechanism between FET and LGA is unclear and its impact on neonatal body composition and metabolic health is unknown. Hypothesis and objectives: The growth hormone (GH) - insulin-like growth factor (IGF) axis plays an essential role in fetal growth and is also linked to metabolic disease due to its interactions with insulin. Thus, the investigator group hypothesize that FET imposes epigenetic alterations towards the GH-IGF-axis leading to enhanced fetal growth and a potential persisting phenotype of metabolic dysfunction. The objective is to determine the effect of endocrine growth factors, maternal metabolic profile, and placental function on intrauterine growth patterns as well as early postnatal body composition and metabolic profile in children born after ART with FET compared to children born after fresh ET and NC children. Methods and outcomes: The investigator group will conduct a prospective cohort study including women pregnant by FET (N=200), fresh ET (N=200) and NC children (N=200). The women will undergo three examinations during pregnancy with blood sampling (analyzed for GH-IGF-related growth factors and metabolic biomarkers), fetal biometry and doppler ultrasound. For a subpopulation the placenta will be collected at delivery. The expression of placental growth factors will be determined using western blot and qPCR and epigenetic alterations assessed by DNA methylation using targeted CpG arrays. The newborns will be examined within two weeks of birth with blood samples (analyzed for growth factors, glucose-metabolism markers, lipids, and cytokines) and a DEXA-scan to evaluate body composition. Information on ART-procedure, obstetric adverse events, birth weight and neonatal complications will be available from electronic health records. The outcomes are grouped in three work packages comparing the differences between FET, fresh ET, and NC in 1) maternal growth factors and metabolic profile and the relationship with fetal growth trajectories, 2) expression and DNA methylation of GH-IGF-axis components in placental tissue, 3) body composition, metabolic profile and DNA methylation of regions related to the GH-IGF axis in neonates. Significance: It is crucial to understand the mechanism between FET and LGA and its impact on metabolic health in children in order to determine the safest ART technique. The investigator group expect that the results will identify the role of the GH-IGF axis in the pathogenesis of FET-induced LGA and its associated metabolic risk which may highlight potential biomarkers of abnormal fetal growth and therapeutic targets for prevention of obesity and metabolic diseases.