Active clinical trials for "Fetal Growth Retardation"

The objective of this project is the non-invasive prenatal detection of placenta-limited aneuploidies, in patients whose fetuses have a intrauterine growth restriction below 3rd percentile, in parallel with an amniocentesis. This study will allow the chromosomal study of the placenta in pregnant women whose genetic prenatal diagnosis, made by amniocentesis, does not allow exploring the placental causes of fetal RCIU.

Intrauterine growth restriction (IUGR) is caused when the placenta cannot provide enough nutrients to allow normal growth of the fetus during pregnancy. It is unclear why IUGR happens, but an increase in inflammatory T cells in the placenta known as villitis of unknown etiology (VUE) is observed in many IUGR infants. The investigators aim to develop ultrasound methods for diagnosing VUE to understand it's role in IUGR.

Comparison of prenatal and postnatal cardiac function assessed by echocardiography using pulsed wave Doppler, Tissue Doppler and speckle tracking (strain and strain rate) between foetuses/neonates with a structural heart disease, with an fetal growth restriction (FGR) and healthy fetuses/neonates.

This study aims to establish a multicenter cohort of FGR high-risk pregnant women, and aims to construct a combined predictive model for FGR by combining basic characteristics, medical history, early pregnancy ultrasound, and biomarkers.

The ultimate goal of this project is to develop methods that allow informed decision-making on the delivery time of fetuses that are at increased risk of stillbirth due to IUGR. In placenta related IUGR pregnancies, there can be multiple concurrent placental pathologies. Although there is no specific correspondence between a single type of pathology and IUGR, the common result of these pathologies is placental insufficiency, which limits the maternal-fetal exchange. Oxygen and nutrition transport is known to be hindered in IUGR placentas due to obstructed or abrupt vasculature, massive fibrin deposition, and inflammation in the villous and intervillous space (villitis). Thus one potential approach to distinguish IUGR pregnancies from normal ones is to assess the efficiency of placental transport. Based on the hypothesis that efficiency of oxygen transport is representative for overall oxygen and nutrition transport in placenta, the investigators propose to characterize the blood oxygenation and blood perfusion in placenta in vivo via MRI, and use it as an index for better stratification in the IUGR risk group. The investigators will also consider alternative MRI approaches such as structural, diffusion and spectroscopy measurements inside the placenta, which might reflect the state of placental transport and reveal the status of placental health. Specific aims: 1) To correlate the MRI metrics that differentiate placental insufficiency from normal placenta transport with histopathology data of the placenta. 2) To correlate the MRI metrics that reflects placental insufficiency with fetal outcome

The investigation will employ a longitudinal approach in which every fetus diagnosed to be SGA (Small for Gestational Age ) will be studied at frequent intervals with sophisticated imaging techniques to assess subtle physiologic changes in the brain, heart, and placenta over time. These findings will be correlated with neurological and cardiovascular function in the newborn and early childhood. This research initiative should yield diagnostic and therapeutic templates that will improve the quality of life of IUGR babies in addition to providing important information that will better inform current diagnostic practices.

The aim of this observational study is to optimize the timing of antenatal corticosteroids administered to patients with pregnancies complicated by early-onset fetal growth restriction in order to reduce neonatal morbidity and mortality. In the Netherlands two main timing strategies of antenatal corticosteroids are commonly practiced. In this study the investigators will compare these two timing strategies regarding CCS administration in early-onset FGR on the combined endpoint of perinatal, neonatal and in-hospital mortality. In addition, the investigators aim to develop a dynamic, prediction tool, a novel technique in prediction research to predict the time-interval in days until delivery within this population. With that, the investigators aim to reduce neonatal morbidity and mortality for future FGR pregnancies.

Background: Congenital heart disease (CHD) is the most frequent inborn defect with an incidence of 1 in 100 newborns per year, i.e. 800 children born in Switzerland per year. 10% to 15% of cases are born with single ventricle (SV), the most complex type of CHF requiring immediate surgical intervention after birth. Infants with SV CHD are treated in three surgical staged procedures over the first three years of life. However, cerebral injuries occur in around 40% of those children and impact neurocognitive abilities. As more than 90% of all infants with CHD survive to adulthood, scientific concern is focussed on patient-individual course brain growth and development within the relative contribution of fetal, perinatal, cardiac and surgical risk factors. Therefore, serial cerebral MRI examinations are needed, starting (1) at the third trimester during fetal life proceeding to (2) pre- and postoperative time points at the stage I surgery after birth and (3) before stage II surgery at 4 months of age. We will compare the cerebral MRI findings with a healthy control population, recruited at the same time points, and correlate brain growth and development with the neurodevelopmental outcome assessed at one year of age. Three Pediatric Heart Centers in Switzerland and Germany will participate. The overall aims are: To analyse the patient-individual cerebral developmental trajectories, brain growth and determine the time course of brain abnormalities in infants with single ventricle CHD by serial cerebral MRI during fetal life, after birth and at an age of 4 months (primary endpoints). To determine the neurodevelopmental outcome at one year of age using the Bayley III and will be correlated with the brain growth and brain development in the third trimester of fetal life and at the age of 4 months (secondary endpoints). To analyse fetal, neonatal, surgery-related and intensive care associated factors determining the patient-individual course for altered cerebral growth and impaired neurodevelopmental outcome at one year of age. Methodology: We will prospectively enroll fetuses and neonates with single ventricle CHD at the three Pediatric Heart Centers in Switzerland (Zurich, Bern) and Germany (Giessen). Advanced MR imaging will assess cerebral volumes, microstructural and hemodynamic changes at repeated time points during the third trimester of fetal life (32. week of gestation), the perioperative neonatal period before and after stage I surgery and before stage II surgery at 4 months of age. Biomechanical analysis of longitudinal changes of brain morphology will be applied to longitudinal fetal and neonatal MRI data. Outcome is determined with the Bayley-III at one year of age. Significance: Using a population-based sample of children with single ventricle CHD, we will be able to determine cerebral growth from the third fetal trimester until the first 4 months after birth, when the brain is most rapidly growing. By performing serial brain imaging, the knowledge of etiological pattern affecting cerebral growth, development and brain injury will increase. Morphometric and biomechanical analysis of brain growth patterns will be performed that may capture fine-grained changes associated with CHD. By correlating these data with the neurodevelopmental outcome at one year of age it will be possible to identify specific risk constellations leading to impaired brain development and categories of brain injuries that confer a higher risk of adverse outcome. The better understanding of the pathophysiological mechanisms will serve as the basis for neuroprotective studies and pharmacological trials aiming to improve outcomes in children with CHD in the future.

The molecular mechanisms underlying developmental programming of childhood obesity remain poorly understood. Here, the investigators address major questions about early childhood obesity programming by studying CD3+ T-cells from intrauterine growth restricted (IUGR) newborns who have an increased risk for obesity and other metabolic disorders in adult life.

In this project there are 2 time points during the pregnancy included, namely at 21 weeks and 30 weeks of gestation, to measure the predictive values of FGR, strain and strain rate. The fetal growth parameters will be collected at the same time points, to define the growth (differences) throughout gestation of both fetuses. A maternal blood sample will be taken at 21 weeks of gestation to identify the level of exposure to air pollution (black carbon) and the level of biochemical markers of placental dysfunction. Doppler ultrasounds will be used for antenatal identification of placenta insufficiency. At birth, umbilical cord blood and the placenta will be collected. The placenta will be examined, to identify morphological findings which are associated with FGR. The umbilical cord blood and placental biopsy will be used for the level of exposure to air pollution and the level of oxidative stress. One to three days after birth, neonatal strain and strain rate will be measured to define postnatal cardiac remodeling as well as the neonatal blood pressure as cardiovascular risk factor.