View clinical trials related to Intrauterine Growth Restriction.
Filter by:The goal of this clinical trial is to learn more about how the food and nutrition babies receive while in the Neonatal Intensive Care Unit (NICU) influences their ability to gain weight and fat-free mass, and their future growth and development. Participants will: - have body growth measurements collected using the PEAPOD device - have nutritional information collected, and - be followed for neurodevelopmental outcomes Participants can expect to be in the study for 36 months.
Previous studies have shown that abnormal coiling of the umbilical cord is associated with adverse perinatal outcome. For example, an umbilical cord that is non-coiled increases the chance of fetal morbidity and mortality, moreover, they have shown that the lack of the usual coiled umbilical cord configuration may result in an umbilical cord that is structurally less able to withstand external mechanical stress, on the other hand, studies from recent years show that hypercoiling - excessive coiling of the umbilical cord is associated with poor obstetric outcomes, such as fetal distress at birth, meconium staining, fetal acidosis, premature birth, intrauterine growth disorder and even fetal death. The studies carried out on the calculation of UCI include performing these measurements in two dimensions, including Doppler activation, but no studies were carried out in which three dimensions were used. The purpose of the study is to measure UCI using a 3D method in a random sample of 250 patients beyond 24 week of gestation, and to compare pregnancies with hypercoiling, hypocoiling or with a normal number of coils in terms of birth outcomes.
The purpose of this study is to determine the impact of a clinical screening strategy and genomic analysis of the factors involved in Placental Dysfunction (Preeclampsia and IUGR) in women of advanced maternal age undergoing assisted reproduction techniques (ART), specifically, in vitro fertilization (IVF) and oocyte donation.
Intrauterine growth restriction (IUGR) is defined as a velocity of fetal growth less than the normal fetus growth potential for a specific neonate as per the race and gender. These neonates face many acute problems during peripartum and after birth .The causes of IUGR may be maternal, placental, fetal or genetic and also due to combination of any of these factors. Knowledge of etiologies of fetal growth restriction (FGR) is essential, so that future care can be targeted at prevention . It is apparent that FGR is primarily caused by placental dysfunction (PIH&PE), insufficiency that lead to reduced fetal growth overall. FGR is associated with lifelong burden of chronic diseases including metabolic, respiratory, cardiovascular and neurological deficits. Pre-eclampsia (PE) is diagnosed by the combined presentation of high blood pressure and proteinuria. New definitions also include maternal organ dysfunction, such as renal, liver, neurological or haematological complications, uteroplacental dysfunction, or FGR . In an attempt to correct fetus reduced supply the placenta release various cytokines and markers as Alpha-1 anti-trypsin (AAT). The Golgi apparatus secretes this cytokine in placental cytotrophoblast and blood vessels. AAT is antinflammatory antiprotease protective molecule. AAT rises during normal pregnancy. The suboptimal rise of AAT in pregnancy are liable for increased obstetrical complications like abortion, preterm labor. AAT levels were found decreased in placenta tissues from women with PE compared that of healthy women. Although AAT deficiency is associated with several pregnancy and placental disorders, little is known regarding AAT levels and PE .
In case of fetal weight below the 10th centile for gestational age, it is important to distinguish SGA and IUGR. SGA is defined as a fetal weight below the 10th centile. IUGR correspond to a pathologic reduction of growth velocity and it is a major determinant of perinatal mortality and morbidity. Even if SGA have long time been considered to be constitutionally small without adverse outcomes, recent evidence has demonstrated that a proportion of SGA, with normal UA Doppler, could be associated with neonatal adverse outcomes, probably related to a late-onset IUGR. Therefore, it seems essential to differentiate several categories of fetuses presenting abnormal fetal weight or intrauterine growth: fetuses SGA without any Doppler abnormalities, fetuses affected by early or late-IUGR. In case of late-IUGR, an important part of these fetuses is initially considered as PAG with a normal umbilical Doppler. In case of fetal weight below the 10th centile for gestational age, longitudinal assessment of the fetal weight and umbilical artery (UA) Doppler is recommended. In case of abnormal UA Doppler, Middle Cerebral Artery (MCA) Doppler is recommended to research a "brain-sparing" effect. If UA and MCA Doppler findings seem to become abnormal in the early stages of IUGR, Ductus Venosus (DV) flow abnormalities have been described as a late marker of fetal decompensation related to an acute myocardial impaired relaxation and acidemia which is a major contributor to adverse perinatal outcome and neurological. The aortic isthmus (AoI) Doppler is an indicator of the progression of fetal hemodynamic deterioration in IUGR and recent data confirm that AoI and DV abnormalities are correlated but AoI Doppler abnormalities would occur earlier than DV Doppler. AoI Doppler could identify abnormalities suggestive of right ventricular dysfunction before DV Doppler and anticipate obstetrical management. In conclusion, Doppler examination could not be reduced to UA Doppler in case of SGA and IUGR and require a global examination including MCA and probably DV and AoI Doppler. That's why fetal growth assessment should not be limited to fetal biometry and umbilical artery Doppler. Thanks to a systematic protocol for Doppler examination based on UA, MCA, DV and Aortic Isthmus (AoI) Doppler, we hope identify these hemodynamic variations in a large cohort of fetuses <10 to improve prenatal assessment of these foetus to and perinatal outcomes, reducing perinatal morbi-mortality.
Intrauterine growth restriction (IUGR) is defined as fetal abdominal circumference (AC) or estimated fetal weight (EFW) < 10th centile. In asymmetrical IUGR the parameter classically affected is the abdominal circumference (AC). Fetal growth restriction (FGR) complicates approximately 0.4% of pregnancies and severely increases the risk of perinatal morbidity and mortality. This is particularly due to premature delivery, both for fetal and for secondary maternal indications such as the development of pre-eclampsia. Consequence of deficient uteroplacental blood flow, including IUGR, pre-eclampsia, and placental abruption have been implicated in more than 50% of iatrogenic premature births. For this reason, the problem of severe IUGR forms a substantial portion of the population that tertiary care centres care for. The effect of early-onset IUGR is particularly significant: of those born alive, less than a third will survive their neonatal intensive care unit (NICU) stay without significant neurodevelopmental sequelae. Survival rates for severely growth-restricted fetuses very remote from term (<28 weeks' gestation) vary from 7% to 33%. As these early-onset IUGR children are born very preterm, there are significant risks of neonatal mortality, major and minor morbidity, and long-term health sequelae. The use of ultrasound Doppler waveform analysis in pregnancies complicated by IUGR suggests compromised uteroplacental circulation and placental hypoperfusion. Currently there are no specific evidence-based therapies for placental insufficiency and severe IUGR. Non-specific interventions include primarily lifestyle modifications, such as reducing or stopping work, stopping aerobic exercise, rest at home, and hospital admission for rest and surveillance. These interventions, which are not supported by evidence from randomized trials, are used in the belief that rest will enhance the uteroplacental circulation at the expense of that to the glutei and quadriceps muscles. There is evidence from ex vivo and animal models of growth restriction that the phosphodiesterase 5 inhibitor sildenafil citrate increases average birth weight and improves uteroplacental blood flow (umbilical artery, uterine artery).