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NCT06957769
The goal of this study is to learn how being exposed to high environmental temperatures during pregnancy affects the health of pregnant women and their babies. The study also aims to understand how the body responds to heat stress during pregnancy and how this might lead to pregnancy complications and birth problems like early birth or low birth weight. The main questions that the study aims to answer are: 1. What are the acute and chronic effects of environmental heat exposure on pregnancy and birth outcomes across different trimesters? 2. Through which biological pathways does heat stress impact maternal, fetal, and infant health across varying gestational ages? 3. How do socio-demographic factors, maternal characteristics, and nutritional status of women modify the relationship between environmental heat exposure and adverse pregnancy outcomes? The study will take place in rural parts of Sindh, Pakistan. These areas often experience extreme heat and have limited access to electricity or cooling systems like fans or air conditioners. This study will include pregnant women who are in their first trimester (under 14 weeks of pregnancy). Before starting any study activities, researchers will explain the study to each woman in a language she understands and ask for her written permission to take part (informed consent). At the beginning of the study, participants will visit a study clinic. During this visit, researchers will check their height and weight, perform an ultrasound, and collect a small amount of blood for testing. Participants will also be asked to wear a small device that measures the air temperature and humidity in their surroundings. The researchers will follow each participant during her pregnancy, with visits during the second and third trimesters at the study clinic. At each visit, researchers will check how much heat the participant has been exposed to using the data from the device and from her own answers to a simple questionnaire. The questionnaire will have questions about their heat exposure at work, home, type of clothing, and how they deal with hot weather. Serial ultrasound, blood and urine tests will be conducted so researchers can study signs of stress, hydration, and other changes in the body. A smaller group of participants will also wear a device to measure their body skin temperature, heart rate, physical activity and sleep during pregnancy. When the baby is born, researchers will collect information about the birth, including the baby's weight and length, the time of delivery, and whether there were any complications during birth. After delivery, both the mother and baby will be followed for up to 12 months. During this time, the research team will check the health of both the mother and baby and see how heat exposure during pregnancy may affect the baby's growth over time. At delivery, placental weight and volume will be collected for a smaller group of women. Breastmilk sampling will also be done for this group of women to understand the effect of high temperatures on breastmilk quality. This study does not involve any treatment or medicine. Instead, researchers will observe the participants to learn how real-life heat exposure affects them during pregnancy. The findings from this study may help public health officials and governments find better ways to protect pregnant women and babies from the harmful effects of climate change and extreme heat, especially in places with limited resources.
NCT06870318
Research has shown that provision of mother's milk is the optimal way to feed very low birthweight (VLBW) infants. Many infants will require a supplement to mother's milk, pasteurized donor human milk (PDHM) compared to preterm formula is the most appropriate supplement as it has been shown to reduce the risk of necrotizing enterocolitis (NEC). Most available evidence suggests neither mother's milk nor PDHM will meet the elevated nutritional requirements of VLBW infants without multi-nutrient fortification. Globally, the current standard of care is to use bovine protein-based nutrient fortifiers to meet these elevated nutrient requirements. Given the known benefits of mother's milk, the reduction in the risk of NEC with use of PDHM as a supplement, and the availability of human milk-based multi-nutrient fortifiers (HMBF), there has been considerable interest in the efficacy of HMBF over the less costly bovine milk-based fortifiers (BMBF). This study is an analysis of individual participant data merged from randomized control trials that examined the efficacy of HMBF compared to BMBF during hospitalization, on the risk of death and severe morbidity or major feeding interruption. Participants of the trials included in the analyses were fed exclusively with human milk or a supplement of pasteurized donor human milk (PDHM). Only two RCTs met this criteria -OptiMoM and the N-forte trial. In both studies the intervention aligned to commence upon randomization into the HMBF or BMBF groups. The difference between the OptiMoM and N-forte feeding protocols was that the later allowed for individualized fortification based on milk analysis whereas OptiMoM used standard fortification, predominant in Canada and globally. For OptiMoM, the feeding intervention continued until infants were 84 days of age, discharge, or when the infant consumed ≥2 complete oral feeds daily. For N-forte trial, the feeding intervention ended when babies reached 34 weeks (zero days). Both studies followed participants and continued data collection if transferred to a level II NICU for convalescence (OptiMoM) or home care service followed closely by NICU nurses (N-forte) until discharge.
NCT06870981
Early nutrition critically influences growth, neurodevelopment and morbidity among infants born of very low birth weight (VLBW), but current one-size-fits-all feeding regimes do not optimally support these vulnerable infants. There is increasing interest in "precision nutrition" approaches, but it is unclear which Human Milk (HM) components require personalized adjustment of doses. Previous efforts have focused on macronutrients, but HM also contains essential micronutrients as well as non-nutrient bioactive components that shape the gut microbiome. Further, it is unclear if or how parental factors (e.g. body mass index, diet) and infant factors (e.g. genetics, gut microbiota, sex, acuity) influence relationships between early nutrition and growth, neurodevelopment and morbidity. Understanding these complex relationships is paramount to developing effective personalized HM feeding strategies for VLBW infants. This is the overarching goal of the proposed Optimizing Nutrition and Milk (Opti-NuM) Project. The Opti-NuM Project brings together two established research platforms with complementary expertise and resources: 1) the MaxiMoM Program\* with its clinically embedded translational neonatal feeding trial network in Toronto (Dr. Deborah O'Connor, Dr. Sharon Unger) and 2) the International Milk Composition (IMiC) Consortium, a world-renowned multidisciplinary network of HM researchers and data scientists collaborating to understand how the myriad of HM components contribute "as a whole" to infant growth and development, using systems biology and machine learning approaches. Members of the IMiC Corsortium that will work with on this study are located at the University of Manitoba (Dr. Meghan Azad), University of California (Dr. Lars Bode) and Stanford (Dr. Nima Aghaeepour).
NCT02817022
Enrolled neonates will be provided routine supportive care as per existing neonatal intensive care unit (NICU)protocols. This will be carried out in the initial 6 months (0-180 days) of study commencement. This group will serve as control group (group A). During subsequent 6 months (181-360 days) of the study period, enrolled neonates fulfilling the inclusion criteria will be provided routine supportive care and the components of developmentally supportive care (DSC).