View clinical trials related to Infant, Newborn, Diseases.
Filter by:The goal of this study is to determine if using a Pedi-Cap (a type of colorimetric carbon dioxide detector) during face mask ventilation (PPV) for newborn infants in the delivery room will lower the time of PPV needed. A group of nurses, doctors, and respiratory therapists, called the neonatal resuscitation team, will either use or not use the Pedi-Cap during face mask PPV for infants born at ≥30 weeks' gestation. A randomization generator will assign each month either using the Pedi-Cap or not using the Pedi-Cap. The researchers will collect information from the chart to find the infant and mother's information, vital signs, medical interventions done in the delivery room, and lab values. In addition, resuscitation team members will fill out a survey of their experiences of using or not using the Pedi-Cap during delivery room PPV.
1. Explore 32 weeks of premature infants or maternal pregnancy infection of newborn septic shock maternal influence factors. 2. Through maternal blood samples before delivery and labor cord blood sample screening and septic shock related proteomics analysis, explore the relationship between the difference protein and septic shock and prognosis, and explore the pathway mechanism, in order to prevent and reduce the occurrence of septic shock in premature infants
The goal of this study is to perform a quality control assessment of our local intubation protocol in any newborn infant requiring endotracheal intubation in the delivery room or neonatal intensive care unit at the Department of Neonatology of the University Hospital Zurich. The primary aims are: - Successful nasal intubation at the first attempt without physiological instability. - Comparison of infants with successful intubation at the first attempt without physiological instability to the infants in the SHINE-Trial in Australia. Participants will be intubated according to our standard intubation procedure using non-invasive ventilation (NIV) delivered through a nasopharyngeal tube.
REAL-MOXY is a set of 5 mixed methods studies designed to understand how oxygen and pulse oximetry are used (or not used) at a facility level, to identify opportunities and barriers for strengthening oxygen systems for beneficiaries, users and managers.
The transition from fetus to newborn is a complex physiological process. Monitoring this process to detect potential disruptions is critical but remains a challenge. Initial evaluation of neonates is usually based on visual inspection, palpation and/or auscultation, and response to stimuli. To objectify the condition of the newborn during this vulnerable transitional period, Virginia Apgar developed a clinical assessment-based scoring system called the Apgar Score, which is widely used around the world. However, there is significant inter-observer and intra-observer variability in clinical assessments using the Apgar score. To objectively assess the condition of the newborn, the latest guidelines for postnatal adaptation and resuscitation recommend the use of electrocardiography (ECG) and pulse oximetry in the delivery room in addition to clinical evaluation. These monitoring methods allow non-invasive continuous monitoring of SpO2 (Oxygen saturation) as well as heart rate (HR), but do not provide information about potentially compromised cardiovascular status, resulting in severely restricted oxygen transport to tissues. Cerebral Oxygenation: The brain is one of the most vulnerable organs to hypoxia during the postnatal adaptation period. The recommended routine monitoring during the neonatal transition is SpO2 and heart rate. Unfortunately, these parameters do not provide any information about cerebral blood flow or oxygen supply or brain activity. About 30% of premature babies develop cerebral hemorrhage in the first 3 days after birth. This can lead to the development of hydrocephalus, poor neurological outcome and even death. For the above reasons, there is increasing interest in additional brain monitoring. Our research group has already shown in various studies that additional cerebral monitoring using near-infrared spectroscopy (NIRS) is possible in newborns immediately after birth and may be beneficial during this vulnerable phase of life. Furthermore, this add-on monitoring could inform interventions to optimize brain oxygenation, potentially affecting survival with improved short- and long-term neurological outcomes. Background: The transition from fetus to newborn is a complex physiological process. Monitoring this process to detect potential disruptions is critical but remains a challenge. Initial evaluation of neonates is usually based on visual inspection, palpation and/or auscultation, and response to stimuli. To objectify the condition of the newborn during this vulnerable transitional period, Virginia Apgar developed a clinical assessment-based scoring system called the Apgar Score, which is widely used around the world. However, there is significant inter-observer and intra-observer variability in clinical assessments using the Apgar score. To objectively assess the condition of the newborn, the latest guidelines for postnatal adaptation and resuscitation recommend the use of electrocardiography (ECG) and pulse oximetry in the delivery room in addition to clinical evaluation. These monitoring methods allow non-invasive continuous monitoring of SpO2 as well as HR, but do not provide information about potentially compromised cardiovascular status, resulting in severely restricted oxygen transport to tissues. Pulsatile mode of NIRS Recently, Hamamatsu developed new software and implemented it as a pulsatile mode in one of their near-infrared spectroscopy (NIRS) instruments, the NIRO 200 NX. In contrast to the conventional NIRS technique, which measures tissue saturation closer to venous oxygen saturation than arterial oxygen saturation, the pulsatile NIRS technique uses a higher measurement rate of 20 Hertz and can therefore measure cerebral pulse rate (cPR) and cerebral arterial oxygen saturation (SnO2) in small vessels. Using the non-invasive pulsatile NIRS technique could be a viable new method to continuously monitor blood flow to the brain during resuscitation. This can be particularly beneficial for critically ill newborns and premature babies. To date, no data have been published in neonates using the pulsatile NIRS technique.
About 10 per cent of all new born babies in Sweden have infant colic. This may affect the the whole family and the early connection between the baby and the parents. Although, there are no effective and safe treatment. Acupuncture is an environmental friendly method that affects pain, anxiety, sleep and the function of gastrointestinal system. Several studies have shown various results, and there are a need for high-qualitative randomised controlled trials to investigate the proposed effect further. 128 children will be randomised into two groups; acupuncture at LI4 or no acupuncture, parents will be blinded. Statistical calculations will be performed on the content of the diaries (bowel movement frequency, crying time, feeding). Registration of crying/crying in connection with acupuncture treatment, i.e. when the needle touches the skin or later until the needle is removed and 30 seconds after.
Study outcomes and endpoints: - Primary outcome: to assess clinical characteristics of infants with confirmed COVID-19 infection at birth and to evaluate long-term respiratory consequences of neonatal COVID-19 infection. - Secondary outcome: to evaluate the prevalence and natural history of lung function impairment among infants with confirmed COVID-19 compared to infants with no history of COVID-19. To this end, infants will undergo pulmonary function testing (PFT) with the Exhalyzer D device (Eco Medics, Switzerland).
The aim of this study is to evaluate the impact of virtual family-centered rounds in the neonatal intensive care unit on parental and neonatal outcomes.
Ventilated newborns frequently need supplemental oxygen but its use must be monitored carefully as both giving too much or too little oxygen can have harmful effects. Giving too little oxygen results to low oxygen levels (hypoxia) and increases the risk of complications and mortality. Excessive oxygen delivery (hyperoxia) increases the risk of diseases involving several organs such as the retinas and the lungs. Although infants born very preterm require support with their breathing more often, more mature neonates may also need to be ventilated at birth and to receive supplemental oxygen. Therefore, they may suffer from problems related to hypoxia and hyperoxia. For the above reasons, oxygen levels are continuously monitored and the amount of oxygen provided is manually adjusted by the nurses and doctors. Closed-loop automated oxygen control systems (CLAC) are a more recent approach that involves the use of a computer software added to the ventilator. This software allows for automatic adjustment of the amount of oxygen provided to the baby in order to maintain oxygen levels within a desired target range depending on the baby's age and clinical condition. Previous studies in preterm and very small infants showed that automated oxygen control systems provided the right amount of oxygen for most of the time and prevented hypoxia and hyperoxia with fewer manual adjustments required by clinical staff. Preliminary results from a study that included infants born at 34 weeks gestation and beyond showed that CLAC systems allowed to reduce the amount of supplementary oxygen more rapidly. With this study we aim to compare the time spent in hyperoxia and the overall duration of oxygen treatment between infants whose oxygen is adjusted either manually or automatically while they remain ventilated. This will help us understand if CLAC systems help reduce the complications related to oxygen treatment.
A randomized controlled trial comparing Noninvasive high frequency oscillatory ventilation (NHFOV) and Noninvasive positive pressure ventilation (NIPPV) as post-extubation respiratory support in preterm neonates with respiratory distress syndrome(RDS)