View clinical trials related to Apnea of Newborn.
Filter by:In the past many neonates with respiratory distress syndrome would require intubation, but over the years these rates have declined as the capabilities of non-invasive ventilation (NIV) have vastly improved. Despite these improvements, the decrease in pressure transmission due to factors such as resistance from tubing or air leaks around the nostrils and mouth, continues to be one of the major drawbacks when using nasal NIV. Current ventilators measure the set pressures at the circuit but do not capture the delivered pressure at the patient's nares. Recently, Medtronic PB980 ventilators feature NIV plus and leak sync software that can be calibrated to measure the pressures provided at the nostrils. Optimum pressures received at the nostrils to provide safe and effective therapy in neonates is currently unknown. In the prospective portion of the study, we aim to evaluate safety and efficacy of the software by comparing the average pressure difference between the circuit and delivery pressure at the nares, the incidence of apnea, bradycardia, desaturations as well as escalation and de-escalation of ventilator support in newborns who are receiving NIV admitted to NICU
Tracheal intubation remains a common procedure in the neonatal intensive care unit (NICU) and the delivery room (DR). Current guidelines recommend Estimation of correct endotracheal tube (ETT) insertion Our hospital policy recommends to estimate the correct depth (cm) of tube placement by measuring the nasal-ear-tragus length using the "7-8-9 rule" when the endotracheal tube is placed orally. Using this formula an infant weighing 1kg would be intubated to a depth of 7cm, a 2kg infant to a depth of 8cm, and a 3kg infant to a depth of 9cm from the upper lip. With the new 2015 guidelines, ETT depth is determined by measuring the newborn's nasal septum-tragus length (NTL) and adding 1cm or by using the "initial endotracheal tube insertion depth" table. The NTL is described as the distance from the base of the nasal septum to the tragus of the ear. However, studies using NTL reported that using this technique only resulted in correct ETT placement in 56% of cases. Every ETT has markings on the tube, which are called vocal cord markings, which are to be used to provide a guidance to how deep to place the ETT into the trachea. There has been npc study to compare the vocal cord markings with the current approach of NTL. The current study aims to determine if the use of vocal cord markings during intubation increases percentage of correct endotracheal tube placement compared to NTL in preterm and term infants.
The study will be conducted in a convenience sample of 75 infants admitted to the NICU at the Montreal Children's Hospital, divided into 3 phases: (a) Phase 1a - monitoring for 8h per day for 4 consecutive days, (b) Phase 1b - monitoring between 2h to 8h per day for 2 to 4 consecutive days, and (c) Phase 2- monitoring for 96h continuously. Study objectives include: 1. Demonstrate the feasibility of continuous wireless monitoring in term and preterm infants with variable degrees of maturation and acuity in the NICU. 2. Assess safety of using a special wireless sensor system in neonates. 3. Evaluate the accuracy of proposed wireless technology as compared to standard monitoring technology in the NICU.
Pilot study of 10 preterm, who are going to be randomly placed to 3 phases : 2 hour of basal observation of respiratory rate, heart rate, saturation, NIPS and aEEG recording, 2 hours with a 20cycles/minute with "scare ventilator", and 2 hours of 40 cycles/minute with "scare ventilator"
Purpose of Study: Apnoea of Prematurity (AOP) is common, affecting the majority of infants born <34 weeks gestational age (GA). Apnea is accompanied by intermittent hypoxia (IH), which contributes to multiple pathologies, including retinopathy of prematurity (ROP), sympathetic ganglia injury, impaired pancreatic islet cell and bone development, and neurodevelopmental disabilities. Standard of care for AOP/IH includes prone positioning, positive pressure ventilation, and caffeine therapy. The objective of this device is to provide an adjunct to current AoP treatment to support breathing in premature infants by using a simple, non-invasive vibratory device placed over limb proprioceptor fibers, an intervention using the principle that limb movements facilitate breathing. Methods Used: Premature infants (27+6 - 34+6 weeks GA) with clinical confirmed weeks with diagnosis of Apnoea of Prematurity. Caffeine therapy was not a reason for exclusion. Small vibration devices were placed on one hand and one foot and activated in a 6 hour ON/OFF sequence for a total of 24 hours. Heart rate, respiratory rate, oxygen saturation (SpO2), and breathing pauses were continuously collected.