View clinical trials related to Respiratory Insufficiency.
Filter by:The study was a retrospective observational cohort where patient medical record review was done and data were gathered on 419 cases. The ICU admission pattern and patient outcome were the primary outcomes presented in the manuscript.
The study is aimed at the clinical and laboratory characteristics of patients with completed vaccination against SARS-CoV-2 admitted to the hospital in the standard ward and intensive care unit due to the severe course of COVID-19.
The study will be a multicenter, multinational, prospective single arm blinded non-interventional follow-up study (from DXT-CS-005) to validate RESPINOR DXT's performance to identify patients at increased risk of weaning failure during the spontaneous breathing trial (SBT). Continuous diaphragmatic excursion measurements by RESPINOR DXT will be conducted during the patients' first SBT. The recording shall be initiated 15 minutes prior to the first SBT and will end 15 minutes post SBT. All patients on mechanical ventilation in the ICU meeting the eligibility criteria shall undergo a daily screen for weaning readiness. If any of the components of the daily screen is not met, the patient will not undergo a SBT that day and continued to be screened daily. Patients passing daily screening criteria shall automatically receive an SBT. The SBT shall last for 30-120 minutes and be performed on continuous positive airway pressure up to 5 cm H2O and pressure support up to 7 cm H2O. The SBT shall be terminated, and mechanical ventilation reinstituted at the original settings if the patient meets any of the SBT failure criteria. A trial is considered successful, and physicians will be asked to approve extubation when the patient can breathe spontaneously for the whole trial. As part of the clinical investigation, patients shall be continued to be screened daily until extubation, 21 days after enrollment, the performance of tracheostomy, death, or withdrawal of care. All patients shall be followed until hospital discharge or death.
Detection and relief of dyspnea in mechanically ventilated patients is a priority. Optimization of mechanical ventilation settings is unfortunately often insufficient to relieve dyspnea in patients entering the weaning process. Pharmacological treatments are effective but their use is likely to delay separation with the ventilator. Promoting the development of non-pharmacological interventions is therefore an interesting avenue. The hypothesis is that the application of high-flow humidified nasal air in orotracheally intubated patients can decrease the work of breathing and relieve dyspnea at the time of weaning from mechanical ventilation. Patients will be exposed to stepwise increase in high flow nasal air (0 L/min, 30 L/min, 50 L/min and 70 L/min) before to undergo a 60 minutes spontaneous breathing trial. During the protocol, dyspnea, inspiratory effort, respiratory drive, respiratory muscles electromyogram (EMG) and patient's comfort will be assessed.
Landmark trials in critical care have demonstrated that, among critically ill adults receiving invasive mechanical ventilation, the use of low tidal volumes and low airway pressures prevents lung injury and improves patient outcomes. Limited evidence, however, informs the best method of mechanical ventilation to achieve these targets. To provide mechanical ventilation, clinicians must choose between modes of ventilation that directly control tidal volumes ("volume control"), modes that directly control the inspiratory airway pressure ("pressure control"), and modes that are hybrids ("adaptive pressure control"). Whether the choice of the mode used to target low tidal volumes and low inspiratory plateau pressures affects clinical outcomes for critically ill adults receiving mechanical ventilation is unknown. All three modes of mechanical ventilation are commonly used in clinical practice. A large, multicenter randomized trial comparing available modes of mechanical ventilation is needed to understand the effect of each mode on clinical outcomes. The investigators propose a 9-month cluster-randomized cluster-crossover pilot trial evaluating the feasibility of comparing three modes (volume control, pressure control, and adaptive pressure control) for mechanically ventilated ICU patients with regard to the outcome of days alive and free of invasive mechanical ventilation.
Rhomboid intercostal block is used to block lateral cutaneous branches of intercostal nerves between T3 and T9 dermatomes. Serratus anterior plane block is used to block lateral cutaneous branches of intercostal nerves between T2 and T6, in addition, it is also known to block thoracodorsal nerve and long thoracic nerve. Both of the blocks are usually performed for postoperative analgesia following breast surgery. The primary hypothesis of the study is that FEV1 value of the patients who will receive modified radical mastectomy (MRM) and rhomboid intercostal plane (RIP) block combined with serratus anterior plane (SAP) will be higher than FEV1 value of the patients in the no-block group. The secondary hypothesis is that RIP+SAP blocks will provide reduction in the pain scores and opioid consumption in the postoperative first 24 hours.
Spirometric assessment of respiratory function before and after adenotonsillectomy surgery
to compare high flow nasal cannula against noninvasive ventilation in patients with non-sever blunt chest trauma in improvement of oxygenation, need for intubation and mechanical ventilation within 28 days
One in ten babies are born preterm (<37 weeks gestation) globally. Complications of prematurity are the leading cause of death in children under 5 years, with the highest mortality rate in Sub-Saharan Africa (SSA). Low flow oxygen, and respiratory support - where an oxygen/air mixture is delivered under pressure - are life saving therapies for these babies. Bubble Continuous Positive Airway Pressure (bCPAP) is the mainstay of neonatal respiratory support in SSA. Oxygen in excess can damage the immature eyes (Retinopathy of Prematurity [ROP]) and lungs (Chronic Lung Disease) of preterm babies. Historically, in well-resourced settings, excessive oxygen administration to newborns has been associated with 'epidemics' of ROP associated blindness. Today, with increasing survival of preterm babies in SSA, and increasing access to oxygen and bCPAP, there are concerns about an emerging epidemic of ROP. Manually adjusting the amount of oxygen provided to an infant on bCPAP is difficult, and fearing the risks of hypoxaemia (low oxygen levels) busy health workers often accept hyperoxaemia (excessive oxygen levels). Some well resourced neonatal intensive care units globally have adopted Automated Oxygen Control (AOC), where a computer uses a baby's oxygen saturation by pulse oximetry (SpO2) to frequently adjust how much oxygen is provided, targetting a safe SpO2 range. This technology has never been tested in SSA, or partnered with bCPAP devices that would be more appropriate for SSA. This study aims to compare AOC coupled with a low cost and robust bCPAP device (Diamedica Baby CPAP) - OxyMate - with manual control of oxygen for preterm babies on bCPAP in two hospitals in south west Nigeria. The hypothesis is that OxyMate can significantly and safely increase the proportion of time preterm infants on bCPAP spend in safe oxygen saturation levels.
An observational study will be conducted in 20 hospitalized surgical patients routinely managed with opioids for anesthesia and post-operative pain control. Trachea Sound Sensor measurements and reference respiratory measurements will be recorded and analyzed to develop diagnostic algorithms that produce a risk-index score that detects/predicts progression from mild hypoventilation, to moderate hypoventilation, to severe hypoventilation due to opioids and other medications that cause respiratory depression. Our current Trachea Sound Sensor (TSS) has a wired Sony commercial microphone integrated into a commercial pediatric stethoscope, coupled to the skin surface over the trachea at the sternal notch. The Trachea Sound Sensor will measure and record the sounds of air moving within the proximal trachea during inhalation and exhalation. The microphone signal will be converted into an accurate measurement of the patient's respiratory rate and tidal volume (during inhalation & exhalation) over time, to determine the minute ventilation trend, breathing patterns, apnea episodes, and degree of snoring (due to partial upper airway obstruction). A commercial respiratory facemask and two pneumotachs (gas flow sensors) will also be used to accurately and continuously measure the patient's respiratory rate and tidal volume (during inhalation & exhalation) to determine the minute ventilation trend, breathing patterns, and apnea episodes. TSS data and reference respiratory data will be collected prior to surgery with the patient breathing normally (baseline), in the Operating Room (OR) during the induction and maintenance of anesthesia, in the Post Anesthesia Care Unit (PACU), and on the general nursing floors of Thomas Jefferson University Hospital (TJUH). The sounds of air flowing through the proximal trachea will be correlated with the reference breathing measurements using signal processing methods to optimize the measurement accuracy of RR, TV, breathing pattern, apnea episodes, and degree of snoring. A commercial accelerometer may be coupled to the skin surface of the neck (with tape) to measure body position and activity level. The TSS and vital sign trend data will be analyzed to produce a Risk-Index Score every 30 seconds with alerts and alarms that warn the patient and caregivers about progressive Opioid Induced Respiratory Depression (OIRD).