View clinical trials related to Hypercapnia.
Filter by:The aim of the present study; To compare the effects of respiratory support options available for NIMV at the emergency department; i.e. AVAPS and ST/T modes, on the patient's pCO2 values, additional treatment need (another non-invasive ventilation method or endotracheal intubation) and the duration of stay in hospital.
Mortality of acute hypoxic - hypercapnic respiratory failure (ARF) patients underwent invasive mechanical ventilation is demonstrated to be higher than in patients who underwent only non invasive mechanical ventilation (NIV). There is an increased need to detect more predictive factors for NIV failure, in order to better identify patients most at risk of facing negative outcomes. The aim of this experimental pilot study is to evaluate the feasibility of the ultrasound of diaphragm in ARF patients underwent non invasive mechanical ventilation ( primary endpoint ). Furthermore the secondary aim is to observe any relationship between diaphragmatic function (excursion), diaphragmatic thickening and the timing of arterial blood gases (ABGs) compensation in patients with ARF undergoing NIV treatment; additional outcomes are: correlation with dyspnea level, time of mechanical ventilation, NIV failure, rate of tracheostomy, length of stay in ICU and in-hospital and 90-day mortality.
Pulmonary vascular dysfunction (DVP) is associated with a pejorative prognosis during ARDS. There is no specific therapeutic intervention to thwart it. Extracorporeal CO2 purification (ECCO2-R) is a technique that has been very rapidly diffused and adopted in intensive care since commercialization of the devices but, the formal clinical evaluation is insufficient. It could significantly improve the prognosis of patients with both DVP and refractory hypercapnia.
Humidified Nasal High-flow with Oxygen (HNHF-O2) therapy has been reported to have acute beneficial effects in patients with hypoxemic respiratory failure who have been hospitalized. The usefulness of this therapy in the outpatient setting is unproven. This pilot study will test the feasibility of using this therapy in the outpatient setting and its effects on sleep.
Objective: To prove that initiation of chronic ventilatory support at home, in patients with chronic hypercapnic respiratory failure due to neuromuscular disease (NMD) or thoracic cage problem is not inferior compared to initiation in a hospital based setting. In addition we believe that the start at home is cheaper compared to an in-hospital start. Hypothesis: Initiation of chronic ventilatory support at home is effective, safe and cost effective compared to a hospital-based initiation. Study design: A nationwide non-inferiority multi-center randomized parallel active control study. Study population: Patients with chronic respiratory insufficiency due to a neuromuscular disease (NMD) or thoracic cage problem who are referred for chronic ventilator support. Intervention: The start of HMV at home Standard intervention to be compared to: The start of HMV is normally in a clinical setting as recommended in the national guideline. Outcome measures: Primary: PaCO2. Secondary: Health related quality of life; lung function; nocturnal transcutaneous carbon dioxide assessment and saturation, and costs Sample size calculation/data analysis: This is a non-inferiority trial based on PaCO2 as primary outcome. A difference in favor of the hospital care group of smaller than 0.5 kPa will be labeled as non-inferior. To retain 72 evaluable patients, and allow for drop-outs, we will include 96 patients in total. Cost-effectiveness analysis: A cost analysis will be conducted alongside the clinical trial. Costs of the initiation of HMV at home and in the hospital will be estimated form a societal perspective over a time horizon of 6 months. Time schedule: After an initial phase of 6 months recruitment will start and will take 24 months. Thirty-six months after the start of the study the last assessments will be done and analysis and writing of the papers will start. After 42 months the study will end.
Background High-flow nasal cannula (NHF) are a promising tool for administering oxygen to critically ill patients with high respiratory demand. Prone positioning (PP) is a simple and cost-effective strategy that since 1980s has been used in mechanically ventilated patients with acute respiratory failure to treat oxygenation impairment. A large randomized study detected a relevant survival benefit by prone positioning in patients with moderate to severe acute respiratory distress syndrome (ARDS) undergoing invasive mechanical ventilation and managed with the ARDS network PEEP-FiO2 table strategy. Theoretically, PP may benefit spontaneous breathing patients too, but data concerning its application in such context are limited to small case series and a retrospective study. The investigators designed a pilot feasibility study to assess the safety and efficacy of prone positioning in acute hypoxemic respiratory failure patients noninvasively treated with NHF. Methods Patients: 15 adult hypoxemic (PaO2/FiO2<200 mmHg with respiratory rate greater than 25 breaths per minute) non-hypercapnic patients with acute respiratory failure. PaO2/FiO2 will be assessed while the patients is receiving 50 L/min of 50% oxygen via a standard face mask for a 15-minute monitoring period at study entry. Protocol Eligible patients will undergo NHF for 1 hour in the supine semi-recumbent position (baseline, BL). Afterwards, each enrolled patient will be placed in the prone position for 2 hours. After a 2-hour PP period, the patient will be rotated and will undergo 1 hour of NHF in the semi recumbent supine position (Supine step). Measurements Patient's demographics will be collected at study entry. At the end of the monitoring period, and then on a hourly basis the following data will be collected: - Respiratory rate, SpO2, pH, PaCO2, PaO2, SaO2, PaO2/FiO2; - Heart Rate, arterial blood pressure; - Dyspnea, as defined by the VAS dyspnoea scale; - Discomfort, as defined by a visual analogic scale (VAS) adapted to rate the procedural pain of ICU patients; - End expiratory lung impedance (EELI), tidal volume distribution, global and regional lung dynamic strain (Change in lung impedence due to tidal volume/ELLI). - Work of breathing, assessed by pressure-time product (PTP) of the esophageal pressure and inspiratory swings in this signal. - Occurrence of pendelluft phenomenon The number of adverse events will be also recorded for each study step.
Sufficient oxygenation is critical for completely buried avalanche victims to avoid life-threatening consequences during hypoxic exposure. Snow contains a remarkable capacity to maintain air availability; it was suspected that the snow physical properties affect the development of hypoxia and hypercapnia. The aim of this study was to evaluate the influence of different snow physical properties on the development of hypoxia and hypercapnia in subjects breathing into an artificial air pocket in snow. Twelve male healthy subjects breathed through an airtight face-mask and 40cm tube into an artificial air pocket of 4L. Every subject performed three tests on different days with varying snow characteristics. Symptoms, gas and cardiovascular parameters were monitored up to 30min. Tests were interrupted at SpO2 <75% (primary endpoint); or due to subjective symptoms like dyspnea, dizziness, and headache (i.e. related to hypercapnia). Snow density was assessed via standard methods and micro-computed tomography (CT) analysis, and permeability and penetration with the snow micro-penetrometer (SMP).
This study aims to evaluate the risk of hyperoxia-induced hypercapnia in post-op obese cardiac surgery patients. It will compare two oxygenation modes in terms of their effect on the arterial partial pressure of carbon dioxide (PaCO2) : manual titration of oxygen delivery for a peripheral oxygen saturation (SpO2) target of > or = 95 % versus automatic titration by a closed-loop system for a SpO2 target of 90%. 15 post-op obese cardiac surgery patients will be recruited and each will receive both interventions (cross-over design). The main outcome will be the PaCO2, which will be compared after each study period. The research hypothesis is that the usual SpO2 target of > or = 95 % is associated with a greater PaCO2 compared with a lesser SpO2 target of 90%.
In this study, 20 hypercapnic COPD patients will perform two constant workrate endurance cycle tests. One test will be while using non-invasive Ventilation (NIV) support, one without in a randomized cross-over design. The aim is to measure, whether NIV is able to change peripheral and respiratory muscle oxygenation.
Baseline cerebral blood flow through the middle cerebral artery (MCA) and cerebral vasodilator response of the MCA to inhaled carbon dioxide (CO2) will be measured in young women, young men, older women, and older men using Magnetic Resonance (MR) imaging and transcranial Doppler ultrasound (TCD). Data collection techniques will be compared.