View clinical trials related to Hypercapnia.
Filter by:The aim of the study is to compare the measurement of peripheral blood oxygen saturation using a smartwatch with a medical-grade pulse oximeter.
Temporary hypercapnia leads to a reproducible increase of cerebral blood flow (CBF) and brain tissue oxygenation (StiO2) as shown in a previous study (Trial-Identification: NCT01799525). The aim of this study now was to measure the course of carbon dioxide partial pressure (pCO2) reactivity after prolonged hypercapnia, and to evaluate the therapeutic effect of graded hypercapnia.
The ETAPES Program, a French national Experimentation in Telemedicine for the Improvement of Healthcare Pathways, was launched in 2018 for 4 years. Its objectives were to provide a temporary public reimbursement for medical telemonitoring in order to determine the benefits for the patient and the impact on medical organization and healthcare costs. In particular, this program applies to patients suffering from hypercapnic chronic respiratory failure and requiring home non invasive ventilation (NIV). For these patients, the ETAPES program combines NIV telemonitoring and therapeutic education. e-VENT study aims at evaluating the ETAPES program, implemented using the Chronic Care Connectâ„¢ telemonitoring solution, versus Standard of Care, on the effectiveness of home NIV, measured by average PtCO2, reflecting the level of nocturnal alveolar hypoventilation.
This study will evaluate the ability of High Velocity Nasal Insufflation [HVNI] next generation nasal cannula designs to effect ventilation and related physiological responses relative to the conventional legacy cannula design.
This study aimed to evaluate the effects of a novel automatic non-invasive ventilation (NIV) mode that continuously adjusts expiratory positive airway pressure (EPAP) to the lowest value that abolishes tidal expiratory flow limitation. The investigators conducted a prospective, randomized, cross-over study on stable chronic obstructive pulmonary disease (COPD) patients. Patients were studied in the hospital during two non-consecutive nights while using either fixed or adaptive EPAP. The primary outcome was the transcutaneous partial pressure of carbon dioxide. Secondary outcomes were: oxygen saturation, breathing pattern, oscillatory mechanics, patient-ventilation asynchronies, sleep quality and sleep-related respiratory events.
In the emergency department and intensive care unit, blood gas analysis is a crucial tool in the assessment of critically ill patients. Blood gas analysis is quick and repeatable at the bedside. The sampling can be done from both arterial and venous samples, with arterial samples generally considered to be more reliable and by that widely used as the standard method. The purpose of this project is to compare venous and arterial blood gas parameters in undifferentiated, critically ill patients. We plan to evaluate the correlation between different parameters through a prospective observational study. In particular, carbon dioxide partial pressure (pCO2) correlation between venous and arterial samples is investigated by using and comparing different conversion models proposed in the literature. 250 patients deemed to be in need of arterial blood gas sampling based on their clinical condition will be included in a consecutive fashion at all hours. The long-term goal is to clinically translate the findings into a limitation on the use of arterial sampling, which could potentially reduce pain and complication risks in the many patients who undergo arterial blood gas sampling every day.
Opioids can decrease breathing and co-administration of benzodiazepines with opioids can further decrease breathing. It is unknown whether certain other drugs also decrease breathing when co-administered with opioids. The objective of this study is to determine whether certain drugs combined with an opioid decrease breathing compared to breathing with an opioid alone. In order to assess this, this study will utilize the Read Rebreathing method, where study participants breathe increased levels of oxygen and carbon dioxide. The increased levels of carbon dioxide cause the study participants to increase breathing. This increased breathing response can be decreased by opioids and benzodiazepines, and potentially other drugs. Using this procedure, low doses of opioids or benzodiazepines can be administered that have minimal-to-no effects on breathing when study participants are going about normal activities breathing room air, however breathing increases less than expected as carbon dioxide levels are increased. This study will also obtain quantitative pupillometry measurements before and after each rebreathing assessment to allow for comparisons of pupillary changes to ventilatory changes when subjects receive different drugs and drug combinations. This study includes three parts: A Lead-In Reproducibility Phase and two main parts (Part 1 and Part 2). The Lead-In Reproducibility Phase will measure the variability between study participants and between repeated uses of the method in the same study participant within a day and between days. Part 1 will study an opioid alone, benzodiazepine alone, and their combination to show the methodology will detect changes in breathing at low doses of the drugs that are known to affect breathing. Part 2 will assess whether two drugs, selected due to their effects on breathing in a nonclinical model, decrease the breathing response when combined with an opioid compared to when an opioid is administered alone.
Hypercapnia is a frequent clinical situation defined as an elevation of the partial pressure of carbon dioxide (PaCO2) above 45 mmHg. Several physiopathological parameters such as respiratory minute volume, dead space volume or CO2 production influence the PaCO2. Therefore, hypercapnia can affect the time of various diseases. Available epidemiological data regarding hypercapnia are from studies investigating the efficacy of non-invasive ventilation (NIV), with different population cohorts. However, their interpretation must be cautious given the heterogeneity in patient case-mix and results. Then, whether hypercapnia is a common reason for intensive care unit (ICU) admission, epidemiological data is scarce and heterogeneous. The aim of this study is to investigate the epidemiological, clinical determinants and outcomes of patients admitted to ICU with hypercapnic respiratory failure.
High-flow nasal cannula (HFNC) enables delivering humidified gas at high-flow rates controlling the oxygen inspired fraction (FiO2). Its efficacy has been demonstrated in hypoxemic acute respiratory failure. However, little is known about its use in hypercapnic acute respiratory failure (ARF). Therefore, we aimed to evaluate the effect of using HFNC through "Precision Flow" equipment as first line of ventilatory support for COPD patients with hypercapnic acute respiratory failure.
Noninvasive ventilation (NIV) is essential to treat acute hypercapnic respiratory failure. However, facial pressure ulcers appearing during facemask-delivered noninvasive ventilation are a source of NIV failure by interface intolerance. A Philips facemask (model : AF541 SE Oro-Nasal mask) has the particularity to display two options for its positioning : a usually used "over-the-nose" positioning or an "under-the-nose" positioning that is supposed to reduce the incidence of facial pressure ulcers while keeping in the same time the qualities of a standard facemask. The goal of this controlled randomized trial is to test the hypothesis that the "under-the-nose" positioning actually reduces the incidence of facial pressure ulcers, compared to the usually used "over-the-nose" positioning. Results of this trial should lead to the proposition of a new interface strategy to prevent facial pressure ulcers and therefore to improve the tolerance of NIV via the use of facemasks displaying an "under-the-nose" positioning.