View clinical trials related to Hypercapnia.
Filter by:We propose to carry out a large multicentric, multinational, randomized controlled trial with two phases (two sequential randomized controled trials) to answer two questions: 1) Should hospitalized patients with recently diagnosed OHS be discharged from the hospital on an auto-titratable NIV treatment until the diagnosis of OHS is confirmed in 3 months? 2) Is the long-term effectiveness of outpatient titrated CPAP non-inferior to titrated NIV in ambulatory patients with OHS 3 months after hospital discharge? Clinical practice, multicenter open-label controlled randomized clinical trial with preset allocation rate (1:1) with two parallel-groups conducted in centers from Spain, France, Portugal and USA. The study will have two phases with two randomizations. The first phase will be a superiority study and the second phase will be a non-inferiority study.
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.
The mechanism behind postural orthostatic tachycardia syndrome (POTS) involves many causes including a sympathetic nervous system problem. Blood gases, like carbon dioxide (CO2), have an important effect on sympathetic activation. The purpose of this research study is to determine if higher CO2 levels have any effect in lowering heart rate and reducing POTS symptoms when upright/standing. The investigators are also searching for the ideal CO2 concentration to achieve the most effective response
The purpose of this research study is to better understand how blood flow and metabolism are different between normal controls and patients with disease. The investigators will examine brain blood flow and metabolism using magnetic resonance imaging (MRI). The brain's blood vessels expand and constrict to regulate blood flow based on the brain's needs. The amount of expanding and contracting the blood vessels can do varies by age. The brain's blood flow changes in small ways during everyday activities, such as normal brain growth, exercise, or deep concentration. Significant illness or physiologic stress may increase the brain's metabolic demand or cause other bigger changes in blood flow. If blood vessels are not able to expand to give more blood flow when metabolic demand is high, the brain may not get all of the oxygen it needs. In less extreme circumstances, not having as much oxygen as it wants may cause the brain to grow and develop more slowly than it should. One way to test the ability of the blood vessels to expand is by measuring blood flow while breathing in carbon dioxide (CO2). CO2 causes blood vessels in the brain to dilate without increasing brain metabolism. The study team will use a special mask to control the amount of oxygen and carbon dioxide patients breath in so that we can study how their brain reacts to these changes. This device designed to simulate carbon dioxide levels achieved by a breath-hold and target the concentration of carbon dioxide in the blood in breathing patients. The device captures exhaled gas and provides an admixture of fresh gas and neutral/expired gas to target different carbon dioxide levels while maintaining a fixed oxygen level. The study team will obtain MRI images of the brain while the subjects are breathing air controlled by the device.
Despite growing evidence showing benefit (in both clinical and cost standpoints), only a small percentage of COPD patients with chronic hypercapnic respiratory failure are managed with nocturnal ventilatory support. There is uncertainty of the value of aggressive nocturnal ventilation, especially polysomnographic estimation of therapy and home transcutaneous CO2 tracking. The driving goal behind this project is to develop and implement a streamlined and comprehensive program for nocturnal ventilator management of patients with advanced, hypercapnic COPD.
Permissive hypercapnia increased the survival rate in patients with acute respiratory distress syndrome (ARDS) who required mechanical ventilation in critical care medicine. This has been explained by its association with ventilator induced lung injury. Since then, a protective lung ventilation strategy has been very important, with a low tidal volume of 4-6 ml/kg. Patients undergoing surgery will inevitably require mechanical ventilation. In particular, patients undergoing one lung ventilation for thoracic surgery may have increased airway pressure and a greater chance of ventilator induced lung injury. Recently, protective lung ventilation has been applied to patients undergoing one ung ventilation during thoracic surgery. The purpose of this study is to evaluate the difference in the degree of pulmonary oxygenation and the incidence of postoperative pulmonary complications in hypercapnia induced by controlling the respiratory rate with a constant tidal volume.
The proposed randomized controlled trial aims at comparing the application of the prone position in spontaneously breathing patients with acute hypoxemic respiratory failure from any cause versus standard treatment on the rate of invasive mechanical ventilation or all-cause of mortality. The secondary endpoints will include time to tracheal intubation and effects of awake proning on the oxygenation parameters, dyspnea sensation, complications, and tolerance. Other endpoints are ventilation free-days at 28 days, duration of invasive ventilation, length of ICU and hospital stay, ICU and hospital mortality, and 28, 60, and 90-day mortality.
This study compares a volume targeted pressure support non-invasive ventilation with an automatic PEP regulation (AVAPS-AE mode) to a pressure support non-invasive ventilation (S/T mode) in patients with acute hypercapnic respiratory failure with acidosis. This study focuses on patients at risk of obstructive apneas or obesity-hypoventilation syndrom (BMI≥30 kg/m²). Half of participants (33 patients) will receive non invasive ventilation with AVAPS-AE mode, the other half will receive non-invasive ventilation with S/T mode.
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.