View clinical trials related to Hypercapnia.
Filter by:Arterial blood sampling is needed to monitor carbon dioxide and PH but is often painful. The aim of this study is to determine whether continuous carbon dioxide monitoring with a skin probe reduces the need for arterial blood sampling by at least 30%. The investigators will also study the safety and effectiveness of skin probe monitoring to manage non-invasive ventilation (NIV).
It is estimated that 1,275,000 people in the United States alone live with spinal cord injury, including around 100,000 Veterans with spinal cord injury, making the V.A. the largest integrated health care system in the world for spinal cord injuries injury care. New therapies are needed to prevent the morbidities and mortalities associated with the high prevalence of respiratory disorders in Veterans with spinal cord injury. The current research project and future studies would set the base for developing innovative therapies for this disorder. This proposal addresses a new therapeutic intervention for sleep apnea in spinal cord injury. The investigators hypothesized that daily hypercapnia treatments improve respiratory symptoms and alleviate sleep apnea in patients with chronic spinal cord injury. The investigators will perform a pilot study to examine the impact of daily hypercapnia treatments for-two week durations among Veterans with spinal cord injury. The investigators believe that this novel approach to treating sleep apnea and will yield significant new knowledge that improves the health and quality of life of these patients.
High flow nasal cannula (HFNC) is used in interventional procedures to prevent hypoxia during sedation. In patients with a patent airway, HFNC reduces dead space ventilation as well. It is unknown if dead space ventilation is also reduced by HFNC in an EndoBroncheal UltraSound procedure, in which the airway is partially blocked by the endoscope. Especially in patients with Chronic Obstructive Pulmonary Disease (COPD) the partial blocking of the airway may reduce ventilation. If HFNC is able to reduce dead space during an EBUS-procedure, it may facilitate CO2 clearance, which may lead to a reduction in work of breathing. This study aims to investigate if HFNC reduces dead space ventilation in patients undergoing an EBUS-procedure and if this is flow-dependent. A randomized, double-blinded, cross-over study is designed.
high flow nasal cannula (HFNC) oxygen therapy utilizes an air oxygen blend allowing from 21 % to 1 00% FiO2 delivery and generates up to 60 L/min flow rates The gas is heated and humidified through an active heated humidifier and delivered via a single limb heated inspiratory circuit (to avoid heat loss and condensation) to the patient through a large diameter nasal cannula Theoretically, HFNC offers significant advantages in oxygenation and ventilation over COT. Constant high flow oxygen delivery provides steady FiO2 and decreases oxygen dilution. It also washes out physiologic dead space and generates positive end expiration pressure (PEEP) that augments ventilation The heated humidification facilitates secretion clearance, decreases bronchospasm, and maintains mucosal integrity. This study aims to evaluate the effectiveness of HFNC compared to NIMV in management of Acute hypoxemic and acute hypercapneic respiratory failure
Current evidence suggests a mechanistic and physiological rationale for the use of high flow nasal cannula (HFNC) in acute respiratory hypoxemic failure (AHRF) based on physiological studies in airway models, healthy volunteers and patients with Chronic Obstructive Respiratory Disease (COPD). This is supported by observational studies in patients with AHRF with reductions in a range of respiratory and other physiological parameters. Observational studies also suggest similar intubation rates and lower failure rates with HFNC when compared to non-invasive ventilation (NIV) with improved patient acceptance and tolerance for HFNC. The role of HFNC is less clear in acute hypercapnic respiratory failure. Although non-invasive ventilation is the recommended treatment, it is associated with discomfort, and a significant proportion (up to 25% in some reports) cannot tolerate non-invasive ventilation. Observational reports and limited data from randomized controlled trials suggests that HFNC is effective in treating patients with hypercapnic respiratory failure. We designed this trial to assess whether early application of HFNC in patients with non-severe hypercapnic respiratory failure can correct barometric abnormalities, and prevent progression to non-invasive ventilation or tracheal intubation and mechanical ventilation.
Opioids are potent painkillers but come with serious adverse effects ranging from addiction to potentially lethal respiratory depression via activation of μ-opioid receptors (MOP) at specific sites in the central nervous system. Cebranopadol is a first-in-class investigational drug to treat patients with acute and chronic pain. The molecule dually activates the Nociceptin/Orphanin FQ peptide (NOP) receptor and the classical MOP receptor. This is a unique mechanism of action and has demonstrated efficacy in multiple Phase 2 and Phase 3 clinical studies across several nociceptive and neuropathic indications as well as a superior safety profile, low potential for abuse and minimal risk of physical dependence. In animal studies, cebranopadol produced considerably less respiratory depression at comparably analgesic doses of oxycodone and fentanyl and appeared to have a ceiling to its respiratory effects. Preliminary clinical trials have suggested that these results will be similar in humans. The present study is designed to investigate if: 1) cebranopadol produces less respiratory depression than oxycodone 2) cebranopadol respiratory effects have a ceiling at very high doses and 3) cebranopadol does not produce significant respiratory depression, as measured in this study design with 30 subjects, at any dose in the VRH model.
This study is designed to evaluate the effects of the coadministration of paroxetine or escitalopram with an opioid on ventilation. Ventilation will be assessed using a rebreathing methodology. This study will evaluate chronic and acute dosing of paroxetine and escitalopram combined with an opioid as well as chronic and acute dosing of the two drugs without coadministration of an opioid. This study is a 3-period, randomized, placebo-controlled crossover study conducted with 25 healthy participants. Each participant will receive each of the 3 treatments (placebo/oxycodone, paroxetine/oxycodone, escitalopram/oxycodone) in a randomized order.
The aim of the project is to evaluate the effect of hypercapnia on physiological parameters in a healthy person during short-term hypoxia and hypercapnia.
We hypothesized that patients with mild hypercapnia during anesthetic emergence after TIVA had a shorter recovery time than patients with normal blood carbonate levels. We will select patients undergoing transurethral lithotripsy, who were expected to have mild postoperative pain, compare tracheal extubation time in patients with normal blood carbonic acid level and mild hypercapnia, to evaluate the effect of blood carbonic acid level during anesthetic emergence on recovery time from TIVA by. We also examined the changes of cerebral blood flow by TCD to investigate the possible mechanism of mild hypercapnia affecting the recovery time from TIVA.
The objective of this study is to assess the efficacy and safety of this new Prismalung+ membrane in its intended clinical setting by demonstrating a reduction in ventilatory parameters and pulmonary energy load or the successful maintenance of spontaneous breathing, respectively, the absence of the need to initiate vv-ECMO therapy, and initial survival.