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.
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.
Elucidating cerebrovascular control mechanisms during physiologic stress may help identify novel therapeutic targets aimed at preventing or reducing the impact of cerebrovascular disease. The physiological stressors of hypoxia and hypercapnia will be utilized to elicit increases in cerebral blood flow (CBF), and intravenously infused drugs will allow for the testing of potential mechanisms of cerebrovascular control. Specifically, the contributions of nitric oxide synthase (NOS), cyclooxygenase (COX), and reactive oxygen species (ROS) to hypoxic and hypercapnic increases in CBF will be examined. The concept that these mechanisms interact in a compensatory fashion to ensure adequate CBF during both hypoxia and hypercapnia will also be tested. ~25 young, healthy men and women will be tested at rest and during hypoxia and hypercapnia. Subjects will participate in two randomized, counterbalanced study visits under the following conditions: inhibition of NOS, NOS-COX, and NOS-COX-ROS or inhibition of COX, COX-NOS, COX-NOS-ROS. During hypoxia, arterial oxygen saturation will be lowered to 80% and end-tidal carbon dioxide will be maintained at basal levels. During hypercapnia arterial carbon dioxide will be increased ~10 mmHg above basal levels and arterial oxygen saturation will be maintained. Blood flow velocity will be measured with transcranial Doppler ultrasound in the anterior (middle cerebral artery; MCA) and posterior (basilar artery; BA) circulations as a surrogate for CBF. It is hypothesized that both NOS and COX independently contribute to hypoxic and hypercapnic vasodilation in the MCA and BA, combined NOS-COX contribute to hypoxic and hypercapnic vasodilation in MCA and BA to a greater extent than either NOS or COX alone, and NOS-COX-ROS contribute to hypoxic and hypercapnic vasodilation in the MCA and BA to a greater extent than NOS-COX.
This is a prospective, longitudinal observational study to provide data regarding the natural course of hypercapnia in premature infants with bronchopulmonary dysplasia using both available blood pCO2 and measured capnography, as well as relate the degree and trend of hypercapnia to later respiratory outcomes.
Procedures performed under sedation have the same severity in regards to morbidity and mortality as procedures performed under general anesthesia1. The demand for anesthesia care outside the operating room has increased tremendously and it poses, according to a closed claim analysis, major risks to patients. Both closed claim analysis identified respiratory depression due to over sedation as the main risk to patients undergoing procedures under sedation. The major problem is that hypoventilation is only detected at very late stages in patients receiving supplemental oxygen. Besides the respiratory effects of hypoventilation, hypercapnia can also lead to hypertension, tachycardia, cardiac arrhythmias and seizures. The incidence of anesthetized patients with obstructive sleep apnea has increased substantially over the last years along with the current national obesity epidemic. These patients are at increased risk of hypoventilation when exposed to anesthetic drugs. The context of the massive increase in procedural sedation and the extremely high prevalence of obstructive sleep apnea poses major respiratory risks to patients and it may, in a near future, increase malpractice claims to anesthesiologists. The development of safer anesthesia regimen for sedation are, therefore, needed. The establishment of safer anesthetics regimen for sedation is in direct relationship with the anesthesia patient safety foundation priorities. It addresses peri-anesthetic safety problems for healthy patient's. It can also be broadly applicable and easily implemented into daily clinical care. Ketamine has an established effect on analgesia but the effects of ketamine on ventilation have not been clearly defined. The investigators have demonstrated that the transcutaneous carbon dioxide monitor is accurate in detecting hypoventilation in patients undergoing deep sedation. Animal data suggest that when added to propofol in a sedation regimen, ketamine decreased hypoventilation when compared to propofol alone. It is unknown if ketamine added to a commonly used sedative agent (propofol) and fentanyl can decrease the incidence and severity of hypoventilation in patients undergoing deep sedation. The investigators hypothesize that patients receiving ketamine, propofol and fentanyl will develop less intraoperative hypoventilation than patients receiving propofol and fentanyl. The investigators also hypothesize that this effect will be even greater in patients with obstructive sleep apnea than patients without obstructive sleep apnea. Significance: Respiratory depression due to over sedation was identified twice as the major factor responsible for claims related to anesthesia. The high prevalence of obstructive sleep apnea combined with more complex procedures done in outpatient settings can increase physical risks to patients and liability cases to anesthesiologists. The main goal of this project is to establish the effect of ketamine in preventing respiratory depression to patients undergoing procedures under deep sedation using propofol and fentanyl. If the investigators can confirm our hypothesis, our findings can be valuable not only to anesthesiologist but also to other specialties (emergency medicine, gastroenterologists, cardiologists, radiologists) that frequently performed procedural sedation. The research questions is; does the addition of ketamine prevent hypoventilation during deep sedation using propofol and fentanyl? The hypotheses of this study: Ketamine will prevent hypoventilation during deep sedation cases.
The objective of this study is to evaluate the clinical benefits of home mechanical ventilation associated to oxygen therapy in COPD patients with chronic respiratory failure (CRF) who develop hypercapnia and nocturnal respiratory acidosis secondary to oxygen administration. We will include clinically stable COPD patients with hypercapnic CRF who develop a nocturnal hypercapnic response to oxygen (PaCO2 increase on awakening, at night with oxygen, >10 mmHg respect to PaCO2 breathing room air and awake). Obstructive sleep apnoea syndrome (OSAS) will previously have been excluded. Patients will be admitted to the Pneumology ward where a nocturnal pulsioxymetry breathing oxygen therapy will be performed. Arterial blood gas samples will be taken at awakening (7AM). Patients who develop a hypercapnic response to oxygen will be randomised into 2 treatment groups: - Oxygen therapy group - Home mechanical ventilation plus oxygen therapy group Home mechanical ventilation will be performed with a bilevel pressure ventilator. Functional respiratory variables as well as quality of life and sleep at onset and after 6 months treatment will be compared. The principal outcome will be the evolution of arterial blood gases (PaCO2) between the two groups.