View clinical trials related to Hypercapnia.
Filter by:Patients with moderate to severe acute exacerbation of chronic obstructive pulmonary disease are often complicated with hypercapnia and respiratory failure, so they need to be admitted to ICU for monitoring and respiratory support treatment. Noninvasive ventilation has become the first-line respiratory support for the treatment of AECOPD with hypercapnia and respiratory failure. However, 26-54% of AECOPD patients with hypercapnia and respiratory failure eventually fail to receive noninvasive ventilation and need endotracheal intubation and invasive ventilation to maintain effective gas exchange. For these patients, the in-hospital survival rate is only 31-76%, and the prognosis is poor. In AECOPD patients with high risk of noninvasive ventilation failure and expected need of intubation, timely giving other ways of respiratory support to reduce blood CO2 may avoid patients receiving tracheal intubation and invasive ventilation, thus avoiding related complications and adverse prognosis. As a new type of respiratory support technology, ECCO2R is worthy of attention in monitoring and evaluation of support effect in AECOPD patients with respiratory failure. It is urgent that ECCO2R can effectively alleviate respiratory failure, avoid complications related to tracheal intubation, improve quality of life and reduce mortality.
The aims of the study are to compare long-term one-year outcome with or without AirvoTM in stabile hypercapnic COPD patients, who are non-compliant to NIV after an acute exacerbation of COPD.
Chronic lung conditions such as smoking related lung damage lead to breathing fail. This results in accumulation of gases such as carbon-di-oxide in the body especially during periods of illness known as exacerbation. Current management of carbon-di-oxide accumulation is administration of oxygen, nebulisers, antibiotics etc and if necessary, provide a tight fitting mask around the face to provide breathing support. If this fails, then a patient is placed on a mechanical ventilator. The tight fitting mask therapy is also called non-invasive ventilation and is used widely but patients acceptability of the therapy is limited. Providing a high flow of air with some oxygen could potentially provide the same benefit of the non-invasive ventilation and may also be better accepted by patients. Currently the knowledge and evidence from studies suggest a beneficial role for this high flow therapy but this has not been investigated in well designed studies. In the proposed study we aim to investigate whether use of the high flow therapy reduces the need for non-invasive ventilation in patients who present with a recent onset accumulation of carbon-di-oxide in their body due to long-term lung disease. If this shows benefit, it will lead to a bigger trial with patient benefiting by reduction in the non-invasive ventilation or indeed a need for an invasive breathing machine.
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
Around 20% of the patients requiring hospitalization for Acute Exacerbation of Chronic Obstructive Pulmonary Disease (AECOPD) develop hypercapnia, which is associated with an increased risk of death. Once Non Invasive Ventilation (NIV) has been initiated, a reduction in Respiratory Rate (RR) and improvement in pH within 4 h predicts NIV success. If pH <7.25 and RR >35 breath per minutes persist, NIV failure is likely. Worsening acidosis, after initial improvement with NIV, is also associated with a worse prognosis. In addition, it has been shown that delaying intubation in patients at high risk for NIV failure has a negative impact on patient survival. Hence, assessing the risk of NIV failure is extremely important. NIV has some limitations: a) intolerance, discomfort and claustrophobia requiring frequent interruptions; b) poor patient-ventilator synchrony, especially in presence of air leaks or high ventilatory requirements. Since removing carbon dioxide by means of an artificial lung reduces the minute ventilation required to maintain an acceptable arterial partial pressure of carbon dioxide (PaCO2), the investigators hypothesize that applying Extra-Corporeal CO2 Removal (ECCO2R) in high-risk AECOPD patients may reduce the incidence of NIV failure and improve patient-ventilator interaction. After the beginning of ECCO2R, NIV could be gradually replaced by High Flow Nasal Cannula Oxygen Therapy (HFNCOT), potentially reducing the risk of ventilator induced lung injury, improving patient's comfort and probably allowing the adoption of a more physiologically "noisy" pattern of spontaneous breathing.
The study will be performed as a randomized controlled non-inferiority trial. HFA has been increasingly used in the last years to treat hypoxic respiratory failure (i.e. type I failure), and numerous studies have shown its efficiency in this indication. Despite this good evidence for HFA in hypoxic respiratory failure, it has only reluctantly been used for hypercapnic respiratory failure. HFA has been shown to generate PEEP, despite not being a closed system, and to improve CO2 clearance by flushing anatomical dead space. It might also help to reduce inspiratory resistance and facilitate secretion clearance from humidified gas. A study on COPD patients showed an increase in breathing pressure amplitude and mean pressure, as well as tidal volume, with a trend towards reduction of carbon dioxide partial pressure. Intervention consists of HFA using standard equipment at the department. A gas flow of 60 litres per minute and a FiO2 as clinically feasible will be used. Therapy will be continued until a pCO2-level of 50 mmHg or less is reached, or therapy has to be aborted because of lack of tolerance by the patient or indication for intubation. Control consists of non-invasive continuous positive airway pressure ventilation support using a tight mask and standard respirator equipment of the Department of Emergency Medicine. A positive airway pressure of 3,67 mmHg and a FiO2 as clinically feasible will be used. Therapy will be continued until a pCO2-level of 50 mmHg or less is reached, or therapy has to be aborted because of lack of tolerance by the patient or indication for intubation.
In the present investigation, in 50 COPD with persistent hypercapnia after an acute exacerbation, the investigators want to assess the acceptability of HFNC and its effectiveness in further reducing the level of PaCO2, and to eventually verify the hypothesis, based on previous physiological studies, that the response to HFNC is dependent on the level of baseline hypercapnia and eventually on the presence of overlap syndrome. This latter parameters to eventually calculate the sample size and the target population to perform future definitive randomized long term trials vs NIV.
For performing transnasal humidified rapid insufflation ventilatory exchange (THRIVE), jaw-thrust maneuver have to maintain to make sure the airway open and the CO2 clearance during apnoea. The objective of present study is to prove that nasopharyngeal airway facilitate THRIVE and no need jaw-thrust maneuver and maintain the similar PO2 and PCO2 during apnoea.
this study evaluates high flow oxygen therapy in addition to non invasive ventilation (NIV) to treat hypercapnic respiratory failure. Between sessions of NIV, half of participants will have high flow nasal cannula while the others will have standard low flow oxygen therapy.
Humidified high flow nasal oxygen therapy decreases dilution of the inhaled oxygen and, by matching patient's peak flow, allows accurate delivery of the set FiO2 throughout the whole inspiratory phase.The purpose of this study is to determine the impact of hign-flow nasal therapy on pediatric hypercapnic respiratory failure by comparing with nasal continuous positive airway pressure.