Trials / Unknown

UnknownNCT01821365

End Tidal Carbon Dioxide Monitoring for Evaluating Changes of PaCO2 After Noninvasive Mechanical Ventilation in COPD

End Tidal Carbon Dioxide Monitoring for Evaluating Changes of Arterial Carbon Dioxide After Noninvasive Mechanical Ventilation in Chronic Obstructive Pulmonary Disease

Summary

Sidestream end-tidal CO2 has been found to be closely correlated to PaCO2 especially when people have the stable hemodynamics and normal lung function. PETCO2 can basically reflect the level of PaCO2,but some investigators found that PETCO2 measurements did not reflect PaCO2 in COPD patients.There may be several reasons for this discrepancy. Due to airway obstruction and ventilation-perfusion mismatch, there is a delay in the maximum alveolar concentration of CO2 reaching the cannula, which may give lower PETCO2 values compared with PaCO2. To overcome this disadvantage, we tried to prolong their expiratory time (extend to 5-8s) in order to guarantee adequate time for alveolar CO2 reaching the cannula.our study mainly focus on two issues.First, to explore the optimal depth of tube placed when patients with COPD breathe spontaneously or receive noninvasive ventilation, and compare the differences of two condition at the same time. Secondly, to evaluate the agreement between the PaCO2 and sidestream PETCO2（5s）values in COPD patients receiving noninvasive ventilation when our extension tube locates in the optimal position, and investigate whether PETCO2（5s）can be used to monitor ventilation status dynamically.

Detailed description

Non-invasive positive pressure ventilation(NPPV) can significantly improve gas exchange and relieve respiratory muscle fatigue for COPD,and arterial blood gas is the gold standard to evaluate ventilation status,but the procedure is time consuming,invasive, painful and in some patients. Sidestream end-tidal CO2 has been found to be closely correlated to PaCO2 especially when people have the stable hemodynamics and normal lung function. PETCO2 can basically reflect the level of PaCO2, but for patients with COPD, due to the presence of airway obstruction and emphysema formation, which cause ventilation-perfusion ratio(V/Q) , result to dead space-tidal volume ratio(VD/VT) and right-to-left shunting(Qs/Qt), the time of various lung units discharge of carbon dioxide is not synchronous. Some investigators found that PETCO2 measurements did not reflect PaCO2 in COPD patients. There may be several reasons for this discrepancy. Due to airway obstruction and ventilation-perfusion mismatch, there is a delay in the maximum alveolar concentration of CO2 reaching the cannula, which may give lower PETCO2 values compared with PaCO2. To overcome this disadvantage, we tried to prolong their expiratory time (extend to 5-8s) in order to guarantee adequate time for alveolar CO2 reaching the cannula. our study mainly focus on two issues.First, to explore the optimal depth of tube placed when patients with COPD breathe spontaneously or receive noninvasive ventilation, and compare the differences of two condition at the same time. Secondly, to evaluate the agreement between the PaCO2 and sidestream PETCO2（5s）values in COPD patients receiving noninvasive ventilation when our extension tube locates in the optimal position, and investigate whether PETCO2（5s）can be used to monitor ventilation status dynamically.

Conditions

• COPD

Timeline

Start date

2013-03-01

Primary completion

2013-07-01

Completion

2013-07-01

First posted

2013-04-01

Last updated

2013-04-05

Locations

1 site across 1 country: China

Source: ClinicalTrials.gov record NCT01821365. Inclusion in this directory is not an endorsement.