During bronchodilator tests, it's common to ask patients with asthma or chronic obstructive pulmonary disease (COPD) to take bronchodilator therapy by inhaling after a maximal exhalation, when the respiratory system volume equals the residual volume. The same maneuver is required for the chronic therapy. Nevertheless, in patients with COPD the distribution of ventilation is more heterogeneous, especially when lung volumes are closer to residual volume . It is therefore predictable that the distribution of air volume containing bronchodilator that has been inhaled at residual volume is more heterogeneous than at higher volumes, such as at functional residual capacity. Accordingly, the bronchodilator can be preferentially distributed in more open airways than in less patent ones, with a heterogeneous distribution of the medication. Therefore, the overall bronchodilation should be greater when the drug inhalation is performed at functional residual capacity than at residual volume. It is common knowledge that the effectiveness of bronchodilator therapy with pMDI in subjects with COPD is greatly affected by the inhalation technique, which can be difficult to perform for many patients. Therefore, in addition to the possibility that inhalation of bronchilation therapy at residual volume could lower the drug effectiveness, this maneuver complicates the sequence of actions required to the patient, enhancing the risk of errors and decreasing the aderence to treatment. The aim of this study is to investigate whether the inhalation of a bronchodilator at different lung volumes can affect its effectiveness in terms of respiratory function, in patients with COPD. Assuming that the bronchodilator effectiveness is equal or greater when inhaled at functional residual capacity rather than at residual volume, the inhalation maneuver can be simplified for patients with COPD.
Study Type
OBSERVATIONAL
Enrollment
30
the patient will be asked to inhale the bronchodilator (salbutamol pMDI, 400 µg) with a spacer from FRC (functional residual capacity, in a random order, with the assistance of an operator. The spacer will be connected to a Fleish flowmeter placed in series with the pMDI device. The valve included in the spacer will guarantee that only the air inhaled by the patient will pass through the flowmeter, reducing the risk of contamination. In both cases a low inspiratory flux and a period of apnea after inhalation of 10 seconds will be used. Before and after the administration it will be asked to the patient to execute a spirometry, a plethysmography, a lung diffusion test, and the NEP technique. These will allow the characterization of the bronchodilator effect in terms of static and dynamic volumes, heterogeneity of ventilation distribution and volume of closure, expiration flux-limitation.
the patient will be asked to inhale the bronchodilator (salbutamol pMDI, 400 µg) with a spacer from VR , with the assistance of an operator. The spacer will be connected to a Fleish flowmeter placed in series with the pMDI device. The valve included in the spacer will guarantee that only the air inhaled by the patient will pass through the flowmeter, reducing the risk of contamination. In both cases a low inspiratory flux and a period of apnea after inhalation of 10 seconds will be used. Before and after the administration it will be asked to the patient to execute a spirometry, a plethysmography, a lung diffusion test, and the NEP technique. These will allow the characterization of the bronchodilator effect in terms of static and dynamic volumes, heterogeneity of ventilation distribution and volume of closure, expiration flux-limitation.
L. Sacco Hospital
Milan, Italy
Efficacy of bronchodilation therapy inhaled at Functional Residual Capacity (FRC) on Forced Expiratory Volume in 1 second (FEV1)
Assuming that the bronchodilator effectiveness is equal or greater when inhaled at functional residual capacity rather than at residual volume, the inhalation maneuver can be simplified for patients with COPD.
Time frame: 1 year
Effects on change in phase III slope of the closing volume curve
Efficacy of bronchodilation therapy inhaled at FRC on reducing phase III slope of the closing volume, as compared to bronchodilation therapy inhaled at RV
Time frame: 1 year
Effects on forced vital capacity (FVC)
Efficacy of bronchodilation therapy inhaled at FRC on static and dynamic lung volumes as compared to bronchodilation therapy inhaled at RV
Time frame: 1 year
Effects on vital capacity (VC)
Efficacy of bronchodilation therapy inhaled at FRC on static and dynamic lung volumes as compared to bronchodilation therapy inhaled at RV
Time frame: 1 year
Effects on residual volume (RV)
Efficacy of bronchodilation therapy inhaled at FRC on static and dynamic lung volumes as compared to bronchodilation therapy inhaled at RV
Time frame: 1 year
Effects on total lung capacity (TLC)
Efficacy of bronchodilation therapy inhaled at FRC on static and dynamic lung volumes as compared to bronchodilation therapy inhaled at RV
Time frame: 1 year
Effects on sensation of dyspnea as measured by modified Medical Research Council (mMRC) score
Efficacy of bronchodilation therapy at functional residual capacity on sensation of dyspnea
Time frame: 1 year
Effects on specific airway resistance (sRAW)
Efficacy of bronchodilation therapy at functional residual capacity on specific pulmonary resistances
Time frame: 1 year
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