The investigators hypothesis is that the adjustment of the inspiratory time may optimize the distribution of ventilation and increase tidal volume, producing potential therapeutic effects on the displacement of secretions and respiratory mechanics. The objective of this study was To evaluate the effects of hyperinflation with the ventilator associated with increased inspiratory time on respiratory mechanics.
A randomized crossover clinical trial was conducted with 38 mechanically ventilated patients with pulmonary infection. The order of hyperinflation or control (without changes in parameters) was randomized. Hyperinflation was performed for 5 minutes in the controlled pressure ventilation mode, with progressive increases of 5cmH2O until reaching a maximum pressure of 35cmH2O, maintaining PEEP. After reaching 35cmH2O, the inspiratory time and respiratory rate were adjusted so that the inspiratory and expiratory flows reached the baseline, respectively. Static compliance (Cest, sr), total resistance (Rsr) and airway resistance (Rva), slow pressure drop (ΔP2) and peak expiratory flow (PEF) were assessed before (PRÉ), immediately after the maneuver (POSSimed) and after aspiration (POSPasp). Two-way ANOVA was used for repeated measurements with Tukey post-test, considering a significant p \<0.05.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
38
The ventilator hyperinflation maneuver with inspiratory time adjustment was performed in the pressure controlled ventilation mode (PCV). The inspiratory pressure was increased gradually every 5 cmH2O until reaching a maximum pressure of 35 cmH2O, according to the tolerance of the patient determined by the absence of cough. PEEP remained unchanged throughout the study. After reaching a maximum pressure of 35 cmH2O (PCV + PEEP level), the inspiratory time was gradually increased until the inspiratory flow reached the baseline. Concomitantly, the respiratory rate was decreased to allow the expiratory flow also to reach the baseline, to avoid self-PEEP. The maneuver was performed for 5 min, followed by tracheal aspiration.
Luciano M Chicayban
Campos dos Goytacazes, Rio de Janeiro, Brazil
Static compliance of respiratory system
Compliance was assessed through the occlusion maneuver at the end of inspiration, considering tidal volume, plateau pressure and PEEP. Three measurements were taken at each moment, the mean being used.
Time frame: Baseline (before), immediately after VHI and five minutes after aspiration
Total Resistance of respiratory system
The total resistance of the respiratory system was evaluated through the occlusion maneuver at the end of the inspiration, considering the resistive pressure, measured by the difference between the maximum plateau pressure. Three measurements were taken at each moment, the mean being used.
Time frame: Baseline (before), immediately after VHI and five minutes after aspiration
Airway Resistance
The airway resistance was assessed by means of the occlusion maneuver at the end of the inspiration, considering the rapid fall of the pressure immediately after the occlusion, measured by the difference between the maximum pressure and P1. Three measurements were taken at each moment, the mean being used.
Time frame: Baseline (before), immediately after VHI and five minutes after aspiration
Peak expiratory flow
The peak expiratory flow was evaluated through passive expiration, being considered the greatest value of the flow in the expiratory phase.
Time frame: Baseline (before), immediately after VHI and five minutes after aspiration
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