Frequency, Tidal Volume, and Mean Airway Pressure Combinations that Provide Adequate Gas Exchange and Low Alveolar Pressure during High Frequency Oscillatory Ventilation in Rabbits

Abstract

We studied healthy and saline lavaged rabbits during high frequency oscillatory ventilation to determine what combination of frequency (f), tidal volume (V_t), and mean airway pressure (P_aw) produced the lowest peak-to-peak alveolar pressure amplitude (P_alv) and physiologic blood gas tensions. Sinusoidal volume changes were delivered through a tracheostomy by a piston pump driven by a linear motor. Tracheal pressure amplitude (P_tr) was measured through a tracheal catheter and alveolar pressure amplitude was measured in a capsule glued to the right lower lobe. Pao₂, Paco₂, P_tr, and P_alv were measured at the following settings: FiO₂ = 0.5, frequency 2-28 Hz, V, 1-3 mL/kg (50 150% dead space) and P_aw 5-15 cm H₂O. Many combinations of frequency and V_t resulted in the same Pao₂ and Paco₂. P_aw had a large effect on P_alv and minimal effect on blood gas tensions. In lavaged rabbits, the composite variable f × V_t² described the trends in P_alv and blood gas tensions. As the product of f × V_t² increased, Pao₂ initially increased and then decreased, whereas Paco₂ decreased and P_alv increased. No single combination of frequency, V_t and P_aw simultaneously provided the lowest P_alv and physiologic blood gas tensions. Adequate blood gas tensions and low P_alvwere obtained at frequencies less than 12 Hz, a V, of 2 mL/kg and a P_aw of 10 cm H2O. In healthy and lavaged rabbits Pao₂ increased and Paco₂ decreased as frequency increased at lower V_t · Pao₂ decreased as frequency increased at higher V_t in lavaged rabbits only. P_alvtended to be greater in lavaged rabbits.