Effects of different triggering systems and external PEEP on trigger capability of the ventilator

Abstract

The triggering capability of both the pressure and flow triggering systems of the Servo 300 ventilator (Siemens-Elema, Sweden) was compared at various levels of positive end-expiratory pressure (PEEP), airway resistance (R_aw), inspiratory effort and air leak, using a mechanical lung model. The ventilator was connected to a two bellows-in-series-type lung model with various mechanical properties. Lung complicance and chest wall compliance were 0.03 and 0.12 l/cmH₂O, respectively. R_aw was 5, 20 and 50 cmH₂O/l/s. Respiratory rate was 15 breaths/min. To compare the triggering capability of both systems, the sensitivity of pressure and flow triggered pressure support ventilation (PSV) was adjusted to be equal by observing the triggering time at 0 cmH₂O PEEP and 16 cmH₂O of pressure support (PS) with no air leak. No auto-PEEP was developed. In the measurement of trigger delay, the PS level ranged from 16 to 22 cmH₂O to attain a set tidal volume (V_T) of 470 ml at a R_aw of 5, 20 and 50 cmH₂O/l/s. The PEEP level was then changed from 0, 5 and 10 cmH₂O at a PS level of 17 cmH₂O and R_aw of 5 and 20 cmH₂O/l/s, and the trigger delay was determined. The effect of various levels of air leak and inspiratory effort on triggering capability was also evaluated. Inspiratory effort during triggering delay was estimated by measurements of pressure differentials of airway pressure (P_aw) and driving pressure in the diaphragm bellows (P_driv) in both systems. There were no significant differences in trigger delay between the two triggering systems at the various PEEP and R_aw levels. At the matched sensitivity level, air leak decreased trigger delay in both systems, and additional PEEP caused auto-cycling. A low inspiratory drive increased trigger delay in the pressure sensing system, while trigger delay was not affected in the flow sensing system. The P_aw and P_driv differentials were lower in flow triggering than in pressure triggering. With respect to triggering delay, the triggering capabilities of the pressure and flow sensing systems were comparable with and without PEEP and/or high air-way resistance at the same sensitivity level, unless low inspiratory drive and air leak were present. In terms of pressure differentials, the flow triggering system may require less inspiratory effort to trigger the ventilator than that of the pressure triggering system with a comparable triggering time. However, this difference may be extremely small.