Sage Journals: Discover world-class research

Abstract

BACKGROUND:

Double-triggering (DT) is a frequent type of patient-ventilator asynchrony and has potentially severe consequences, such as alveolar overdistention or the generation of intrinsic PEEP. However, the first breath of DT could be patient-triggered (DT-P), auto-triggered (DT-A), or ventilator-triggered (DT-V).

OBJECTIVE:

To differentiate DT-P, DT-A, and DT-V using airway pressure or flow changes during the trigger-delay phase in ventilated patients.

METHODS:

Fourteen mechanically ventilated patients with DT were included. All patients were on flow-triggered ventilation modes and received either continuous mandatory ventilation or pressure support ventilation. Breaths in which the first breath was associated with an esophageal pressure drop of > 1 cm H₂O were categorized as DT-P. Breaths in which the first breath occurred at the ventilator set cycle were categorized as DT-V. Breaths in which the first breath occurred earlier than the ventilator set cycle without esophageal pressure drop were categorized as DT-A. The pressure drop and flow change at 0.13 s (PD_0.13 and F_0.13, respectively) in the trigger-delay phase were calculated from the nadir.

RESULTS:

There were 507 double-triggered breaths: 271 DT-V (53%), 50 DT-A (10%), and 186 DT-P (37%). The PD_0.13 for DT-V, DT-A, and DT-P were 0.16 ± 0.12 cm H₂O, 0.25 ± 0.17 cm H₂O, and 1.34 ± 0.67 cm H₂O, respectively. The F_0.13 for DT-V, DT-A, and DT-P were 2.11 ± 2.31 L/min, 2.64 ± 2.07 L/min, and 16.51 ± 8.02 L/min, respectively. The best discriminatory criteria for differentiating DT-P from DT-V and DT-A, based on the Youden index (sensitivity + specificity – 1) was PD_0.13 ≥ 0.49 cm H₂O, which had a Youden index of 95%. CONCLUSION: DT-P can be distinguished from DT-V and DT-A by using airway pressure deflections in the trigger-delay phase.

Keywords

patient-ventilator asynchrony double triggering

Get full access to this article

View all access options for this article.

References

Thille

, Rodriguez

, Cabello

, Lellouche

, Brochard

. Patient-ventilator asynchrony during assisted mechanical ventilation. Intensive Care Med, 2006; 2(10):1515–1522.

Nilsestuen

, Hargett

. Using ventilator graphics to identify patient-ventilator asynchrony. Respir Care, 2005; 50(2):202–232.

Brochard

, Lellouche

. Pressure support ventilation. In: Tobin

editor. Principles and practice of mechanical ventilation, 2nd edition. New York: McGraw-Hill; 2006:232.

Jubran

. Inspiratory flow rate: more may not be better. Crit Care Med, 1999; 27(4):670–671.

Chen

, Lin

, Hsu

. Pseudo-double-triggering. Intensive Care Med, 2007; 33(4):742–743.

Fanfulla

, Delmastro

, Berardinelli

, Lupo

, Nava

. Effects of different ventilator settings on sleep and inspiratory effort in patients with neuromuscular disease. Am J Respir Crit Care Med, 2005; 172(5):619–624.

Baydur

, Behrakis

, Zin

, Jaeger

, Millic-Emili

. A simple method of assessing the validity of the esophageal balloon technique. Am Rev Respir Dis, 1982; 126(5):788–791.

Leung

, Jubran

, Tobin

. Comparison of assisted ventilator modes on triggering, patient effort, and dyspnea. Am J Respir Crit Care Med, 1997; 155(6):1940–1948.

Takeuchi

, Williams

, Hess

, Kacmarek

. Continuous positive airway pressure in new-generation mechanical ventilators: a lung model study. Anesthesiology, 2002; 96(1):162–172.

10.

Thille

, Lyazidi

, Richard

, Galia

, Brochard

. A bench study of intensive-care-unit ventilators: new versus old and turbine-based versus compressed gas-based ventilators. Intensive Care Med, 2009; 35(8):1368–1376.

11.

Marchese

, Chipman

, de la Oliva

, Kacmarek

. Adult ICU ventilators to provide neonatal ventilation: a lung simulator study. Intensive Care Med, 2009; 35(4):631–638.

12.

Schisterman

, Perkins

, Liu

, Bondell

. Optimal cut-point and its corresponding Youden index to discriminate individuals using pooled blood samples. Epidemiology, 2005; 16(1):73–81.

13.

Parthasarathy