Effects on lung stress of position and different doses of perfluorocarbon in a model of ARDS.

We determined whether the combination of low dose partial liquid ventilation (PLV) with perfluorocarbons (PFC) and prone positioning improved lung function while inducing minimal stress. Eighteen pigs with acute lung injury were assigned to conventional mechanical ventilation (CMV) or PLV (5 or 10 ml/kg of PFC). Positive end-expiratory pressure (PEEP) trials in supine and prone positions were performed. Data were analyzed by a multivariate polynomial regression model. The interplay between PLV and position depended on the PEEP level. In supine PLV dampened the stress induced by increased PEEP during the trial. The PFC dose of 5 ml/kg was more effective than the dose 10 ml/kg. This effect was not observed in prone. Oxygenation was significantly higher in prone than in supine position mainly at lower levels of PEEP. In conclusion, MV settings should take both gas exchange and stress/strain into account. When protective CMV fails, rescue strategies combining prone positioning and PLV with optimal PEEP should improve gas exchange with minimal stress.

Effects of expiratory tracheal gas insufflation in patients with severe head trauma and acute lung injury.

OBJECTIVE: This study analyzed the effect of phasic tracheal gas insufflation at mid- to end-expiration in patients with severe head trauma and acute lung injury (ALI)/acute respiratory distress syndrome (ARDS). DESIGN AND SETTING: A prospective interventional study in a 16-bed intensive care unit. PATIENTS: Seven patients with severe head trauma (Glasgow Coma Scale <9) and ALI/ARDS. INTERVENTIONS: Patients were ventilated in assist/control mode with a ventilatory strategy providing adequate oxygenation (PaO(2) >70 mmHg) and normocapnia (PaCO(2) between 35-40 mmHg). Mid to end expiratory tracheal gas insufflation at 8 l/min flow rate was delivered for 90 min while normocapnia was maintained by simultaneous reductions in tidal volume. We measured (hemodynamics, oxygenation, lung mechanics, and cerebral parameters) in basal situation and during and after tracheal insufflation. MEASUREMENTS AND RESULTS: Tracheal gas insufflation allowed a significant decrease in tidal volume from 9.1 to 7.2 ml/kg, with associated reduction in driving pressure (plateau pressure minus positive end-expiratory pressure, PEEP) from 18.1 to 13.2 cm H(2)O. Total PEEP increased from 9.3 to 12.7 cm H(2)O due to the generation of lung hyperinflation. Oxygenation improved slightly during tracheal gas insufflation, and this improvement remained after stopping tracheal insufflation. No changes in hemodynamic or cerebral parameters were observed during the study. CONCLUSIONS: In patients with severe head trauma and ALI receiving mechanical ventilation, expiratory tracheal gas insufflation allowed the targeted arterial PCO(2) level to be maintained together with a substantial reduction in tidal volume.

Tracheal gas insufflation as an adjunct to mechanical ventilation.

Tracheal gas insufflation (TGI) as an adjunct to mechanical ventilation delivers fresh gas into the central airways continuously or in a phasic fashion to improve the efficiency of alveolar ventilation or to minimize the ventilatory pressure requirements. Recently, TGI has received increasing attention as an adjunctive tool for lung-protective mechanical-ventilation strategies. Experimental studies in animal and mechanical-lung models have been essential in the quest to understand TGI's mechanisms of action and operational characteristics. Experimental studies in animal models of lung injury have substantiated the potential role of TGI in clinical practice. Currently, the evolution of TGI is entering a phase in which overcoming obstacles to clinical implementation may lead to the development of commercial systems with more widespread TGI application.

Recruitment maneuver: does it promote bacterial translocation?

OBJECTIVE: High peak airway opening pressures (Pao) are used routinely during recruitment maneuvers to open collapsed lung units. High peak Pao, however, can cause lung injury as evidenced by translocation of intratracheally inoculated bacteria. In this study we explored whether recruitment maneuvers that used high Pao could cause translocation of the intratracheally inoculated from the alveoli into the systemic circulation. DESIGN: Prospective, randomized, animal study. SETTING: Experimental animal care laboratory. SUBJECTS: Eighteen male Sprague Dawley rats. INTERVENTIONS Rats were anesthetized, tracheostomized, and ventilated with 14 cm H2O peak Pao and 0 cm H2O positive end-expiratory pressure (PEEP) in pressure-controlled ventilation (frequency, 30 bpm; inspiratory/expiratory ratio, 1:2; Fio, 1). Intratracheal inoculation of 500 microL of saline containing 1 x 10 colony forming units/mL was performed before randomization into three groups (n = 6 in each): a low-pressure group (14 cm H2O peak Pao, 0 cm H2O PEEP), a high-pressure group (45 cm H2O peak Pao, 0 cm H2O PEEP), and a recruitment maneuver group (14 cm H2O peak Pao, 0 cm H2O PEEP, and a recruitment maneuver sustained inflation of 45 cm H2O continuous positive airway pressure for 30 secs every 15 mins). Blood samples for blood gas analysis were obtained before intratracheal instillation of bacteria and at the end of the experimental protocol (2 hrs). Blood cultures were obtained before and after bacterial instillation at 30-min intervals during the experiment. Blood samples were cultured directly in sheep blood, MacConkey, and Iso-Sensitest agars and were observed on the second day. Bacteremia was defined as the presence of one or more colonies of in 1 mL of blood. MEASUREMENTS AND MAIN RESULTS: The blood cultures were positive for in only six rats in the high-pressure group and remained negative throughout the study period in the low-pressure and recruitment maneuver groups. Oxygenation deteriorated in all groups after intratracheal instillation of bacteria. In the high-pressure group, oxygenation decreased from 417 +/- 67 mm Hg to 79 +/- 20 mm Hg ( p=.004), whereas in the low-pressure and recruitment maneuver groups PaO2 decreased from 410 +/- 98 mm Hg and 383 +/- 78 mm Hg to 287 +/- 105 mm Hg ( p=.031) and 249 +/- 59 mm Hg (p =.11), respectively. CONCLUSION: Intermittent recruitment maneuvers applied as a sustained inflation superimposed on low-pressure ventilation with 0 cm H2O PEEP did not cause translocation of intratracheally inoculated.