Perfluorocarbon-associated gas exchange improves oxygenation, lung mechanics, and survival in a model of adult respiratory distress syndrome.

OBJECTIVE: To compare the effectiveness of perfluorocarbon-associated gas exchange to volume controlled positive pressure breathing in supporting gas exchange, lung mechanics, and survival in an acute lung injury model. DESIGN: A prospective, randomized study. SETTING: A university medical school laboratory approved for animal research. SUBJECTS: Neonatal piglets. INTERVENTIONS: Eighteen piglets were randomized to receive perfluorcarbon-associated gas exchange with perflubron (n=10) or volume controlled continuous positive pressure breathing (n=8) after acute lung injury was induced by oleic acid infusion (0.15 mL/kg iv). MEASUREMENTS AND MAIN RESULTS: Arterial and venous blood gases, hemodynamics, and lung mechanics were measured every 15 mins during a 3-hr study period. All animals developed a metabolic and a respiratory acidosis during the infusion of oleic acid. Following randomization, the volume controlled positive pressure breathing group developed a profound acidosis (p<.05), while pH did not change in the perfluorocarbon-associated gas exchange group. Within 15 mins of initiating perfluorocarbon-associated gas exchange, oxygenation increased from a PaO2 of 52 +/- 12 torr (6.92 +/- 1.60 kPa) to 151 +/- 93 torr (20.0 +/- 12.4 kPa) and continued to improve throughout the study (p<.05). Animals that received volume controlled positive pressure breathing remained hypoxic with no appreciable change in PaO2. Although both groups developed hypercarbia during oleic acid infusion, PaCO2, steadily increased over time in the control group (p<.01). Static lung compliance significantly increased postrandomization (60 mins) in the animals supported by perflurocarbon-associated gas exchange (p<.05), whereas it remained unchanged over time in the volume controlled positive pressure breathing group. However, survival was significantly higher in the perfluorocarbon-associated gas exchange group with eight (80%) of ten animals surviving the entire study period. Only two (25%) of the eight animals in the volume controlled positive pressure breathing group were alive at the end of the study period (log-rank statistic, p=.013). CONCLUSIONS: Perflurocarbon-associated gas exchange enhanced gas exchange, pulmonary mechanics, and survival in this model of acute lung injury.

Cardiorespiratory effects of perfluorocarbon-associated gas exchange at reduced oxygen concentrations.

OBJECTIVE: To determine whether reducing FIO2 during perfluorocarbon-associated gas exchange would cause deterioration of hemodynamics, lung mechanics, or gas exchange in normal piglets. DESIGN: A prospective, controlled animal trial. SETTING: Experimental animal laboratory in a university setting. SUBJECTS: Twelve normal, anesthetized piglets, 7 to 14 days old, and weighing 3.31 +/- 0.75 kg. INTERVENTIONS: After the induction of anesthesia, tracheostomy and catheterization, piglets were stabilized. They were mechanically ventilated with a tidal volume of 15 mL/kg, inspiratory time of 25%, positive end-expiratory pressure of 4 cm H2O, and a respiratory rate of 20 to 28 breaths/min to obtain a baseline PaCO2 between 34 and 45 torr (4.7 and 6.0 kPa). Each animal was studied during continuous positive-pressure breathing, and during perfluorocarbon-associated gas exchange. They were ventilated at an FIO2 of 1.0 for 15 mins. FIO2 was randomly varied among 0.75, 0.5, and 0.3 every 15 mins, then returned to 1.0. At each FIO2, measurements of gas exchange, lung mechanics, and hemodynamics were made. After continuous positive-pressure breathing, perfluorocarbon-associated gas exchange was instituted by replacing the gaseous functional residual capacity of the lungs with perfluorooctylbromide. Animals were then ventilated and measurements were taken. MEASUREMENTS AND MAIN RESULTS: At each FIO2, measurements of gas exchange (arterial blood gases and saturation), lung mechanics (mean airway pressure, static end-inspiratory pressure, and peak inspiratory pressure), and hemodynamics (heart rate, and mean arterial, right atrial, pulmonary artery occlusion, and pulmonary arterial pressures) were recorded. In six piglets, cardiac output was measured at each FIO2 by thermodilution. Cardiac index, indexed oxygen delivery and consumption, and indexed pulmonary vascular resistance were derived using standard formulas. Piglets were well saturated at all FIO2 settings during continuous positive-pressure breathing. However, during perfluorocarbon-associated gas exchange, arterial saturation decreased to 72% at an FIO2 of 0.3. Cardiac index and oxygen consumption were not affected by reducing FIO2 during perfluorocarbon-associated gas exchange, and were not significantly different than during continuous positive-pressure breathing. Oxygen delivery was reduced at an FIO2 of 0.3 during perfluorocarbon-associated gas exchange, but oxygen consumption remained in the flow independent portion of the curve despite arterial desaturation. Pulmonary arterial pressure was higher during perfluorocarbon-associated gas exchange than during continuous positive-pressure breathing. Pulmonary arterial pressure and indexed pulmonary vascular resistance were significantly higher during perfluorocarbon-associated gas exchange at an FIO2 of 0.3 than at any other FIO2 settings. CONCLUSIONS: Piglets showed no adverse effects on lung mechanics during perfluorocarbon-associated gas exchange. Hemodynamics were well supported at all FIO2 settings, and arterial blood was fully oxygenated during perfluorocarbon-associated gas exchange at an FIO2 of > or = 0.5.

Perfluorocarbon-associated gas exchange in gastric aspiration.

OBJECTIVES: To test whether perfluorocarbon-associated gas exchange (gas ventilation of the perfluorocarbon-liquid filled lung) could support oxygenation better than conventional positive pressure breathing in a piglet model of gastric aspiration-induced adult respiratory distress syndrome (ARDS). DESIGN: Prospective, randomized, blinded, controlled study. SETTING: A critical care research laboratory in a university medical school. SUBJECTS: Fourteen healthy piglets. INTERVENTIONS: Under alpha-chloralose anesthesia and metocurine iodide neuromuscular blockade, 14 piglets underwent tracheostomy; central venous, systemic and pulmonary arterial catheterizations; and volume-regulated continuous positive-pressure breathing. Homogenized gastric aspirate (1 mL/kg) titrated to pH of 1.0 was instilled into the tracheostomy tube of each subject at 0 min to induce ARDS. Hemodynamics, lung mechanics, and gas exchange were evaluated every 30 mins for 6 hrs. Seven piglets were treated at 60 mins by tracheal instillation of perflubron, a volume selected to approximate normal functional residual capacity, and were supported by perfluorocarbon-associated gas exchange without modifying ventilatory settings. Perflubron was added to the trachea every hour to replace evaporative losses. MEASUREMENTS AND MAIN RESULTS: There was a significant difference in oxygenation over time when tested by repeated-measures analysis of variance (F test = 8.78, p < .01). On further analysis, the differences were not significant from baseline to 2.5 hrs but became increasingly significant from 2.5 to 6 hrs after injury (p < .05) in the inflammatory phase of gastric aspiration-induced ARDS. Histologic evidence for ARDS in the treated group 6 hrs after injury was lacking. CONCLUSIONS: In the piglet model, perfluorocarbon-associated gas exchange with perflubron facilitates oxygenation in the acute phase of gastric aspiration-induced inflammatory ARDS when compared with conventional positive-pressure breathing. Histologic and physiologic data suggest that perfluorocarbon-associated gas exchange with perflubron might prevent ARDS if instituted after aspiration in the time window before the acute inflammatory process is manifest.

Oxygenation during perfluorocarbon associated gas exchange in normal and abnormal lungs.

Perfluorocarbon-associated gas exchange (PAGE) has been proposed for the treatment of lung diseases characterized by high alveolar surface tension. Perflubron (perfluorooctyl bromide, LiquiVent, Alliance Pharmaceutical Corp.) is a high purity medical grade perfluorocarbon suitable for PAGE. We studied PAGE using perflubron in normal piglets and in animal models of pulmonary disease (meconium aspiration syndrome, oleic acid infusion and gastric acid aspiration as models of ARDS, and neonatal respiratory distress syndrome). All animals were studied under anesthesia. PAGE was instituted by intratracheal instillation of a volume of perflubron (generally 30 ml/kg) that approximates a normal functional residual capacity of the lung. Arterial blood gases were measured at 15 minute intervals. FiO2 during PAGE was 1.0. In normal piglets, PaO2 fell from 543 torr (during conventional gas breathing) to 363 torr (during PAGE). However, in models of lung disease, PAGE significantly enhanced PaO2.

Perfluorocarbon-associated gas exchange.

BACKGROUND AND METHODS: Liquid ventilation with oxygenated perfluorocarbon eliminates surface tension due to pulmonary air/fluid interfaces, and improves pulmonary function and gas exchange in surfactant deficiency. In liquid ventilation, perfluorocarbon is oxygenated, purged of CO2, and cycled into and out of the lungs using an investigational device. A new approach, perfluorocarbon-associated gas exchange, uses a conventional ventilator and combines features of liquid ventilation and continuous positive-pressure breathing. In 13 normal piglets, a volume of perfluorocarbon equivalent to the normal functional residual capacity (30 mL/kg) was instilled into the trachea, left in situ, and volume-regulated gas ventilation (FIO2 1.0) was resumed. For 1 hr, perfluorocarbon was continuously bubble-oxygenated within the lungs, where it directly participated in gas exchange. RESULTS: PaO2 and PaCO2 averaged 401 +/- 51 and 40 +/- 4 torr (53.6 +/- 6.8 and 5.3 +/- 0.5 kPa), respectively. Peak airway pressure during perfluorocarbon-associated gas exchange (22 +/- 2 cm H2O at 1 hr) and during continuous, positive-pressure breathing (23 +/- 4 cm H2O) were nearly identical. Venous oxygen saturation and pH were normal (73 +/- 8% and 7.43 +/- 0.05, respectively, at 1 hr). CONCLUSIONS: Perfluorocarbon-associated gas exchange was uniformly well tolerated, and its efficiency approached that of continuous positive-pressure breathing. Applications of perfluorocarbon technology to lung disease may not be limited by existing instrumentation.