Objective: Perfluorocarbon liquid ventilation has been shown to have a
dvantages over conventional gas ventilation in premature newborn and l
ung-injured animals. To simplify the process of liquid ventilation, we
adapted an extracorporeal life-support circuit as a time-cycled, volu
me-limited liquid ventilator. Design: Laboratory study that involved s
equential application of gas and liquid ventilation in normal cats and
in lung-injured sheep. Setting: A research laboratory at a university
medical center. Subjects: Eight normal cats weighing 2.7 to 3.8 kg (m
ean 3.1 +/- 0.5), and four lung-injured young sheep weighing 10.4 to 2
2.5 kg (mean 15.9 +/- 5.0). Interventions: Normal cats were supported
with traditional gas ventilation for 1 hr (respiratory rate 20 breaths
/min, peak inspiratory pressure 12 cm H2O, positive end-expiratory pre
ssure 4 cm H2O, and FIO2 1.0). The lungs were then filled with perfluo
rocarbon (30 mL/kg) and tidal volume liquid ventilation was instituted
, utilizing a newly developed liquid ventilation device. Liquid ventil
atory settings were 4 sees for inspiration time, 8 secs for expiration
time, 5 breaths/min for respiratory rate, and 15 to 20 mWkg for tidaI
volume. Liquid ventilation utilizing this device was also applied to
sheep after induction of severe lung injury by right atrial injection
of 0.07 mL/kg of oleic acid, followed by saline pulmonarvy lavage. Ext
racorporeal life support was instituted to provide a stable model of l
ung injury. For the first 30 mins of extracorporeal support, all anima
ls were ventilated with gas. Animals were then ventilated with 15 mL/k
g of perfluorocarbon over the ensuing 2.5 hrs. Measurements and Main R
esults: In normal cats, mean Pao(2) values after 1 hr of liquid or gas
ventilation were 275 +/- 90 (SD) torr (36.7 +/- 10.4 kPa) in the liqu
id-ventilated animals and 332 +/- 78 torr (44.3 +/- 10.4 kPa) in the g
as-ventilated animals (NS). Mean Pace, values were 40.5 +/- 5.7 torr (
5.39 +/- 0.31 kPa) in the liquid-ventilated animals and 37.6 +/- 2.3 t
orr (5.01 +/- 0.31 kPa) in the gas-ventilated animals (NS). Mean arter
ial pH values were 7.35 +/- 0.07 in the liquid-ventilated animals and
7.34 +/- 0.04 in the gas-ventilated animals (NS). No significant chang
es in heart rate, mean arterial pressure, lung compliance, or right at
rial venous oxygen saturation were observed during liquid ventilation
when compared with gas ventilation. In the lung-injured sheep, an incr
ease in physiologic shunt from 15 +/- 7% to 66 +/- 9% was observed wit
h induction of lung injury during gas ventilation. Liquid ventilation
resulted in a significant reduction in physiologic shunt to 31 +/- 10%
(p < .001). In addition, the extracorporeal blood flow rate required
to maintain the Pao(2) in the 50 to 80 torr (6.7 to 10.7 kPa) range wa
s substantially and significantly (p < .001) lower during Liquid venti
lation than during gas ventilation (liquid ventilation 15 +/- 5 vs. ga
s ventilation 87 +/- 15 mL/min/kg). Conclusions: Liquid ventilation ca
n be performed successfully utilizing this simple adaptation of an ext
racorporeal life-support circuit. This modification to an existing ext
racorporeal circuit may allow other centers to apply this new investig
ational method of ventilation in the laboratory or clinical setting.