Liquid ventilation: a mathematical model of gas diffusion in the premature lung

Pulmonary applications of perfluorochemical liquids: ventilation and beyond

In this review of liquid ventilation, concepts and applications are presented that summarise the pulmonary applications of perfluorochemical liquids. Beginning with the question of whether this alternative form of respiratory support is needed and ending with lessons learned from clinical trials, the various methods of liquid assisted ventilation are compared and contrasted, evidence for mechanoprotective and cytoprotective attributes of intrapulmonary perfluorochemical liquid are presented and alternative intrapulmonary applications, including their use as vehicles for drugs, for thermal control and as imaging agents are presented.

A mathematical model of neonatal tidal liquid ventilation integrating airway mechanics and gas transfer phenomena

Tidal liquid ventilation (TLV) was proposed as an alternative to conventional mechanical ventilation in the case of surfactant-deficiency diseases, particularly for very premature subjects. Although many experimental studies have been conducted up to now, the effects of variations in ventilatory settings, such as frequency and tidal volume, on blood arterialization and lung mechanics have not been studied quantitatively. We developed a mathematical model simulating the breathing processes occurring during neonatal TLV treatments. The model integrates the description of O2 and CO2 transport, from the trachea to pulmonary capillary blood and vice versa, with the description of fluid mechanics within the airways and the saccules (the alveoli precursors). Gas transfer is described with a mono-dimensional model, accounting for convective and diffusive transport through the airways, coupled with a 3-compartment model, simulating gas diffusion between saccules, plasma and red blood cells, and chemical reactions dependent on the concentrations of gases and related chemical species. Mechanic loads on airways are calculated by means of a lumped-parameters approach. The model calculates mechanical stress and gas exchange as a function of the ventilatory settings. The integration of these results sheds light on possible ventilation strategies to allow for optimal management of blood arterialization and lung mechanical load.

Changes in FiO2 affect PaO2 with minor alterations in cerebral concentration of oxygenated hemoglobin during liquid ventilation in healthy piglets

OBJECTIVE

To measure the impact of changes in the fraction of inspired oxygen (FiO2) on systemic and cerebral oxygen supply in gas and liquid ventilated healthy animals.

DESIGN

Interventional prospective animal study.

SETTING

University research laboratory.

PARTICIPANTS

Ten healthy, new-born piglets.

INTERVENTIONS

Variations in FiO2 during conventional mechanical ventilation (CMV) followed by partial liquid ventilation (PLV) with two different filling volumes of PF 5080 (10 vs. 30 ml/kg).

MEASUREMENTS AND RESULTS

Arterial blood gases were obtained 15 min after changing FiO2 and concentrations of cerebral oxygenated and total hemoglobin were determined with near infrared spectroscopy. During CMV an increase in FiO2 1.0 was associated with a constant rise in PaO2 but only a small increase in the cerebral concentration of oxygenated Hb. Initiation of PLV (at FiO2 of 1.0) caused a rapid drop in PaO2 towards values that were similar to CMV at FiO2 of 0.5. At FiO2 of 0.5 a reduction in oxygenated Hb was found in the 30 ml/kg filling group. Complete filling of the lungs with PFC caused a significant drop in total cerebral Hb concentration. CONCLUSIONS. According to our data, PLV in healthy lungs should be performed with a FiO2 of 1.0 and a small filling volume to avoid deterioration in cerebral oxygen supply.

A model of neonatal tidal liquid ventilation mechanics

Tidal liquid ventilation (TLV) with perfluorocarbons (PFC) has been proposed to treat surfactant-deficient lungs of preterm neonates, since it may prevent pulmonary instability by abating saccular surface tension. With a previous model describing gas exchange, we showed that ventilator settings are crucial for CO(2) scavenging during neonatal TLV. The present work is focused on some mechanical aspects of neonatal TLV that were hardly studied, i.e. the distribution of mechanical loads in the lungs, which is expected to differ substantially from gas ventilation. A new computational model is presented, describing pulmonary PFC hydrodynamics, where viscous losses, kinetic energy changes and lung compliance are accounted for. The model was implemented in a software package (LVMech) aimed at calculating pressures (and approximately estimate shear stresses) within the bronchial tree at different ventilator regimes. Simulations were run taking the previous model's outcomes into account. Results show that the pressure decrease due to high saccular compliance may compensate for the increased pressure drops due to PFC viscosity, and keep airway pressure low. Saccules are exposed to pressures remarkably different from those at the airway opening; during expiration negative pressures, which may cause airway collapse, are moderate and appear in the upper airways only. Delivering the fluid with a slightly smoothed square flow wave is convenient with respect to a sine wave. The use of LVMech allows to familiarize with LV treatment management taking the lungs' mechanical load into account, consistently with a proper respiratory support.