Effect of liquid ventilation on preterm lamb tracheal mechanics

Cardiopulmonary function and oxygen delivery during total liquid ventilation

INTRODUCTION

Total liquid ventilation (TLV) with perfluorocarbons has shown to improve cardiopulmonary function in the injured and immature lung; however there remains controversy over the normal lung. Hemodynamic effects of TLV in the normal lung currently remain undetermined. This study compared changes in cardiopulmonary and circulatory function caused by either liquid or gas tidal volume ventilation.

METHODS

In a prospective, controlled study, 12 non-injured anesthetized, adult New Zealand rabbits were primarily conventionally gas-ventilated (CGV). After instrumentation for continuous recording of arterial (AP), central venous (CVP), left artrial (LAP), pulmonary arterial pressures (PAP), and cardiac output (CO) animals were randomized into (1) CGV group and (2) TLV group. In the TLV group partial liquid ventilation was initiated with instillation of perfluoroctylbromide (12 ml/kg). After 15 min, TLV was established for 3 hr applying a volume-controlled, pressure-limited, time-cycled ventilation mode using a double-piston configured TLV. Controls (CGV) remained gas-ventilated throughout the experiment.

RESULTS

During TLV, heart rate, CO, PAP, MAP, CVP, and LAP as well as derived hemodynamic variables, arterial and mixed venous blood gases, oxygen delivery, PVR, and SVR did not differ significantly compared to CGV.

CONCLUSIONS

Liquid tidal volumes suitable for long-term TLV in non-injured rabbits do not significantly impair CO, blood pressure, and oxygen dynamics when compared to CGV.

Tracheal compliance and limit flow rate changes in a murine model of asthma

Trachea is the unique passage for air to flow in and out. Its tone is of importance for the respiration system. However, investigation on how tracheal tone changes due to asthma is limited. Aiming at studying how the mechanical property changes due to asthma as well as the compliance and flow limitation, the following methods are adopted. Static and passive pressure-volume tests of rats' trachea of the asthmatic and control groups are carried out and a new type of tube law is formulated to fit the experimental data, based on which changes of compliance and limit flow rate are investigated. In order to give explanation to such changes, histological examinations with tracheal soft tissues are made. The results show that compliance, limit flow rate and material constants included in the tube law largely depend on the longitudinal stretching ratio. Compared with the control group, the tracheal compliance of asthmatic animals decreases significantly, which results in an increased limit flow rate. Histological studies indicate that asthma can lead to hyperplasia/hypertrophy of smooth muscle cells, and increase elastin and collagen fibres in the muscular membrane. Though decreasing compliance increases stability, during the onset of asthma, limit flow rate is much smaller due to the lower transmural pressure. Asthma leads to a stiffer trachea and the obtained results reveal some aspects relevant to asthma-induced tracheal remodelling.

Effect of Repeated Induced Airway Collapse During Total Liquid Ventilation

Negative pressure generated during the expiratory phase of total liquid ventilation (TLV) may induce airway collapse. Evaluation of the effect of repeated airway collapse is crucial to optimize this technique. A total of 24 New Zealand White rabbits were randomly divided into four groups. Ventilation was performed for 6 hours with different strategies: conventional gas ventilation, TLV without airway collapse, and TLV with collapse induced in either 75 or 150 sequential breaths. In the treated groups, airway collapse was induced by increasing the perfluorocarbon drainage velocity while maintaining the minute ventilation constant. Airway pressure, gas exchange, and blood pressure were monitored at 30-minute intervals. At the end of the experiment, airway and lung parenchyma specimens were processed for light microscopy. No evidence of fluorothorax was noticed in any of the four groups at autopsy examination. Minimal signs of inflammation were noticed in all airway and lung parenchyma specimens, but no evident structural alteration was visible. Adequate gas exchange and systemic blood pressure were maintained during all the studies. Repeated airway collapse is not associated with structural changes in the respiratory system and does not alter the gas exchange ability of the lungs.

The Impact of Mechanical Ventilation on Immature Airway Smooth Muscle: Functional, Structural, Histological, and Molecular Correlates

Preterm infants exposed to mechanical ventilation often develop airway dysfunction and bronchopulmonary dysplasia. The mechanisms of mechanical ventilation-induced airway injury are currently unknown. This study correlates the age-related effects of mechanical ventilation on airway function with structural alterations at the tissue, cellular, ultrastructural, and molecular levels. Mechanically ventilated and nonventilated tracheal rings were obtained from premature and newborn lambs. In tissue baths, the passive and active length-tension relationships and dose-response characteristics of the tracheal rings were determined. Fixed tracheal rings were digested and the resulting isolated smooth muscle cells measured. Rings were analyzed by light and electron microscopy. Additionally, protein was extracted from the tracheal smooth muscle and myosin heavy chain isoforms were separated by SDS-polyacrylamide gel electrophoresis and analyzed by densitometry. Mechanical ventilation resulted in a significant decrease of both the slope of the passive length-stress relationship and of maximal force generation, with both effects being most pronounced in the newborn age group. These age-related functional alterations correlated with a decrease in smooth muscle cell length and a disruption of ultrastructural architecture, which were also most pronounced in the older groups. Furthermore, mechanical ventilation resulted in epithelial denudation at all ages. There were no acute statistically significant effects of mechanical ventilation on myosin heavy chain isoform expression. This study demonstrates age-related effects of mechanical ventilation on the passive and active characteristics of tracheal function and provides a structural analysis of potential mechanisms. The mechanisms behind these functional differences involve ultrastructural changes in cell length, tissue matrix, and disruption of epithelial integrity. These findings help elucidate the pathogenesis of ventilator-induced airway injury.

A numerical and experimental study of compliance and collapsibility of preterm lamb tracheae

Knowledge of the mechanical behaviour of immature tracheae is crucial in order to understand the effects exerted on central airways by ventilatory treatments, particularly of Total Liquid Ventilation. In this study, a combined experimental and computational approach was adopted to investigate the compliance and particularly collapsibility of preterm lamb tracheae in the range of pressure likely applied during Total Liquid Ventilation (-30 to 30 cmH2O). Tracheal samples of preterm lambs (n = 5; gestational age 120-130 days) were tested by altering transmural pressure from -30 to 30 cmH2O. Inflation (Si) and collapsing (Sc) compliance values were calculated in the ranges 0 to 10 cmH2O and -10 to 0 cmH2O, respectively. During the tests, an asymmetric behaviour of the DeltaV/V0 vs. P curves at positive and negative pressure was observed, with mean Si = 0.013 cmH2O(-1) and Sc = 0.053 cmH2O(-1). A different deformed configuration of the sample regions was observed, depending on the posterior shape of cartilaginous ring. A three-dimensional finite-element structural model of a single tracheal ring, based on histology measurements of the tested samples was developed. The model was parameterised in order to represent rings belonging to three different tracheal regions (craniad, median, caudal) and numerical analyses replicating the collapse test conditions were performed to evaluate the ring collapsibility at pressures between 0 and -30 cmH2O. Simulation results were compared to experimental data to verify the model's reliability. The best model predictions occurred at pressures -30 to -10 cmH2O. In this range, a model composed of median rings best interpreted the experimental data, with a maximum error of 2.7%; a model composed of an equal combination of all rings yielded an error of 12.6%.

Development of a time-cycled volume-controlled pressure-limited respirator and lung mechanics system for total liquid ventilation

Total liquid ventilation can support gas exchange in animal models of lung injury. Clinical application awaits further technical improvements and performance verification. Our aim was to develop a liquid ventilator, able to deliver accurate tidal volumes, and a computerized system for measuring lung mechanics. The computer-assisted, piston-driven respirator controlled ventilatory parameters that were displayed and modified on a real-time basis. Pressure and temperature transducers along with a lineal displacement controller provided the necessary signals to calculate lung mechanics. Ten newborn lambs (<6 days old) with respiratory failure induced by lung lavage, were monitored using the system. Electromechanical, hydraulic, and data acquisition/analysis components of the ventilator were developed and tested in animals with respiratory failure. All pulmonary signals were collected synchronized in time, displayed in real-time, and archived on digital media. The total mean error (due to transducers, analog-to-digital conversion, amplifiers, etc.) was less than 5% compared with calibrated signals. Components (tubing, pistons, etc.) in contact with exchange fluids were developed so that they could be readily switched, a feature that will be important in clinical settings. Improvements in gas exchange and lung mechanics were observed during liquid ventilation, without impairment of cardiovascular profiles. The total liquid ventilator maintained accurate control of tidal volumes and the sequencing of inspiration/expiration. The computerized system demonstrated its ability to monitor in vivo lung mechanics, providing valuable data for early decision making.

Tracheobronchial trauma associated with airway management in neonates

Airway management procedures are an integral part of caring for the newborn infant with respiratory compromise. Concomitant with these interventions are latrogenic consequences that result in varying degrees of trauma to the tracheobronchial tree. Common interventions such as intubation, mechanical ventilation, use of heated and humidified gases, and endotracheal suctioning are discussed using research-based literature that evaluates the injury to the trachea and the mucociliary transport system.

Perfluorocarbons: future clinical possibilities

Perfluorocarbons are now being used as oxygen carriers in clinical settings. Because these chemicals may have a role as a blood substitute, in organ preservation, and in the management of respiratory failure, we have reviewed some of the research leading to these applications.

Novel therapies for acute respiratory failure

Mortality in acute respiratory failure in the non-neonatal pediatric patient has not changed substantially in 20 years, despite advances and refinements in conventional therapeutic strategies and technology. A host of innovative therapies are currently in various stages of investigation, including high frequency ventilation, pressure control ventilation, permissive hypercapnia, extracorporeal membrane oxygenation, exogenous surfactant administration, inhaled nitric oxide, and liquid ventilation. While none of these therapies has yet been prospectively studied in non-neonatal pediatric patients, all show much promise by virtue of their emphasis on either directly addressing pathophysiologic derangements associated with acute respiratory failure or by reducing the complications associated with conventional therapy.

Potential clinical applications for blood substitutes

In the coming decade, it is likely that oxygen-carrying alternatives to red blood cells will become available for clinical use. The driving force behind their development is the risk of transfusion of homologous blood, which includes transmission of viral disease (HIV and hepatitis) and transfusion reactions as well as the expense of collecting and storing human blood. A number of clinical applications for these products can be anticipated now, but when available, it is likely that the list will grow. How widely these products will be used depends on their safety. In addition to these clinical applications, blood substitutes will be useful in furthering our understanding of basic oxygen transport physiology.

Synthetic oxygen transport fluids based on perfluorochemicals: applications in medicine and biology

Recent advances in the development and assessment of synthetic oxygen transport fluids based on perfluorochemicals (PFCs) are reviewed. The basic properties of PFCs are outlined, together with the selection criteria for biomedical applications. PFCs must be emulsified for intravascular use and attention is focussed on the formulation and biocompatibility testing of both first- and second-generation emulsions and their components in man and other species. The multidisciplinary applications for PFCs in medicine and basic biomedical research are described, including the clinical use of Fluosol-DA 20% as an oxygen-carrying perfusate in percutaneous transluminal coronary angioplasty.

Influence of smooth muscle tone and longitudinal tension on the collapsibility of immature airways

Mechanical properties and pressure-flow relationships of tracheae excised from very premature lambs were studied in a plethysmograph. Control (Group I) data revealed the tracheae to be extremely compliant, collapsible airways, with an inflation compliance (Si) of 0.033 (+/- 0.004 SE) mmHg-1, collapsing compliance (Sc) of 0.026 (+/- 0.001 SE) mmHg-1, and pressure-flow relationships similar to those of a Starling resistor. Acetylcholine administration (Group II) lowered both Si, 0.026 (+/- 0.003 SE) mmHg-1 and Sc, 0.022 (+/- SE) mmHg-1, as did longitudinal stretch (Group III): Si, 0.021 (+/- .003 SE) mmHg-1, and Sc, 0.017 (+/- 0.002 SE) mmHg-1. Alterations in tracheal collapsibility were also evidenced by significant reductions in resistance to airflow when the tracheae were subjected to compressive forces. Altering both smooth muscle tone (acetylcholine administration) and longitudinal length simultaneously (Group IV) produced results similar to those obtained for Group III. These data help to define the functional characteristics of immature airways and may provide insight for more effective clinical management of the premature infant.

Perfluorocarbons as oxygen-transport fluids

1. An overview of the proposed biological applications of perfluorocarbons and their emulsions as oxygen-transport fluids is presented. 2. Aspects of the properties, preparation, composition and physiological assessment of perfluorocarbon emulsions are discussed. 3. The experimental basis for some of the potential therapeutic uses of PFCs in liquid ventilation, treatment of decompression sickness, organ perfusion, oxygenation of ischaemic and malignant tissues, and as contrast media for NMR imaging is described. 4. The extent to which emulsified perfluorocarbons may have value as substitutes for red blood cells is discussed in detail. Data from both animal and human studies with such emulsions is reviewed. Brief consideration is also given to the possible use of native and modified haemoglobin in blood replacement together with recent work on the preparation of so-called "synthetic red cells".