Cardiac output and mixed venous O2 content measurements by a tracer bolus method: animal validation study.

A bolus method for noninvasive measurement of cardiac output (CO) and mixed venous oxygen content (O2) has been tested against absolute CO and O2 standards in dogs. No statistical differences in CO were found between bolus method and electromagnetic flowmeter measurement comparisons in an 18-dog study in which CO varied from 0. 5 to 3.0 l/min. The SD for all paired differences was 0.14 l/min; however, data averaging over 10-min intervals were found to reduce the CO measurement uncertainty to <0.08 l/min. The ability of the bolus method to follow rapid CO changes, experimentally produced by control of a pump (surgically placed between the superior and inferior vena cava and the right atrium), was documented and found to satisfy CO monitoring requirements of unstable subjects. O2 bolus values were found to be statistically equivalent to reference measurements.

Cardiac output and mixed venous oxygen content measurements by a tracer bolus method: theory.

We present a bolus method of inert-gas delivery to the lungs that facilitates application of multiple inert gases and the multiple inert-gas-exchange technique (MIGET) model to noninvasive measurements of cardiac output (CO) and central mixed venous oxygen content Reduction in recirculation error is made possible by 1) replacement of sinusoidal input functions with impulse inputs and 2) replacement of steady-state analyses with transient analyses. Recirculation error reduction increases the inert-gas selection to include common gases without unusually high (and difficult to find) tissue-to-blood partition coefficients for maximizing the systemic filtering efficiency. This paper also presents a practical method for determining the recirculation contributions to inert expired profiles in animals and determining their specific contributions to errors in the calculations of CO and from simulations applied to published ventilation-perfusion ratio (V/Q) profiles. Recirculation errors from common gases were found to be reducible to the order of 5% or less for both CO and whereas simulation studies indicate that measurement bias contributions from recirculation, V/Q mismatch, and the V/Q extraction process can be limited to 15% for subjects with severe V/Q mismatch and high inspired oxygen fraction levels. These studies demonstrate a decreasing influence of V/Q mismatch on parameter extraction bias as the number of inert gases are increased. However, the influence of measurement uncertainty on parameter extraction error limits improvement to six gases.

Gas-blood Pco2 and Po2 equilibration in a steady-state rebreathing dog preparation.

Alveolar gas and mixed venous blood PCO2 and PO2 were compared in a steady-state rebreathing dog preparation, during spontaneous breathing and mechanical ventilation, by a new null-balancing method that removes potential biases in the comparison of measurements in the blood and gas phases and includes an inert gas test to verify the equilibration between the rebreathing lung and the bag. No systematic PCO2 and PO2 differences were observed under equilibrium conditions. However, inert gas studies suggested that a high percentage of measurements obtained during spontaneous breathing were unreliable because of inadequate equilibration between blood and rebreathing bag (attributable to reduced ventilation or perfusion) and that all mechanical ventilation measurements were acceptable. The present data support the view that no PCO2 or PO2 gradients exist when the pulmonary capillary blood and alveolar gas are in equilibrium; the data also suggest that the steady-state rebreathing dog preparation may not be completely stable and that the time course of PCO2 and PO2 in the rebreathing bag may not be reliable as a means of assessing the equilibration between blood and bag.