Cardiac output: a view from Buffalo

Cardiac output: a view from Buffalo

Cardiac output (Q) is a primary determinant of blood pressure and O2 delivery and is critical in the maintenance of homeostasis, particularly during environmental stress. Cardiac output can be determined invasively in patients; however, indirect methods are required for other situations. Soluble gas...

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Bibliographic Details
Published in:European journal of applied physiology 2003-10, Vol.90 (3-4), p.292-304
Main Authors: Olszowka, A J, Shykoff, B E, Pendergast, D R, Lundgren, C E G, Farhi, L E
Format: Article
Language:eng
Subjects:
Algorithms
Blood Flow Velocity - physiology
Blood pressure
Carbon Dioxide - blood
Carbon Dioxide - metabolism
Cardiac Output - physiology
Diving - physiology
Exercise - physiology
Exhalation - physiology
Gravitation
Humans
Hypoxia - physiopathology
Immersion - physiopathology
Inhalation - physiology
New York
Oxygen - blood
Oxygen - metabolism
Partial Pressure
Pulmonary Gas Exchange - physiology
Pulmonary Ventilation - physiology
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Summary:Cardiac output (Q) is a primary determinant of blood pressure and O2 delivery and is critical in the maintenance of homeostasis, particularly during environmental stress. Cardiac output can be determined invasively in patients; however, indirect methods are required for other situations. Soluble gas techniques are widely used to determine Q. Historically, measurements during a breathhold, prolonged expiration and rebreathing to CO2 equilibrium have been used; however, with limitations, especially during stress. Farhi and co-workers developed a single-step CO2 rebreathing method, which was subsequently revised by his group, and has been shown to be valid (compared to direct measures) and reliable. Carbon dioxide output (VCO2), partial pressure of arterial CO2 (PaCO2), and partial pressure of mixed venous CO2 (Pv(CO2)) are determined during 12-25 s of rebreathing, using the appropriate tidal volume, and Q is calculated. This method has the utility to provide accurate data in laboratory and field experiments during exercise, increased and micro-gravity, water immersion, lower body pressure, head-down tilt, and changes in gas composition and pressure. Utilizing the Buffalo CO2 rebreathing method it has been shown that the Q can adjust to a wide range of changes in environments maintaining blood pressure and O2 delivery at rest and during exercise.
ISSN:1439-6319
1439-6327