Search results for "Respiratory Dead Space"

showing 3 items of 3 documents

Differential contribution of dead space ventilation and low arterial pCO2 to exercise hyperpnea in patients with chronic heart failure secondary to i…

2003

In chronic heart failure (CHF), the abnormally large ventilatory response to exercise (VE/VCO(2) slope) has 2 conceptual elements: the requirement of restraining arterial partial pressure of carbon dioxide (pCO(2)) from increasing (because of an increased ratio between increased physiologic dead space and tidal volume [VD/VT]) and the depression of arterial pCO(2) by further increased ventilation, which necessarily implies an important non-carbon dioxide stimulus to ventilation. We aimed to assess the contribution of these 2 factors in determining the elevated VE/VCO(2) slope in CHF. Thirty patients with CHF underwent cardiopulmonary exercise testing (age 65 +/- 11 years, left ventricular e…

Cardiomyopathy DilatedMalemedicine.medical_specialtyPartial PressureMyocardial IschemiaHyperpneaHypercapniaInternal medicineIdiopathic dilated cardiomyopathymedicineHumansTidal volumeAgedEjection fractionbusiness.industryVO2 maxRespiratory Dead SpaceCarbon DioxideMiddle Agedmedicine.diseasePulmonary AlveoliHeart failureExercise TestCardiologyBreathingFemaleAcidosis RespiratoryBlood Gas Analysismedicine.symptomPulmonary VentilationCardiology and Cardiovascular Medicinebusinesshuman activitiesHypercapniaThe American Journal of Cardiology
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Measurement of phase I volume breath by breath in spontaneously breathing guinea pigs.

1990

A new method to determine phase I volume in tracheotomized spontaneously breathing guinea pigs is presented. Measurements were performed in three animals weighing 567-896 g. In simultaneous tracings of tidal volume (VT) and expiratory profiles of endogenous gases (PO2 or PCO2), the phase I volume of each breath was determined graphically as the volume expired up to the end of phase I of the expirogram. The mean phase I volume of different animals ranged from 0.29 to 0.43 ml with an arithmetic dispersion between 0.014 and 0.021 ml. Spontaneous sighs sometimes with doubling of the VT caused a significant rise of phase I volume up to 50% of the normal values. The linear regression curve was c…

MalePhysiologybusiness.industryChemistryPulmonary Gas ExchangeGuinea PigsBronchiRespiratory Dead SpacepCO2Volume (thermodynamics)Physiology (medical)AnesthesiaRespirationBreathingRespiratory MechanicsTidal VolumePlethysmographAnimalsLung volumesFemaleRespiratory systemNuclear medicinebusinessTidal volumePlethysmography Whole BodyJournal of applied physiology (Bethesda, Md. : 1985)
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Theoretical Analysis of Factors Influencing Recovery of Ventilation Distributions from Inert Gas Washout Data

1990

For the quantitative analysis of intraregional ventilation inhomogeneities, one classically applies the inert gas washout method [7,24] in which an inert gas of negligible solubility in blood and tissue is washed into the lungs. After washin is complete, the inspiratory inert gas fraction is set to a smaller value and the time course of the mixed endexpiratory inert gas fraction during the subsequent inert gas washout is recorded. The determinants of this time course are: The endexpiratory alveolar volume at the instant of change in inspiratory inert gas fraction, the anatomical dead space, the gas exchange ratio, the respiratory frequency, the in- and expiratory tidal volumes, and the inho…

Washout (aeronautics)ChromatographylawChemistryDead spaceVentilation (architecture)Respiratory Dead SpaceFraction (chemistry)MechanicsAlveolar volumeInert gasTidal volumelaw.invention
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