Your search keyword '"Kays, C"' showing total 3 results

1. In vivo estimates of NO and CO conductance for haemoglobin and for lung transfer in humans.

Author

Guénard HJ, Martinot JB, Martin S, Maury B, Lalande S, and Kays C

Subjects

Adult, Aged, Capillaries metabolism, Carbon Monoxide blood, Female, Humans, Linear Models, Lung blood supply, Male, Middle Aged, Nitric Oxide blood, Oxygen metabolism, Pressure, Pulmonary Diffusing Capacity, Young Adult, Carbon Monoxide metabolism, Hemoglobins metabolism, Lung metabolism, Models, Cardiovascular, Nitric Oxide metabolism, Pulmonary Gas Exchange

Abstract

Membrane conductance (Dm) and capillary lung volume (Vc) derived from NO and CO lung transfer measurements in humans depend on the blood conductance (θ) values of both gases. Many θ values have been proposed in the literature. In the present study, measurements of CO and NO transfer while breathing 15% or 21% O2 allowed the estimation of θNO and the calculation of the optimal equation relating 1/θCO to pulmonary capillary oxygen pressure (PcapO2). In 10 healthy subjects, the mean calculated θNO value was similar to the θNO value previously reported in the literature (4.5mmHgmin(-1)) provided that one among three θCO equations from the literature was chosen. Setting 1/θCO=a·PcapO2+b, optimal values of a and b could be chosen using two methods: 1) by minimizing the difference between Dm/Vc ratios for any PcapO2, 2) by establishing a linear equation relating a and b. Using these methods, we are proposing the equation 1/θCO=0.0062·PcapO2+1.16, which is similar to two equations previously reported in the literature. With this set of θ values, DmCO reached the morphometric range., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

2. Improvement of brain-dead lung assessment based on the mechanical properties of the respiratory system.

Author

Labrousse L, Sztark F, Kays C, Thicoïpe M, Lassié P, Couraud L, and Marthan R

Subjects

Elasticity, Humans, Lung physiopathology, Respiration, Artificial, Viscosity, Brain Death physiopathology, Lung physiology, Lung Transplantation, Tissue Donors

Published

1996

3. Effect of gravity on chest wall mechanics

Author

O. Bailliart, Giuseppe Miserocchi, P. Vaida, D. Bettinelli, C. Kays, Pierre Techoueyres, Jean-Luc Lachaud, André Capderou, Bettinelli, D, Kays, C, Bailliart, O, Capderou, A, Techoueyres, P, Lachaud, J, Vaida, P, and Miserocchi, G

Subjects

Thorax, Male, medicine.medical_specialty, Gravity (chemistry), Physiology, Vital Capacity, Respiratory physiology, Chest wall mechanics, Physiology (medical), Internal medicine, medicine, Pressure, Humans, Lung volumes, Lung, Physics, Weightlessness, Total Lung Capacity, chest wall resting volume, Middle Aged, chest wall compliance, Surgery, Compliance (physiology), Residual Volume, Volume (thermodynamics), Inhalation, Cardiology, Respiratory Mechanics, esophageal pressure, Female, Lung Volume Measurements, supine posture, Compliance, Gravitation

Abstract

Chest wall mechanics was studied in four subjects on changing gravity in the craniocaudal direction (Gz) during parabolic flights. The thorax appears very compliant at 0 Gz: its recoil changes only from −2 to 2 cmH2O in the volume range of 30–70% vital capacity (VC). Increasing Gz from 0 to 1 and 1.8 Gzprogressively shifted the volume-pressure curve of the chest wall to the left and also caused a fivefold exponential decrease in compliance. For lung volume z than from 1 to 1.8 Gz. For a volume from 30 to 70% VC, the effect is inspiratory going from 0 to 1 Gz but expiratory from 1 to 1.8 Gz. For a volume greater than ∼70% VC, gravity always has an expiratory effect. The data suggest that the chest wall does not behave as a linear system when exposed to changing gravity, as the effect depends on both chest wall volume and magnitude of Gz.

Published

2002