Your search keyword '"Effros, Richard M."' showing total 6 results

1. Pulmonary vascular heterogeneity and the Starling hypothesis.

Author

Effros RM and Parker JC

Subjects

Animals, Biological Transport, Blood Vessels metabolism, Capillary Permeability, Humans, Hydrostatic Pressure, Lung metabolism, Microcirculation physiology, Microvessels metabolism, Proteins metabolism, Pulmonary Alveoli metabolism, Pulmonary Artery metabolism, Pulmonary Edema physiopathology, Lung blood supply, Osmotic Pressure, Pulmonary Alveoli blood supply, Pulmonary Circulation

Abstract

It has generally been assumed that movement of fluid between the pulmonary microvasculature and surrounding tissues is governed by a "Starling" balance of hydrostatic and protein osmotic forces similar to that which prevails in the extremities. However, both recent and older observations suggest that the lungs are more resistant to edema formation than most other organs. Several structural aspects of the lung may account for protection of the airspaces from edema formation. The pulmonary microvasculature, which comprises >70% of the pulmonary circulatory bed, appears to be less permeable to fluid and electrolytes than the endothelium of the pulmonary arteries and veins and other microvascular exchange areas. This arrangement may help explain why early edema is confined to the perivascular and peribronchial regions and why lymphatics do not reach the alveoli. Unlike the peripheral vasculature, which is compressed by edema formation, the extra-alveolar vessels remain tethered open by airway distention, even when interstitial pressures rise above those in the vessels. This may also facilitate return of proteins to the circulation. Ultrafiltration of plasma may lower local protein concentrations in the interstitium, thereby slowing further edema formation. Transendothelial reabsorption of fluid may also be altered by vesicular transport.

Published

2009

2. Exhaled breath condensate pH.

Author

Effros RM

Subjects

Breath Tests, Humans, Exhalation, Hydrogen-Ion Concentration, Lung metabolism, Pulmonary Disease, Chronic Obstructive metabolism, Saliva metabolism

Published

2006

3. Epithelial lining fluid solute concentrations in chronic obstructive lung disease patients and normal subjects.

Author

Effros RM, Peterson B, Casaburi R, Su J, Dunning M, Torday J, Biller J, and Shaker R

Subjects

Aged, Body Water metabolism, Calcium blood, Calcium metabolism, Case-Control Studies, Epithelium metabolism, Exhalation, Female, Humans, Isotonic Solutions metabolism, Magnesium blood, Magnesium metabolism, Male, Middle Aged, Osmolar Concentration, Potassium blood, Potassium metabolism, Saliva metabolism, Sodium blood, Sodium metabolism, Body Fluids metabolism, Lung metabolism, Pulmonary Disease, Chronic Obstructive metabolism

Abstract

The exhaled breath condensate (EBC) method represents a new, noninvasive way to detect inflammatory and metabolic markers in the fluid that covers the airways [epithelial lining fluid (ELF)]. However, respiratory droplets represent only a very small and variable fraction of the EBC, most (approximately 99.99%) of which is water vapor. Our objective was to show that ELF concentrations could be calculated from EBC values by using any of three dilutional indicators (urea, total cations, and conductivity) in nine normal and nine chronic obstructive lung disease (COPD) subjects. EBC concentrations of Na(+), K(+), Ca(2+), Mg(2+), total cations, urea, and conductivity varied over a 10-fold range among individuals, but concentrations of these constituents (except Ca(2+)) remained well correlated (r(2) = 0.44-0.83, P < 0.001). Dilution (D) of respiratory droplets in water vapor was calculated by dividing plasma concentrations of the dilutional indicators by EBC concentrations. Estimates of D were not significantly different among these indicators, and urea D averaged 10,800 +/- 2,100 (SE) in normal and 12,600 +/- 3,300 in COPD subjects. Although calculated Na(+) concentrations in the ELF were less than one-half those in plasma, and concentrations of K(+), Ca(2+), and Mg(2+) exceeded those in plasma, total cation concentrations in ELF were not significantly different from those in plasma, indicating that ELF is isotonic in both normal and COPD subjects. EBC amylase concentrations (measured with an ultrasensitive procedure) indicated that saliva represented <10% of the respiratory (ELF) droplets in all but three samples. Dilutional and salivary markers are essential for interpretation of EBC studies.

Published

2005

4. The effect of inhaled nitric oxide and oxygen on the hydroxylation of salicylate in rat lungs.

Author

Nelin LD, Morrisey JF, Effros RM, Dawson CA, and Schapira RM

Subjects

Animals, Hydroxybenzoates metabolism, Hydroxylation, Inhalation Exposure, Lung chemistry, Male, Organ Size, Rats, Rats, Sprague-Dawley, Regression Analysis, Lung metabolism, Nitric Oxide metabolism, Oxygen metabolism, Salicylates metabolism

Abstract

Inhaled nitric oxide (iNO) is used as a selective pulmonary vasodilator, and often under conditions when a high fraction of inspired oxygen is indicated. However, little is known about the potential toxicity of iNO therapy with or without concomitant oxygen therapy. NO can combine with superoxide (O2-) to form peroxynitrite (ONOO-), which can in turn decompose to form hydroxyl radical (OH.). Both OH. and ONOO- are involved in various forms of lung injury. To begin evaluation of the effect of iNO under either normoxic or hyperoxic conditions on OH. and/or ONOO- formation, rats were exposed for 58 h to either 21% O2, 21% O2 + 10 parts per million (ppm) NO, 21% O2 + 100 ppm NO, 50% O2, 90% O2, 90% O2 + 10 ppm NO, or 90% O2 + 100 ppm NO. We used a salicylate hydroxylation assay to detect the effects of these exposures on lung OH. and/or ONOO- formation measured as the appearance of 2,3-dihydroxybenzoic acid (2,3-DHBA). Exposure to 90% O2 and 90% O2 + 100 ppm NO resulted in significantly (p < 0.05) greater lung wet weight (1.99 +/- 0.14 g and 3.14 +/- 0.30 g, respectively) compared with 21% O2 (1.23 +/- 0.01 g). Exposure to 21% O2 + 100 ppm NO led to 2.5 times the control (21% O2 alone) 2,3 DHBA formation (p < 0.05) and exposure to 90% O2 led to 2.4 times the control 2,3-DHBA formation (p < 0.05). However, with exposure to both 90% O2 and 100 ppm NO, the 2,3-DHBA formation was no greater than the control condition (21% O2). Thus, these results indicate that, individually, both the hyperoxia and the 100 ppm NO led to greater salicylate hydroxylation, but that the combination of hyperoxia and 100 ppm NO led to less salicylate hydroxylation than either did individually. The production of OH. and/or ONOO- in the lung during iNO therapy may depend on the ratio of NO to O2.

Published

2003

5. Do low exhaled condensate NH4+ concentrations in asthma reflect reduced pulmonary production?

Author

Effros RM

Subjects

Breath Tests, Humans, Asthma metabolism, Lung metabolism, Quaternary Ammonium Compounds metabolism

Published

2003

6. Historical perspectives on lung edema clearance.

Author

Crandall ED and Effros RM

Subjects

Absorption, Animals, Biological Transport, Epithelium metabolism, Physiology trends, Body Fluids metabolism, Lung metabolism, Pulmonary Edema metabolism

Abstract

Early studies of fluid transport across the pulmonary epithelium were conducted in intact animals or isolated lungs. Although the location and cells responsible for transport cannot be determined with studies in whole mammalian lungs, such preparations remain indispensable for determining the physiological and clinical relevance of in vitro investigations of cells and their transport proteins. Three different approaches have been used to study transport and exchange between the vascular and air space compartments in intact lungs. Some of the advantages and limitations of these methods are briefly reviewed here.

Published

2002