Pulmonary circulation in experimental pulmonary edema during diverse artificial respiration regimes

In acute experiments on cats with closed chest by ultrasonic method the authors studied the blood flow in low-lobar pulmonary artery and the vein, the blood pressure in pulmonary artery, lung vessels resistance in experimental pulmonary edema caused by intravenous infusion of mixture fatty acids at artificial ventilation of increased frequencies or volumes, at was shown, that artificial ventilation of increased frequencies in pulmonary edema reduces the pressure increase in pulmonary artery, lung vessels resistance and increases the blood flow in pulmonary artery and vein. Artificial ventilation of increased volumes produces more intense pressure increase in pulmonary artery and lung vessels resistance than in initial ventilation but the blood flow was slightly changed. The authors assume that artificial ventilation of increased frequencies or volumes in pulmonary edema due to pulmonary circulation change reduces the pulmonary edema intensity at the beginning.     

Pulmonary circulation in embolic pulmonary edema

The ultrasonic method was used in acute experiments on cats with open chest under artificial lung ventilation to obtain blood flow in low-lobar pulmonary artery and vein, the blood pressure in pulmonary artery, as well as the left atrial pressure in fat (olive oil) and mechanical (Lycopodium spores) pulmonary embolism. It is shown that pulmonary embolism produces the decrease in the blood flow in pulmonary artery and vein, the increase of the pressure in pulmonary artery and left atria, the increase of lung vessels resistance. The decrease is observed of systemic arterial pressure, bradycardia, and extrasystole. After 5-10 min the restoration of arterial pressure and heart rhythm occur and partial restoration of blood flow in pulmonary artery and vein. In many experiments the blood flow in vein outdoes that in the artery--it allows to suppose the increase of the blood flow in bronchial artery. After 60-90 min there occur sudden decrease of systemic arterial pressure, the decrease of the blood flow in pulmonary artery and vein. The pressure in pulmonary artery and resistance of pulmonary vessels remain high. Pulmonary edema developed in all animals. The death occurs in 60-100 min after the beginning of embolism.     

Pulmonary and bronchial blood circulation under conditions of changed gaseous environment

By means of ultrasonic method used in acute experiments on cats with closed chest under normal respiration the authors studied the blood flow in left low-lobar pulmonary artery and vein and in bronchial artery, as well as the blood pressure in pulmonary and femoral arteries in inhalation of next gaseous mixtures: 7.5% O2 in nitrogen; 30% O2; 3% CO2; 21% O2+ +79% He; 30% O2 + 67% He + 3% CO2. It was shown, that inhalation of the normoxic gaseous mixture, in which nitrogen is replaced by helium, did not call significant changes in pulmonary and systemic circulation. However, the presence of the helium in complicated gaseous mixture can change the reactivity of pulmonary and bronchial vessels to influence the components participating in these complicated gaseous mixtures.     

A method to study pulmonary vascular response in the conscious newborn piglet

New methods for chronic instrumentation of the newborn piglet are described, which allow continuous monitoring of not only pressures in the pulmonary artery and aorta but also in the left and right atria, pulmonary vein, as well as main branch pulmonary artery flows. Changes in pulmonary vascular tone to short-acting vasoactive agents can be recognized by redistribution of flow between lungs and localized to the precapillary vessels or pulmonary veins. Furthermore, vasoactive response in small pulmonary veins may be investigated as well as selective metabolic studies across the right lung. Methods are also described for the chronic cannulation of the neck vessels permitting repeated introduction of catheters on separate study days in the conscious piglet. The pulmonary circulation of the piglet constricts briskly to moderate hypoxemia (PaO2 = 39.2 +/- 2 Torr, 1 Torr = 133.32 Pa) with little change in cardiac output or systemic resistance. The piglet demonstrated responses to dilator and constrictor prostaglandins generally similar to the lambs and other species. None of these agents significantly affect pulmonary venous tone.     

Stochastic Simulation of Human Pulmonary Blood Flow and Transit Time Frequency Distribution Based on Anatomic and Elasticity Data

The objective of our study was to develop a computing program for computing the transit time frequency distributions of red blood cell in human pulmonary circulation, based on our anatomic and elasticity data of blood vessels in human lung. A stochastic simulation model was introduced to simulate blood flow in human pulmonary circulation. In the stochastic simulation model, the connectivity data of pulmonary blood vessels in human lung was converted into a probability matrix. Based on this model, the transit time of red blood cell in human pulmonary circulation and the output blood pressure were studied. Additionally, the stochastic simulation model can be used to predict the changes of blood flow in human pulmonary circulation with the advantage of the lower computing cost and the higher flexibility. In conclusion, a stochastic simulation approach was introduced to simulate the blood flow in the hierarchical structure of a pulmonary circulation system, and to calculate the transit time distributions and the blood pressure outputs.     

Differential effects of prostaglandins A1 and A2 on pulmonary vascular resistance in the dog.

The effects of PGA1 and PGA2 were studied in the canine pulmonary vascular bed. Infusion of PGA1 into the lobar artery decreased lobar arterial and venous pressure but did not change left atrial pressure. In contrast, PGA2 infusion increased lobar arterial and venous pressure and the effects of this substance were similar in experiments in which the lung was perfused with dextran or with blood. These data indicate that under conditions of controlled blood flow PGA1 decreases pulmonary vascular resistance by dilating intrapulmonary veins and to a lesser extent vessels upstream to the small veins, presumably small arteries. The present data show that PGA2 increases pulmonary vascular resistance by constricting intrapulmonary veins and upstream vessels. The predominant effect of PGA2 was on upstream vessels and the pressor effect was not due to interaction with formed elements in the blood or platelet aggregation.     

Pulmonary circulation in different gaseous media

The ultrasonic method was used in acute experiments on cats with an open (under artificial lung ventilation) and closed chest to explore lung circulation in a changed gaseous medium. Moderate hypoxia (10% O2) and hypercapnia (5, 10% CO2) induce a 10-15% decrease in the lung blood flow in the inferolobular pulmonary artery in the presence of unchanged or slightly elevated minute volume of the heart. The higher hypoxia (5% O2) provokes inconclusive changes in the lung blood flow: biphasic response or increase. It is assumed that considerable elevation of blood pressure in the common pulmonary artery in all the cases points to vasoconstriction that occurs under the effect of hypoxia and hypercapnia.     

Hypoxia and angiotensin II infusion redistribute lung blood flow in lambs

To assess the effects of alveolar hypoxia and angiotensin II infusion on distribution of blood flow to the lung we performed perfusion lung scans on anesthetized mechanically ventilated lambs. Scans were obtained by injecting 1-2 mCi of technetium-labeled albumin macroaggregates as the lambs were ventilated with air, with 10-14% O2 in N2, or with air while receiving angiotensin II intravenously. We found that both alveolar hypoxia and infusion of angiotensin II increased pulmonary vascular resistance and redistributed blood flow from the mid and lower lung regions towards the upper posterior region of the lung. We assessed the effects of angiotensin II infusion on filtration pressure in six lambs by measuring the rate of lung lymph flow and the protein concentration of samples of lung lymph. We found that angiotensin II infusion increased pulmonary arterial pressure 50%, lung lymph flow 90%, and decreased the concentration of protein in lymph relative to plasma. These results are identical to those seen when filtration pressure increases during alveolar hypoxia. We conclude that alveolar hypoxia and angiotensin II infusion both increase fluid filtration in the lung by increasing filtration pressure. The increase in filtration pressure may be the result of a redistribution of blood flow in the lung with relative overperfusion of vessels in some areas and transmission of the elevated pulmonary arterial pressure to fluid-exchanging sites in those vessels.     

Influence of lung volume and left atrial pressure on reverse pulmonary venous blood flow

Infarction of the lung is uncommon even when both the pulmonary and the bronchial blood supplies are interrupted. We studied the possibility that a tidal reverse pulmonary venous flow is driven by the alternating distension and compression of alveolar and extra-alveolar vessels with the lung volume changes of breathing and also that a pulsatile reverse flow is caused by left atrial pressure transients. We infused SF6, a relatively insoluble inert gas, into the left atrium of anesthetized goats in which we had interrupted the left pulmonary artery and the bronchial circulation. SF6 was measured in the left lung exhalate as a reflection of the reverse pulmonary venous flow. No SF6 was exhaled when the pulmonary veins were occluded. SF6 was exhaled in increasing amounts as left atrial pressure, tidal volume, and ventilatory rates rose during mechanical ventilation. SF6 was not excreted when we increased left atrial pressure transients by causing mitral insufficiency in the absence of lung volume changes (continuous flow ventilation). Markers injected into the left atrial blood reached the alveolar capillaries. We conclude that reverse pulmonary venous flow is driven by tidal ventilation but not by left atrial pressure transients. It reaches the alveoli and could nourish the alveolar tissues when there is no inflow of arterial blood.     

Acute increases in anastomotic bronchial systemic to pulmonary blood flow due to generalized lung injury

Since pulmonary blood flow to regions involved in adult respiratory disease syndrome (ARDS) is reduced by hypoxic vasoconstriction, compression by cuffs of edema, and local thromboses, we postulated that the bronchial circulation must enlarge to provide for the inflammatory response. We measured anastomotic bronchial systemic to pulmonary blood flow [QBr(s-p)] serially in a lung lobe in 31 open-chest dogs following a generalized lobar injury simulating ARDS. The pulmonary circulation of the weighed left lower lobe (LLL) was isolated and perfused (zone 2) with autologous blood in anesthetized dogs. QBr(s-p) was measured from the amount of blood which overflowed from this closed vascular circuit corrected by any changes in the lobe weight. The LLL was ventilated with 5% CO2 in air. The systemic blood pressure (volume infusion), gases, and acid-base status (right lung ventilation) were kept constant. We injured the LLL via the airway by instilling either 0.1 N HCl or a mixture of glucose and glucose oxidase or via the pulmonary vessels by injecting either alpha-naphthylthiourea or oleic acid into the LLL pulmonary artery. In both types of injury, there was a prompt rise in QBr(s-p) (mean rise = 247% compared with control), which was sustained for the 2 h of observation. The cause of this increase in flow was studied. Control instillation of normal saline into the airways or into the pulmonary vessels did not change QBr(s-p) nor did a similar increase in lobar fluid (weight) due to hydrostatic edema. Neither cardiac output nor systemic blood pressure increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pulmonary vascular effects of Leu5-enkephalin in conscious newborn lambs

Anatomic evidence suggests that leu5-enkephalin (Leu5-enk) may be involved in the physiologic control of pulmonary vascular tone. Information regarding its pulmonary vascular effect is limited; we therefore studied its effect on the immature pulmonary circulation. Normoxic and hypoxic unsedated newborn lambs with chronically implanted flow probes around the right and left pulmonary arteries were used. Leu5-enk was injected into one pulmonary artery only, so that any direct effect of the peptide on the pulmonary vessels could be determined by measuring changes in the ratio of blood flow to the injected versus the non-injected lung. Leu5-enk caused a small but significant increase in pulmonary artery pressure without increasing cardiac output or left atrial pressure (threshold = 1 microgram/kg); it is therefore a pulmonary vasoconstrictor. At a dose of 10 micrograms/kg, Leu5-enk also raised pulmonary artery pressure (20.6 mmHg to 23.9 mmHg; F(8,36) = 15.1 p less than 0.001) and calculated PAR (14.6 to 16.1 units; NS). However, the ratio of blood flow to the two lungs did not change; thus, Leu5-enk does not appear to directly act on pulmonary vessels, but rather through an intermediary to produce pulmonary vasoconstriction. This indirect pulmonary vasoconstriction was blocked by pretreatment with naloxone (3 mg/kg). We conclude that Leu5-enk is a pulmonary vasoconstrictor, albeit a weak one, in the lamb and may therefore play a role in pulmonary vascular homeostasis. This vasoconstriction does not seem to be due to a direct effect on pulmonary vessels by Leu5-enk, but may be effected through a neural or hormonal intermediary.     

Physiological characteristics of the smooth muscles vessels of the small circle of blood circulation

Now sireos problem of pulmonology there are the diseases connected with infringement of coordinated regulation of a tone of smooth muscles of vessels and airways of ways that conducts to dissociation of parameters haemodinamyc and ventilation of lungs and as consequence, to infringement airwave-perfusion attitudes. In the review features humoral regulation contractile activity of smooth muscles of vessels of a small circle of blood circulation, a role of endocellular alarm systems in these mechanisms, and endothelium, as the local modulator endocrine functions are considered. Disgusting muscles of a small circle are distinguished from the main vessels of the big circle of blood circulation with predisposition to the raised mechanical pressure. In spite of the fact that endothelium renders modulating relaxe influence on contractile answers of smooth muscles of vessels of a venous and arterial small circle of blood circulation at action corresponding vasoconstriction, pulmonary veins are capable to endothelium-dependent dilatation to a lesser degree, in comparison with pulmonary arteries. And, on the contrary, in absence endothelium, they are characterized with high sensitivity to vasopression to substances--serotonin, histamine, phenylephrine. Features of regulation smooth muscle pressure pulmonary an artery are shown in contractile reactions of its isolated segments in reply to influence beta-adreno agonist--isoprotherenol and phosphoesterase inhibitors. Though, increase in endocellular concentration cyclic nucleotides (cAMP and\or cGMP), on the standard representations, cannot explain growth of a mechanical pressure of smooth muscles, apparently, in contractile reactions of a pulmonary artery to influence biologically and physiologically active substances interfere more complex mechanisms in which basis processes of interaction of smooth muscles cells lay, endothelium and cells of a microenvironment. Finding-out of the contribution cyclic nucleotides in these processes demands the further researches.     

Extra-alveolar vessel fluid filtration coefficients in excised and in situ canine lobes

We continuously weighed fully distended excised or in situ canine lobes to estimate the fluid filtration coefficient (Kf) of the arterial and venous extra-alveolar vessels compared with that of the entire pulmonary circulation. Alveolar pressure was held constant at 25 cmH2O after full inflation. In the in situ lobes, the bronchial circulation was interrupted by embolization. Kf was estimated by two methods (Drake and Goldberg). Extra-alveolar vessels were isolated from alveolar vessels by embolizing enough 37- to 74-micron polystyrene beads into the lobar artery or vein to completely stop flow. In excised lobes, Kf's of the entire pulmonary circulation by the Drake and Goldberg methods were 0.122 +/- 0.041 (mean +/- SD) and 0.210 +/- 0.080 ml X min-1 X mmHg-1 X 100 g lung-1, respectively. Embolization was not found to increase the Kf's. The mean Kf's of the arterial extra-alveolar vessels were 0.068 +/- 0.014 (Drake) and 0.069 +/- 0.014 (Goldberg) (24 and 33% of the Kf's for the total pulmonary circulation). The mean Kf's of the venous extra-alveolar vessels were similar [0.046 +/- 0.020 (Drake) and 0.065 +/- 0.036 (Goldberg) or 33 and 35% of the Kf's for the total circulation]. No significant difference was found between the extra-alveolar vessel Kf's of in situ vs. excised lobes. These results suggest that when alveolar pressure, lung volume, and pulmonary vascular pressures are high, approximately one-third of the total fluid filtration comes from each of the three compartments.     

Teaching the effects of gravity and intravascular and alveolar pressures on the distribution of pulmonary blood flow using a classic paper by West et al

"Distribution of blood flow in isolated lung; relation to vascular and alveolar pressures" by J. B. West, C. T. Dollery, and A. Naimark (J Appl Physiol 19: 713-724, 1964) is a classic paper, although it has not yet been included in the Essays on the American Physiological Society Classic Papers Project (http://www.the-aps.org/publications/classics/). This is the paper that originally described the "zones of the lung." The final figure in the paper, which synthesizes the results and discussion, is now seen in most textbooks of physiology or respiratory physiology. The paper is also a model of clear, concise writing. The paper and its final figure can be used to teach or review a number of physiological concepts. These include the effects of gravity on pulmonary blood flow and pulmonary vascular resistance; recruitment and distention of pulmonary vessels; the importance of the transmural pressure on the diameter of collapsible distensible vessels; the Starling resistor; the interplay of the pulmonary artery, pulmonary vein, and alveolar pressures; and the vascular waterfall. In addition, the figure can be used to generate discovery learning and discussion of several physiological or pathophysiological effects on pulmonary vascular resistance and the distribution of pulmonary blood flow.     

Effects of obsidan on the development of pulmonary edema and hemodynamics of the lesser circulation after administration of noradrenaline

In experiments on white rats, guinea pigs and cats it was shown that preliminary infusion of propranolol sharply increases the edemagenous lungs sensitiveness to the infusion of exogenous norepinephrine of white rats and guinea pigs. The infusion of the propranolol to cats leads to a decrease of volume blood flow velocity in the pulmonary artery with the simultaneous difficulty of the outflow in pulmonary veins and to increase of hydrostatic pressure in the lesser circulation. The infusion on that background of epinephrine called the development of temporary sharp hearts failure with the sharp increase of the pressure in pulmonary artery (to 196%) and systemic pressure.     

Numerical simulation of blood flow and pressure drop in the pulmonary arterial and venous circulation

A novel multiscale mathematical and computational model of the pulmonary circulation is presented and used to analyse both arterial and venous pressure and flow. This work is a major advance over previous studies by Olufsen et al. (Ann Biomed Eng 28:1281–1299, 2012) which only considered the arterial circulation. For the first three generations of vessels within the pulmonary circulation, geometry is specified from patient-specific measurements obtained using magnetic resonance imaging (MRI). Blood flow and pressure in the larger arteries and veins are predicted using a nonlinear, cross-sectional-area-averaged system of equations for a Newtonian fluid in an elastic tube. Inflow into the main pulmonary artery is obtained from MRI measurements, while pressure entering the left atrium from the main pulmonary vein is kept constant at the normal mean value of 2 mmHg. Each terminal vessel in the network of ‘large’ arteries is connected to its corresponding terminal vein via a network of vessels representing the vascular bed of smaller arteries and veins. We develop and implement an algorithm to calculate the admittance of each vascular bed, using bifurcating structured trees and recursion. The structured-tree models take into account the geometry and material properties of the ‘smaller’ arteries and veins of radii \(\ge \) 50  \(\upmu \) m. We study the effects on flow and pressure associated with three classes of pulmonary hypertension expressed via stiffening of larger and smaller vessels, and vascular rarefaction. The results of simulating these pathological conditions are in agreement with clinical observations, showing that the model has potential for assisting with diagnosis and treatment for circulatory diseases within the lung.     

The effect of closing the ductus arteriosus on the pulmonary circulation of the fetal sheep

In the mammalian fetus the ductus arteriosus allows right ventricular output to be shunted away from the lungs to the systemic circulation. This study was performed to determine how closing the ductus arteriosus of the fetal sheep would affect the pulmonary circulation. Under halothane anaesthesia 6 near-term fetal sheep were delivered with the umbilical circulation intact. Catheters were placed in the right atrium, the pulmonary artery, and the aorta. Pulmonary blood flow was measured by injecting radioactive microspheres into the right atrium while a reference sample was withdrawn from the pulmonary artery. Closing the ductus arteriosus increased pulmonary arterial pressure by 22% from 51 +/- 3 to 62 +/- 3 mmHg and increased pulmonary blood flow disproportionately by 198% from 232 +/- 74 to 692 +/- 80 ml/min per 100g. Thus, pulmonary vascular resistance decreased by 75% from 0.451 +/- 0.65 to 0.095 +/- 0.010 mmHg 100g min/ml. These findings extend the observation that pressure and flow in the pulmonary circulation of the air-breathing lung do not have a linear relationship passing through the origin to include a striking example in the fluid-filled lung of the intact fetus. They also raise questions about the nature of the elevated vascular resistance in the fetal lung.     

Pressure in the pulmonary artery and transbronchial electroplethysmography in rats

A complex technique for pulmonary circulation study involving catheterization of pulmonary artery and transbronchial electroplethysmography has been tested in rats. The technique permits pulmonary artery pressure measurement and registration of electrical resistance in the lung lobe of closed-chest animals with the subsequent estimation of blood flow, blood volume and air content in the lungs expressed in adequate units per unit of organ volume. The experimental data characterizing standard values of the above parameters in rats are presented.     

Effect of furosemide on pulmonary blood flow distribution in resting and exercising horses.

We determined the spatial distribution of pulmonary blood flow (PBF) with 15-micron fluorescent-labeled microspheres during rest and exercise in five Thoroughbred horses before and 4 h after furosemide administration (0.5 mg/kg iv). The primary finding of this study was that PBF redistribution occurred from rest to exercise, both with and without furosemide. However, there was less blood flow to the dorsal portion of the lung during exercise postfurosemide compared with prefurosemide. Furosemide did alter the resting perfusion distribution by increasing the flow to the ventral regions of the lung; however, that increase in flow was abated with exercise. Other findings included 1) unchanged gas exchange and cardiac output during rest and exercise after vs. before furosemide, 2) a decrease in pulmonary arterial pressure after furosemide, 3) an increase in the slope of the relationship of PBF vs. vertical height up the lung during exercise, both with and without furosemide, and 4) a decrease in blood flow to the dorsal region of the lung at rest after furosemide. Pulmonary perfusion variability within the lung may be a function of the anatomy of the pulmonary vessels that results in a predominantly fixed spatial pattern of flow distribution.     

Redistribution in left ventricular regional flow following acute right ventricular pressure overload

The left ventricular dysfunction following acute pulmowary hypertension remains unexplained. We wondered if acute pulmonary hypertension could alter the transmural flow distribution within the left ventricular myocardium, independent of coronary flow and perfusion pressure. We used a canine preparation in which the left coronary system was perfused at constant flow and induced a two- to three-fold increase in pulmonary artery pressure by banding the pulmonary artery. Regional myocardial blood flow of the left coronary system was measured using radioactive microspheres, injected into the left coronary system before and after 10-30 min of banding of the pulmonary artery. The left ventricular subendocardial:epicardial ratio fell by 12 and 31% (p less than 0.05) of control value, 10 and 30 min, respectively, after banding of the pulmonary artery, the total flow to the left coronary system being kept constant. Left atrial mean pressure increased from 2.9 +/- 2.4 to 3.6 +/- 1.9 and 6.0 +/- 2.1 (p less than 0.05) following banding. The mechanism of the redistribution of coronary flow may relate to inappropriate vasodilation of the right septal myocardium with consequent relative left ventricular subendocardial hypoperfusion which might aggravate left ventricular ischemia in the presence of hypotension and hypoxia.