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.     

Pulmonary circulation in experimental toxic edema of the lungs

By means of ultrasonic method used in acute experiments on cats with open chest under artificial lung ventilation the authors studied the blood flow in low-lobar pulmonary artery and the vein, the blood pressure in pulmonary artery as well as the balance between output of right and left ventricles in experimental pulmonary edemas caused by intravenous infusion of mixture fatty acids. It was shown, that acute injury of lungs vessels produces redistribution of blood flow to the lesser circulation, increases the pressure in pulmonary artery. The pattern of pulsating blood flow in lobar artery and vein changes. The authors assume that in situation, when lung vessels permeability is already deranged redistribution of the blood to the lesser circulation aggravates the degree of edema.     

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.     

Perfluoro compounds as artificial erythrocytes.

Some liquid perfluoro compounds dissolve relatively large amounts of oxygen and can be used in dispersed form as substitutes for erythrocytes. The commonly used perfluoro compounds contain about the same amount of oxygen as do equal volumes of erythrocytes when equilibrated with 100% oxygen. However, when equilibrated with alveolar air, the perfluoro compounds contain much less oxygen than erythrocytes. The dispersed fluorochemicals are adequate substitutes for perfusion of isolated preparations of mammalian brain, heart kidney, lung and liver. However, when put into the circulation of the intact animal, the dispersed fluorochemicals tends to produce lesions of the lungs, dilation of the right heart, and ultimately fatal hypoxia. It is suggested that the course of events following intravenous injection of dispersed fluorochemical is initiated by an interaction of the perfluoro particles with blood platelets or blood clotting factors. The ensuing intravascular clotting could then cause the changes in the lungs which lead to a marked increase in pulmonary artery pressure and dilation of the right heart. These events would terminate in fatal hypoxia due to pulmonary pathology and heart failure.     

Functional Anatomy of the Hearts of Lungfishes and Amphibians

Lungfishes and amphibians have bimodal gas exchange, but variousspecies employ airbreathing with lungs to different degrees.An increased use of pulmonary breathing is correlated with progressivestructural and functional separation of the pulmonary and systemicvascular circuits. Representatives from all genera of lungfishesand several anurans and urodeles utilizing pulmonary breathing,show a preferential distribution of blood tending to minimizerecirculation to the systemic and pulmonary circuits. The degreeof shunting between the two circuits is variable and may expressnormal shifts in regional blood flow. The most important structural and functional features influencingthe preferential circulation through dipnoan and amphibian heartsinclude: (a) Dynamics of inflow in the pulmonary and systemicveins; (b) The extent and localization of atrial septation;(c) The partial ventricular septum in lungfishes and the massiveventricular trabeculation in both amphibians and lungfishes;(d) A laminar ventricular outflow pattern; (e) Structural guidanceof flow in the partially separated bulbus segment of the heart;(f) Vasomotor reactions in the various outflow vessels fromthe heart.     

Effect of respiratory gases on compliance of intrapulmonary arteries and veins

A method was developed that permitted changes in the pressure-volume characteristics of large intrapulmonary vessels occurring with changes in the composition of alveolar gas to be studied in excised lungs. The capillary bed was emptied by keeping intravascular pressure well below alveolar pressure, and the relationship between changes in the volume of the pulmonary arteries or veins with changes in transpulmonary pressure was measured. The volume of the arteries and veins always decreased with a decrease in transpulmonary pressure, but when the alveoli contained carbon dioxide, the decrease in vascular volume was less, for the same decrease in transpulmonary pressure, than when the alveoli contained oxygen or nitrogen without carbon dioxide. This change with carbon dioxide was probably due to a decrease in the compliance of the larger intrapulmonary arteries and veins. Since there was no pathway for carbon dioxide to enter these vessels except by diffusion from the alveoli, it is concluded that carbon dioxide can act directly on the intrapulmonary arteries and veins to reduce their compliance, but it is not known whether this effect has physiological significance. No effect on the large pulmonary vessels was found with variations in alveolar concentrations of oxygen. blood vesselsblood volumecarbon dioxidediffusionlungspulmonary circulation     

Pulmonary hemodynamics in fetal lambs during development at normal and increased oxygen tension.

During the latter third of gestation, the number of resistance vessels in the lungs of the fetal sheep increases by 10-fold even after correction for lung growth. We measured pulmonary arterial pressure and blood flow directly and calculated total pulmonary resistance (pressure divided by flow) in intrauterine fetal lambs at 93-95 days and at 136 days of gestation (term is 145-148 days). In addition, we used a hyperbaric chamber to increase oxygen tension in the fetuses and measured the effect on the pulmonary circulation. When corrected for wet weight of the lungs, pulmonary blood flow did not change with advancing gestation (139 +/- 42 to 103 +/- 45 ml.100 g-1.min-1). Pulmonary arterial pressure increased (42 +/- 5 to 49 +/- 3 mmHg); thus total pulmonary resistance increased with advancing gestation from 0.32 +/- 0.12 to 0.55 +/- 0.21 mmHg.100 g.min.ml-1. If the blood flow is corrected for dry weight of the lungs, neither pulmonary blood flow nor total pulmonary resistance changed with advancing gestation. Increasing oxygen tension increased pulmonary blood flow 10-fold in the more mature fetuses but only 0.2-fold in the less mature fetuses. At the normal low oxygen tension of the fetus, pulmonary blood flow does not increase between these two points of gestation in the fetal lamb despite the increase in vessel density in the lungs. However, during elevated oxygen tension, pulmonary blood flow does increase in proportion to the increase in vessel density.     

Copper deficiency and cardiovascular disease: role of peroxidation, glycation, and nitration

Dietary copper deficiency causes a variety of cardiovascular deficits. Systemic effects include high blood pressure, enhancement of inflammation, anemia, reduced blood clotting, and possibly arteriosclerosis. Effects on specific organs or tissues include weakened structural integrity of the heart and blood vessels, impairment of energy use by the heart, reduced ability of the heart to contract, altered ability of blood vessels to control their diameter and grow, and altered structure and function of circulating blood cells. In some instances, the cause of a defect can be directly attributed to reduced activity of a specific copper-dependent enzyme. However, three nonspecific mechanisms of damage have been implicated in cardiovascular defects of copper deficiency. They are peroxidation, the interaction of oxygen-derived free radicals with lipids and proteins (possibly DNA); glycation, the nonenzymatic glycosylation of proteins; and nitration, the interaction of nitric oxide and its metabolites with peptides and proteins. Though independently these mechanisms present great potential for damage, the possibility that they may interact presents an added reason for concern. Furthermore, the fact that at least two of these mechanisms are associated with diabetes and aging suggests that copper deficiency may exacerbate deficits associated with these two conditions.     

Effect of lung inflation on lung blood volume and pulmonary venous flow

Phasic changes in lung blood volume (LBV) during the respiratory cycle may play an important role in the genesis of the respiratory wave in arterial pressure, or pulsus paradoxus. To better understand the effects of lung inflation on LBV, we studied the effect of changes in transpulmonary pressure (delta Ptp) on pulmonary venous flow (Qv) in eight isolated canine lungs with constant inflow. Inflation when the zone 2 condition was predominant resulted in transient decreases in Qv associated with increases in LBV. In contrast, inflation when the zone 3 condition was predominant resulted in transient increases in Qv associated with decreases in LBV. These findings are consistent with a model of the pulmonary vasculature that consists of alveolar and extra-alveolar vessels. Blood may be expelled from alveolar vessels but is retained in extra-alveolar vessels with each inflation. The net effect on LBV and thus on Qv is dependent on the zone conditions that predominate during inflation, with alveolar or extra-alveolar effects being greater when the zone 3 or zone 2 conditions predominate, respectively. Lung inflation may therefore result in either transiently augmented or diminished Qv. Phasic changes in left ventricular preload may therefore depend on the zone conditions of the lungs during the respiratory cycle. This may be an important modulator of respiratory variations in cardiac output and blood pressure.     

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.     

Modeling of the Norwood circulation: effects of shunt size, vascular resistances, and heart rate

Hypoplastic left heart syndrome is the most common lethal cardiac malformation of the newborn. Its treatment, apart from heart transplantation, is the Norwood operation. The initial procedure for this staged repair consists of reconstructing a circulation where a single outlet from the heart provides systemic perfusion and an interpositioning shunt contributes blood flow to the lungs. To better understand this unique physiology, a computational model of the Norwood circulation was constructed on the basis of compartmental analysis. Influences of shunt diameter, systemic and pulmonary vascular resistance, and heart rate on the cardiovascular dynamics and oxygenation were studied. Simulations showed that 1) larger shunts diverted an increased proportion of cardiac output to the lungs, away from systemic perfusion, resulting in poorer O2 delivery, 2) systemic vascular resistance exerted more effect on hemodynamics than pulmonary vascular resistance, 3) systemic arterial oxygenation was minimally influenced by heart rate changes, 4) there was a better correlation between venous O2 saturation and O2 delivery than between arterial O2 saturation and O2 delivery, and 5) a pulmonary-to-systemic blood flow ratio of 1 resulted in optimal O2 delivery in all physiological states and shunt sizes.     

MIcrocirculatory bed of various internal organs in modeling of the inter-atrial shunt

At modelling a congenital heart failure--defect of the interatrial septum during late stages of the experiment, dilatation of the pulmonary artery and certain changes in the microcirculatory bed of the lungs, oesophagus, stomach and colon are observed. It has been demonstrated histologically and morphometrically that in adaptive reactions of the blood bed an important role belongs to the arteriolar part and metabolic link of the microcirculatory bed of the organs investigated. The changes in the pulmonary vessels are insufficiently expressed and possibility of hypertension in the lesser circulation is not great.     

Microvascular pressures measured by micropipettes in isolated edematous rabbit lungs

To study the mechanical effects of lung edema on the pulmonary circulation, we determined the longitudinal distribution of vascular resistance in the arteries, veins, and microvessels, and the distribution of blood flow in isolated blood-perfused rabbit lungs with varying degrees of edema. Active vasomotor changes were eliminated by adding papaverine to the perfusate. In three groups of lungs with either minimal [group I, mean wet-to-dry weight ratio (W/D) = 5.3 +/- 0.6 (SD), n = 7], moderate (group II, W/D = 8.5 +/- 1.2, n = 10), or severe (group III, W/D = 9.9 +/- 1.6, n = 5) edema, we measured by direct micropuncture the pressure in subpleural arterioles and venules (20-60 micron diam) and in the interstitium surrounding these vessels. We also measured pulmonary arterial and left atrial pressures and lung blood flow, and in four additional experiments we used radio-labeled microspheres to determine the distribution of blood flow during mild and severe pulmonary edema. In lungs with little or no edema (group I) we found that 33% of total vascular pressure drop was in arteries, 60% was in microvessels, and 7% was in veins. Moderate edema (group II) had no effect on total vascular resistance or on the vascular pressure profile, but severe edema (group III) did increase vascular resistance without changing the longitudinal distribution of vascular resistance in the subpleural microcirculation. Perivascular interstitial pressure relative to pleural pressure increased from 1 cmH2O in group I to 2 in group II to 4 in group III lungs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Perinatal history of hypoxia leads to lower vascular pressures and hyporeactivity to angiotensin II in isolated lungs of adult rats

The most dramatic changes in pulmonary circulation occur at the time of birth. We hypothesized that some of the effects of perinatal hypoxia on pulmonary vessels are permanent. We studied the consequences of perinatal exposure to hypoxia (12 % O2 one week before and one week after birth) in isolated lungs of adult male rats (approximately 12 weeks old) perfused with homologous blood. Perfusion pressure-flow relationship was tilted towards lower pressures in the perinatally hypoxic as compared to the control, perinatally normoxic rats. A non-linear, distensible vessel model analysis revealed that this was due to increased vascular distensibility in perinatally hypoxic rats (4.1 +/- 0.6 %/mm Hg vs. 2.3 +/- 0.4 %/mm Hg in controls, P = 0.03). Vascular occlusion techniques showed that lungs of the perinatally hypoxic rats had lower pressures at both the pre-capillary and post-capillary level. To assess its role, basal vascular tone was eliminated by a high dose of sodium nitroprusside (20 microM). This reduced perfusion pressures only in the lungs of rats born in hypoxia, indicating that perinatal hypoxia leads to a permanent increase in the basal tone of the pulmonary vessels. Pulmonary vasoconstrictor reactivity to angiotensin II (0.1-0.5 microg) was reduced in rats with the history of perinatal-hypoxia. These data show that perinatal hypoxia has permanent effects on the pulmonary circulation that may be beneficial and perhaps serve to offset the previously described adverse consequences.     

Patent ductus arteriosus in mice with smooth muscle-specific Jag1 deletion

The ductus arteriosus is an arterial vessel that shunts blood flow away from the lungs during fetal life, but normally occludes after birth to establish the adult circulation pattern. Failure of the ductus arteriosus to close after birth is termed patent ductus arteriosus and is one of the most common congenital heart defects. Mice with smooth muscle cell-specific deletion of Jag1, which encodes a Notch ligand, die postnatally from patent ductus arteriosus. These mice exhibit defects in contractile smooth muscle cell differentiation in the vascular wall of the ductus arteriosus and adjacent descending aorta. These defects arise through an inability to propagate the JAG1-Notch signal via lateral induction throughout the width of the vascular wall. Both heterotypic endothelial smooth muscle cell interactions and homotypic vascular smooth muscle cell interactions are required for normal patterning and differentiation of the ductus arteriosus and adjacent descending aorta. This new model for a common congenital heart defect provides novel insights into the genetic programs that underlie ductus arteriosus development and closure.     

A radiological study of the central circulation in the lungfish, Protopterus aethiopicus

The dipnoan heart is only in part structurally developed to support a separated circulation in pulmonary and systemic circuits. In the present investigation biplane angiocardiography has been used to describe the extent of such a double circulation and the factors which may modify it in the African lungfish, Protopterus aethiopicus. Contrast injections in the pulmonary vein revealed a clear tendency for aerated blood returing from the lungs to be selectively dispatched to the anterior branchial arteries giving rise to the major systemic circulation. Contrast injections in the vena cava delineated the sinus venosus as a large receiving chamber for systemic venous blood. Contraction of the sinus venosus discharged blood into the right, posterior part of the partially divided atrial space. Contrast injection in the pulmonary vein showed that vessel to pass obliquely from right to left such that blood was emptied distinctly into the left side of the atrium. During contraction the atrial space tended to retain a residual volume in its anterior undivided part which minized mixing. Ventricular filling occurred through separate right and left atrio-ventricular connections. Right-left separation in most of the ventricle was maintained by the partial ventricular septum, the trabeculated, spongelike myocardium and the mode of inflow from the atria. Mixing in the anterior undivided portion of the ventricle during the ejection phase was slight due to a streamlined ejection pattern. The outflow through the bulbus cordis occurred in discrete streams which in part were structurally separated by well developed spiral folds. In the anterior bulbus segment the spiral folds are fused and make completely separate dorsal and ventral outflow tracts. The ventral bulbus channel provides blood to the three anterior branchial arteries. The second and third branchial arteries are large and represent direct shunts to the dorsal aorta. The fourth and fifth branchial arteries are gill bearing and receive blood form the dorsal bulbus channel. The most posterior epibranchial vessels give rise to the pulmonary arteries.     

Hypersensitivity of lung vessels to catecholamines in systemic hypertension.

Among patients with primary systemic hypertension pressure and arteriolar resistance in the pulmonary circulation exceed normal values and are hyper-reactive to sympathetic stimulation. A study was therefore carried out in 16 patients with uncomplicated essential hypertension and nine healthy subjects to compare the pulmonary vascular reactivity to exogenous catecholamines. In the normotensive group the dose response relation to adrenaline (microgram: dyn) was 1 = -4, 2 = -9, 3 = -9, and 4 = -10 and to noradrenaline 2 = +3, 4 = /8, 6 = +4, and 8 = +3. The relations in the hypertensive subjects were 1 = +18, 2 = +42, 3 = +59, and 4 = +77 and 2 = +39, 4 = +54, 6 = +76, and 8 = +100, respectively. Group differences were highly significant. Cardiac output (blood flow through the lungs) was raised by adrenaline and reduced by noradrenaline. In either case the driving pressure across the lungs was significantly augmented in the hypertensive patients but not in the normotensive group. Both catecholamines had a vasoconstrictor effect on the pulmonary circulation as a result of vascular over-reactivity. The opposite changes in resistance between normal and hypertensive subjects produced by adrenaline suggest that a constrictor vascular hypersensitivity occurs in the pulmonary circulation with the development of systemic high blood pressure.     

Regional neurovasomotor reactions of pulmonary circulation

In experiments on anaesthetized cats with intact chest regional blood volume and flow in the lungs at horizontal and vertical body positions and under vagus and sympathetic nerve stimulation were studied using regional lung electroplethysmography. The regions of the lungs bearing more significant hydrostatic and hemodynamic load turn more labile to neurogen stimuli. The parasympathetic vasomotor reaction of the basal lung regions increases while the apical region reaction decreases at a vertical body position. The results obtained suggest the occurrence of regionally differentiated mechanisms of vasomotor control in the pulmonary circulation, directed to compensation of postural changes in pulmonary hemodynamics.     

Cardiovascular effects of dietary copper deficiency

Dietary copper deficiency may impair cardiovascular health by contributing to high blood pressure, enhancement of inflammation, anemia, reduced blood clotting and arteriosclerosis. The purpose of this review is to compile information on the numerous changes of the heart, blood and blood vessels that may contribute to these cardiovascular defects. These alterations include weakened structural integrity of the heart and blood vessels, impairment of the use of energy by the heart, reduced ability of the heart to contract, altered ability of blood vessels to control their diameter and to grow, and altered structure and function of circulating blood cells. The fundamental causes of these changes rest largely on reduced effectiveness of enzymes that depend on copper for their activity.     

Causes of experimental pulmonary hypertension in rats.

Experimental pulmonary hypertension was induced in young male rats by means of tracheoconstriction and repeated injections of aqueous bean (Phaseolus vulg.) extract into the trachea. After 120 days, the blood pressure of the experimental and control animals was measured in the pulmonary artery with a shaped polyethylene catheter, without opening the chest. In all the experimental animals the blood pressure in the pulmonary artery was higher than in the controls. The mean pressure in the pulmonary artery of the experimental rats was 25 +/- 1 torr and in the controls 16 +/- 0.4 torr. The right ventricle of the experimental animals was larger than in the controls. No difference was found between the systemic blood pressure values, measured in the femoral artery, in the experimental animals and the controls. The experimental animals had a faster heart rate. Cardiac output, measured by the dye dilution method, was the same in the control and experimental animals and there was likewise no difference in the PO2 PCO2 and pH values in the arterial blood. The inhalation of oxygen instead of air did not affect the blood pressure in the pulmonary artery. The pulmonary blood vessels were evaluated quantitatively in histological sections of the experimental and control animal's lungs. There was no different between the thickness of the media of the distal pulmonary vessels, expressed as a percentage of the outer diameter of the vessel, in the experimental animals and the controls. A media thicker than 7% was found in 15% of the evaluated vessels from experimental animals and in 8% of those from the controls. No correlation between the mean thickness of the media and the mean blood pressure in the pulmonary artery was found in any of the animals.