Pulmonary and systemic vascular responses to 6-keto-PGE1 in the conscious lamb

6-Keto-PGE₁ is a potent direct dilator of the pulmonary and systemic circulations of the newborn lamb under both normoxic and hypoxic conditions. Its threshold dose is similar to that of PGI₂ and PGE₁. Under hypoxia, 6-keto-PGE₁ appears equally effective on the pulmonary and systemic circulations, while under normoxia it predominantly affects the systemic circulation.     

Comparison of vascular and respiratory effects of endothelin-1 in the pig

The haemodynamic and respiratory responses caused by i.v. administration of endothelin-1 (ET-1) (20-100 pmol/kg) were studied in anaesthetized spontaneously breathing pigs. Intravenous bolus administration of synthetic ET-1 (40-100 pmol/kg) caused a transient decrease followed by a long-lasting increase in mean pulmonary arterial pressure and dose dependent vasoconstriction both in the systemic and pulmonary circulations. The effect on pulmonary arterial pressure was biphasic, with an initial transient fall followed by a long-lasting dose dependent increase. A biphasic response of the systemic mean arterial pressure was demonstrated only at a high dose of ET-1 (100 pmol/kg). ET-1 administration did not significantly change breathing pattern or phasic vagal input, but caused a significant decrease in passive compliance. Passive resistances or active compliance and resistances of the respiratory system were not modified. These results suggest that in the pig ET-1 is a more potent constrictor of vascular than of bronchial smooth muscle. The vasoconstrictor activity was greater in the pulmonary than the systemic circulations.     

Vascular remodeling in the circulations of the lung.

The lung is unique in its double sources of perfusion from the pulmonary and systemic circulations. One striking difference between the two circulations is the capacity for angiogenesis. The bronchial circulation has a capacity that seems quite similar to all systemic arteries, whereas the pulmonary circulation seems relatively inert in this regard. Extra-alveolar pulmonary arteries can grow somewhat in length, and septal capillaries seem to have the capability of reforming, but these processes do not seem to occur with nearly the same intensity associated with the bronchial arteries. In this review, we emphasize these differences between the two circulations of the lung, anticipating that future research will allow more focused probing into the molecular signaling that regulates the novel mechanistic and pathological pathways of each.     

Acute and chronic cardiovascular effects of intermittent hypoxia in C57BL/6J mice.

We investigated the effects of 1) acute hypoxia and 2) 5 wk of chronic intermittent hypoxia (IH) on the systemic and pulmonary circulations of C57BL/6J mice. Mice were chronically instrumented with either femoral artery or right ventricular catheters. In response to acute hypoxia (4 min of 10% O2; n = 6), systemic arterial blood pressure fell (P < 0.005) from 107.7 +/- 2.5 to 84.7 +/- 6.5 mmHg, whereas right ventricular pressure increased (P < 0.005) from 11.7 +/- 0.8 to 14.9 +/- 1.3 mmHg. Another cohort of mice was then exposed to IH for 5 wk (O2 nadir = 5%, 60-s cycles, 12 h/day) and then implanted with catheters. In response to 5 wk of chronic IH, mice (n = 8) increased systemic blood pressure by 7.5 mmHg, left ventricle + septum weight by 32.2 +/- 7.5 x 10(-2) g/100 g body wt (P < 0.015), and right ventricle weight by 19.3 +/- 3.2 x 10(-2) g/100 g body wt (P < 0.001), resulting in a 14% increase in the right ventricle/left ventricle + septum weight (P < 0.005). We conclude that in C57BL/6J mice 1) acute hypoxia causes opposite effects on the pulmonary and systemic circulations, leading to preferential loading of the right heart; and 2) chronic IH in mice results in mild to moderate systemic and pulmonary hypertension, with resultant left- and right-sided ventricular hypertrophy.     

Form and Function in Reptilian Circulations

Consistent with the great variation in their circulatory morphology,there are distinct variations in the cardiovascular physiologyof extant reptiles. The chelonian and squamate reptiles havea complexly structured heart that includes three partially separatedventricular cava. In most species (under most conditions), theventricle acts as a single pressure pump perfusing both thepulmonary and systemic circuits. However, the varanid lizardsprovide a striking exception. Subtle evolutionary changes incardiac morphology allow the ventricle of the varanid lizardto divide functionally during systole into a low pressure, pulmonarypump and a high pressure, systemic pump. The crocodilians representyet another anatomical and physiological pattern. The ventricleis completely divided into left and right chambers as in homeotherms,but the systemic and pulmonary circuits may still communicatethrough the left aorta that arises from the right ventricle. A fundamental feature of all reptilian circulations is the abilityto regulate the distribution of cardiac output between systemicand pulmonary circuits via central vascular blood shunts.Regardlessof species, mechanisms for regulating intracardiac shuntinginvolve changes in the balance between peripheral resistanceof the pulmonary and systemic circulations, and adjustmentsin cardiac performance per se. Several hypotheses are presentedthat suggest selective advantages for central vascular shuntingin intermittent breathing reptiles with variable body temperatureand metabolic rate.     

Effects of prostaglandins of the E-series on pulmonary and systemic circulations of newborn goats during normoxia and hypoxia.

Effects of exogenous prostaglandins of the E-series on pulmonary and systemic circulations of newborn goats were investigated during normoxia and hypoxia. Pulmonary arterial infusion of prostaglandins E1 and E2 decreased pulmonary vascular resistance 20% and 14%, respectively, without systemic effects. Prostaglandin E1 abolished the pulmonary pressor response to hypoxia. Prostaglandin E2 was less effective in counteracting this hypoxic response. The increased pulmonary vascular resistance and augmented response to hypoxia following indomethacin administration was reversed by prostaglandin E1. Infusion of prostaglandin E1 directly into the pulmonary circulation may be of benefit to the distressed newborn with elevated pulmonary vascular resistance.     

Changes in venous return parameters associated with univentricular Fontan circulations

To clarify the physiology of venous return (Q(vr)) in Fontan circulations, venous return conductance (G(vr)) and mean circulatory filling pressure (P(mcf)) were determined in pentobarbital sodium-anesthetized pigs. Relationships between Q(vr) and right (biventricular, n = 8) or left (Fontan, n = 8) filling pressures are described by straight lines with significant correlation coefficients. Estimated P(mcf) values were correlated with observed P(mcf) values in either circulations (P 相似文献   

Effects of prostaglandins of the E-series on pulmonary and systemic circulations of newborn goats during normoxia and hypoxia

Effects of exogenous prostaglandins of the E-series on pulmonary and systemic circulations of newborn goats were investigated during normoxia and hypoxia. Pulmonary arterial infusion of prostaglandins E₁ and E₂ decreased pulmonary vascular resistance 20% and 14%, respectively, without systemic effects. Prostaglandin E₁ abolished the pulmonary pressor response to hypoxia. Prostaglandin E₂ was less effective in counteracting this hypoxic response. The increased pulmonary vascular resistance and augmented response to hypoxia following indomethacin administration was reversed by prostaglandin E₁. Infusion of prostaglandin E₁ directly into the pulmonary circulation may be of benefit to the distressed newborn with elevated pulmonary vascular resistance.     

Computational model of the fluid dynamics in systemic-to-pulmonary shunts

A systemic-to-pulmonary shunt is a connection created between the systemic and pulmonary arterial circulations in order to improve pulmonary perfusion in children with congenital heart diseases. Knowledge of the relationship between pressure and flow in this new, surgically created, cardiovascular district may be helpful in the clinical management of these patients, whose survival is critically dependent on the blood flow distribution between the pulmonary and systemic circulations. In this study a group of three-dimensional computational models of the shunt have been investigated under steady-state and pulsatile conditions by means of a finite element analysis. The model is used to quantify the effects of shunt diameter (D), curvature, angle, and pulsatility on the pressure-flow (DeltaP-Q) relationship of the shunt. Size of the shunt is the main regulator of pressure-flow relationship. Innominate arterial diameter and angles of insertion have less influence. Curvature of the shunt results in lower pressure drops. Inertial effects can be neglected. The following simplified formulae are derived: DeltaP=(0. 097Q+0.521Q(2))/D(4) and DeltaP=(0.096Q+0.393Q(2))/D(4) for the different shunt geometries investigated (straight and curved shunts, respectively).     

The Role of Cardiac Shunts in the Regulation of Arterial Blood Gases

SYNOPSIS. The pulmonary and systemic circulations are not completelyseparated in reptiles and amphibians, so oxygen-rich blood returningfrom the lungs can mix with oxygen-poor blood returning fromthe systemic circuit (cardiac shunts). In these animals, thearterial blood gas composition is determined by both lung ventilationand the cardiac shunt. Therefore, changes in cardiac shuntingpatterns may participate actively in the regulation of arterialblood gases. In turtles the cardiac shunt pattern changes independentlyof ventilation and the cardiac R-L shunt (pulmonary bypass ofsystemic venous blood) is reduced under circumstances wherethe demands on efficient gas exchange are high (hypoxia, hypoxemiaor exercise). We propose, therefore, that the size of cardiacshunts is regulated independently of ventilation and hypothesizethat there exist at least two groups of peripheral chemoreceptorswith different reflex roles.     

In vitro steady-flow analysis of systemic-to-pulmonary shunt haemodynamics.

A modified Blalock-Taussig shunt is a connection created between the systemic and pulmonary arterial circulations to improve pulmonary perfusion in children with congenital heart diseases. Survival of these patients is critically dependent on blood flow distribution between the pulmonary and systemic circulations which in turn depends upon the flow resistance of the shunt. Previously, we investigated the pressure-flow relationship in rigid shunts with a computational approach. to estimate the pulmonary blood flow rate on the basis of the in vivo measured pressure drop. The present study aims at evaluating, in vitro how the anastomotic distensibility and restrictions due to suture presence affect the shunt pressure-flow relationship. Two actual Gore-Tex shunts (3 and 4 mm diameters) were sutured to compliant conduits by a surgeon and tested at different steady flow rates (0.25-11 min(-1)) and pulmonary pressures (3-34 mmHg). Corresponding computational models were also created to investigate the role of the anastomotic restrictions due to sutures. In vitro experiments showed that pulmonary artery pressure affects the pressure-flow relationship of the anastomoses. particularly at the distal site. However, this occurrence scarcely influences the total shunt pressure drop. Comparisons between in vitro and computational models without anastomotic restrictions show that the latter underestimates the in vitro pressure drops at any flow rate. The addition of the anastomotic restrictions (31 and 47% of the original area of 3 and 4 mm shunts, respectively) to the computational models reduces the gap, especially at high shunt flow rate and high pulmonary pressure.     

The adrenergic regulation of the cardiovascular system in the South American rattlesnake, Crotalus durissus

The present study investigates adrenergic regulation of the systemic and pulmonary circulations of the anaesthetised South American rattlesnake, Crotalus durissus. Haemodynamic measurements were made following bolus injections of adrenaline and adrenergic antagonists administered through a systemic arterial catheter. Adrenaline caused a marked systemic vasoconstriction that was abolished by phentolamine, indicating this response was mediated through alpha-adrenergic receptors. Injection of phentolamine gave rise to a pronounced vasodilatation (systemic conductance (G(sys)) more than doubled), while injection of propranolol caused a systemic vasoconstriction, pointing to a potent alpha-adrenergic, and a weaker beta-adrenergic tone in the systemic vasculature of Crotalus. Overall, the pulmonary vasculature was far less responsive to adrenergic stimulation than the systemic circulation. Adrenaline caused a small but non-significant pulmonary vasodilatation and there was tendency of reducing this dilatation after either phentolamine or propranolol. Injection of phentolamine increased pulmonary conductance (G(pul)), while injection of propranolol produced a small pulmonary constriction, indicating that alpha-adrenergic and beta-adrenergic receptors contribute to a basal regulation of the pulmonary vasculature. Our results suggest adrenergic regulation of the systemic vasculature, rather than the pulmonary, may be an important factor in the development of intracardiac shunts.     

Two alternative models concerning the perialveolar microcirculation in mammalian lungs

Despite the fact that the concept of sheet-flow in the pulmonary microcirculation of mammals was introduced more than three decades ago, the capillary circulatory model still prevails in the physiological literature. Since cardiac output is identical in the systemic and in pulmonary circulations, it is noteworthy that in the former, the resulting arterial pressure is five times higher than that of the latter, which means that the corresponding microcirculations must be radically different. The present study addresses this problem from both morphological and physiological perspectives.     

Multiscale modelling in biofluidynamics: application to reconstructive paediatric cardiac surgery

Multiscale computing is a challenging area even in biomechanics. Application of such a methodology to quantitatively compare postoperative hemodynamics in congenital heart diseases is very promising. In the treatment of hypoplastic left heart syndrome, which is a congenital heart disease where the left ventricle is missing or very small, the necessity to feed the pulmonary and systemic circulations is obtained with an interposition shunt. Two main options are available and differ from the sites of anastomoses: (i) the systemic-to-pulmonary conduit (Blalock-Taussig shunt known as the Norwood Operation (NO)) connecting the innominate artery (NO-BT) or the aorta (NO-CS) to the right pulmonary artery and (ii) the right ventricle to pulmonary artery shunt (known as Sano operation (SO)). The proposition that the SO is superior to the NO remains controversial. 3-D computer models of the NO (NO-BT and NO-CS) and SO were developed and investigated using the finite volume method. Conduits of 3, 3.5 and 4 mm were used in the NO models, whereas conduits of 4, 5 and 6 mm were used in the SO model. The hydraulic nets (lumped resistances, compliances, inertances and elastances) which represent the systemic, coronary and pulmonary circulations and the heart were identical in the two models. A multiscale approach was adopted to couple the 3-D models with the circulation net. Computer simulation results were compared with post-operative catheterization data. Results showed that (i) there is a good correlation between predicted and observed data: higher aortic diastolic pressure, decreased pulmonary arterial pressure, lower pulmonary-to-systemic flow ratio and higher coronary perfusion pressure in SO; (ii) there is a minimal regurgitant flow in the SO conduit. The close correlation between predicted and observed clinical data supports the use of mathematical modelling, with a mandatory multiscale approach, in the design and assessment of surgical procedures.     

Rapid shallow breathing evoked by capsaicin from isolated pulmonary circulation

Recently Green et al. (J. Appl. Physiol. 57:562-567, 1984) reported that pulmonary C-fibers initiate the prompt apnea evoked by pulmonary arterial injections of capsaicin; however, their role in the subsequent rapid shallow breathing of the pulmonary chemoreflex is still in dispute. To determine whether this reflex tachypnea is triggered by pulmonary C-fibers rather than by afferents further downstream, we separately perfused the pulmonary and systemic circulations in dogs anesthetized with either halothane or alpha-chloralose as the lungs were ventilated with a servo-controlled ventilator driven by phrenic nerve activity. Injection of capsaicin (10 micrograms/kg) into the pulmonary artery of the isolated pulmonary circulation evoked an immediate apnea followed by rapid shallow breathing. Injection of the same dose of capsaicin into the left atrium of the isolated pulmonary circulation had no effect. By contrast, when capsaicin was administered at a slower rate into the pulmonary artery (10-20 micrograms X kg-1 X min-1) rapid shallow breathing occurred but without apnea. Our results are consistent with the hypothesis that in spontaneously breathing animals, stimulation of pulmonary C-fibers can evoke rapid shallow breathing.     

The role of nitric oxide in the regulation of the systemic and pulmonary vasculature of the rattlesnake, <Emphasis Type="Italic">Crotalus durissus terrificus</Emphasis>

The functional role of nitric oxide (NO) was investigated in the systemic and pulmonary circulations of the South American rattlesnake, Crotalus durissus terrificus. Bolus, intra-arterial injections of the NO donor, sodium nitroprusside (SNP) caused a significant systemic vasodilatation resulting in a reduction in systemic resistance (Rsys). This response was accompanied by a significant decrease in systemic pressure and a rise in systemic blood flow. Pulmonary resistance (Rpul) remained constant while pulmonary pressure (Ppul) and pulmonary blood flow (Qpul) decreased. Injection of L-Arginine (L-Arg) produced a similar response to SNP in the systemic circulation, inducing an immediate systemic vasodilatation, while Rpul was unaffected. Blockade of NO synthesis via the nitric oxide synthase inhibitor, L-NAME, did not affect haemodynamic variables in the systemic circulation, indicating a small contribution of NO to the basal regulation of systemic vascular resistance. Similarly, Rpul and Qpul remained unchanged, although there was a significant rise in Ppul. Via injection of SNP, this study clearly demonstrates that NO causes a systemic vasodilatation in the rattlesnake, indicating that NO may contribute in the regulation of systemic vascular resistance. In contrast, the pulmonary vasculature seems far less responsive to NO.     

Evidence for pulmonary CO2 chemosensitivity: effects on ventilation

To determine whether there is a pulmonary chemoreceptor for CO2 that influences spontaneous ventilation (VE), we separated the systemic and pulmonary circulations and controlled partial pressure of CO2 (PCO2) independently in each circuit under hyperoxic conditions and measured VE. Dogs were anesthetized with ketamine and maintained with 1% halothane. Systemic venous return was drained from the right atrium and passed through an oxygenator and heat exchanger; blood was returned to the ascending aorta. An identical bypass was established for the pulmonary circulation, draining blood from the left atrium and returning it to the pulmonary artery. The heart was fibrillated; all cannulas were brought through the chest wall; and the median sternotomy was closed. Blood flow through both circuits was maintained at 0.080 l . kg-1 . min-1. Systemic PCO2 (PSCO2) was held constant at three different nonoscillatory levels. At each level, pulmonary PCO2 (PpCO2) was randomly varied between approximately 7 and 85 Torr. With PSCO2 at 43.5 +/- 0.4 Torr, VE increased 2.67 +/- 0.61 l . min-1 as PpCO2 was varied between these limits. With PSCO2 at 63.8 +/- 2.5 Torr, VE increased 3.95 +/- 0.73 l . min-1 over these same limits of PpCO2. With PSCO2 below 25--30 Torr, the dogs were apneic and no longer responded to changes in PpCO2. The effect of PpCO2 on VE was abolished by vagotomy. These results suggest the presence of a CO2 chemoreceptor in the lung that interacts with the nonpulmonary chemoreceptors in the control of VE.     

Analysis of responses to endothelins in the rabbit pulmonary and systemic vascular beds

The effects of two isoforms of human endothelin (ET) on the pulmonary and systemic vascular beds were compared in the anesthetized intact-chest rabbit under conditions of constant pulmonary blood flow and left atrial pressure. Intralobar bolus injections of ET-1 (0.1-1 micrograms) and ET-3 (1-3 micrograms) produced modest vasoconstriction in the pulmonary vascular bed, whereas both peptides decreased systemic arterial pressure. The pulmonary vasoconstrictor response to ET-1 and ET-3 was inhibited by intralobar infusion of nitrendipine but was not altered by indomethacin. In contrast to the small effects of ET-1 and ET-3 on intact pulmonary resistance vessels, both peptides markedly contracted isolated pulmonary conductance vessels, with greater activity on venous than on arterial segments. Intravenous bolus injection of ET-1 (0.1-0.3 micrograms) or ET-3 (0.3-1 microgram) decreased systemic arterial pressure, increased cardiac output, and markedly decreased systemic vascular resistance. Higher doses of ET-1 produce a biphasic systemic vascular response with a prominent secondary pressor component. The present data suggest that the pulmonary vasoconstrictor activity of ET-1 is greater than that of ET-3 and their pressor activity depends on an extracellular source of calcium. The pulmonary and systemic hemodynamic effects of ET-1 and ET-3 in the rabbit do not depend on cyclooxygenase products. The systemic vasodilator response to ET-1 is not altered by first-pass lung transit. Furthermore the systemic vasodilator response to both peptides occurs independent of activation of muscarinic, beta 2-adrenergic, and platelet-activating factor receptors. Although ET-1 and ET-3 were initially reported as vasoconstrictor peptides, the present data suggest that, by having unique and potent systemic vasodilator activity, ET-1 and ET-3 act differently in the systemic and pulmonary vascular beds under resting conditions in the rabbit.     

Ventilatory changes associated with changes in pulmonary blood flow in dogs

To examine the influence of pulmonary blood flow (Qp) on spontaneous ventilation (VE), we isolated the systemic and pulmonary circulations and controlled the arterial blood gases and blood flow (Q) in each circuit as we measured VE. Each dog was anesthetized with ketamine and maintained with halothane. Systemic Q was drained from the right atrium and pumped through an oxygenator and heat exchanger and returned to the aorta. An identical bypass was established for the pulmonary circulation, draining blood from the left atrium and pumping it to the pulmonary artery. The heart was fibrillated, all cannulas were brought through the chest wall, and the median sternotomy was closed. The dog was then allowed to breathe spontaneously. The arterial O2 partial pressure (PO2) of both circuits was maintained greater than 300 Torr. Systemic Q was maintained at 0.080 l X min-1 X kg-1. Initially the arterial CO2 partial pressure (PCO2) of both circuits was set at 40 Torr as Qp was varied randomly between approximately 0.025 and 0.175 l X min-1 X kg-1. The average VE-Qp relationship was linear with a slope of 1.45 (P less than 0.0005). Increasing the arterial PCO2 of both circuits to 60 Torr elevated VE an average of 0.37 l X min-1 X kg-1 at each level of Qp (P less than 0.0005). Vagotomy abolished the effect of Qp on VE. Increasing Qp affected the systemic arterial PCO2-VE response curve by shifting it upward without altering its slope. These results demonstrate that increases in Qp are associated with increases in VE. This phenomenon may contribute to exercise hyperpnea.