Hemodynamics mechanisms of changes in the right atrial pressure following intravenous injection of the depressor drugs

Changes of the right atrial pressure, superior and inferior vena cava flows, right ventricular myocardial contractility (first derivate of right ventricular pressure, dP/dt max) following i.v. injection of acetylcholine, histamine and isoproterenol, were studied in acute experiments on anaesthetized mongrel cats with artificial lung ventilation and opened chest. The right atrial pressure in those cases could be increased (I group of animals) or decreased (II group). In maximal shifts of right atrial pressure following acetylcholine injection, the superior vena cava flow increased but the inferior vena cava flow decreased in equal proportion. When the right ventricular myocardial contractility decreased more than the right atrial pressure was augmented, and when the cardiac negative inotropic effect was weak, the right atrial pressure was reduced. After histamine injection in both groups of animals, right ventricular myocardial contractility was increased on the same level, and changes of the inferior vena cava flow were insignificant. The right atrial pressure was elevated following greater increase of superior vena cava flow. Isoproterenol caused the positive cardiac inotropic effect and augmenting of the superior vena cava flow in both groups of animals. The right atrial pressure was elevated if the inferior vena cava flow increased and, on the other hand, when the inferior vena cava flow decreased the right atrial pressure was reduced. Thus different maximal changes of the right atrial pressure following i.v. injection of acetylcholine, histamine and isoproterenol could be explained by different hemodynamic mechanisms of the interaction between superior and inferior vena cava flow shifts and changes of the right ventricular myocardial contractility.     

Correlations between changes of the right and left atrial pressures and systemic hemodynamics parameters following catecholamines intravenous injections in cats

In acute experiments on anesthetized cats, intravenous injection of epinephrine and norepinephrine caused different changes of right and left artrial pressures. These shifts mostly (82%) had similar directions: in these experiments, both right and left atrial pressures could be decreased (I group of animals) or increased (II group). The number of animals in these groups was equal. However, in 18% of the experiments, right atrial pressure was decreased, while left atrial pressure was increased. The changes of the left atrial pressure was, as a rule, more significant as compared with right atrial pressure shifts. In the I group of animals, systolic right atrial pressure was not changed, and systolic left atrial pressure was decreased. In the II group of animals, systolic pressure in both atria was augmented. Diastolic pressure was decreased in both atria in all the animals. When the atrial pressures were decreased, the increases of the superior and inferior vena cava flows, venous return and cardiac output were more significant as compared with animals in which the atrial pressures had been elevated. The changes of the superior and inferior vena cava flows were more obvious in animals following epinephrine injection as compared with animals in which norepinephrine was injected. The right atrial pressure returned to the initial level more rapidly than the left atrial pressure, and the time dynamics of the shifts of the right atrial pressure was similar to that of the superior vena cava flow. The temporal changes of the left atrial pressure were identical to the time changes of the cardiac output. We concluded that character of changes of the mean, systolic, and diastolic right and left atrial pressures following catecholamines injections was not correlated with the direction of venous return and cardiac output shifts, and was depending on intracardiac hemodynamics.     

Correlations between changes of the right and left atrial pressures following intravenous injections of pressor and depressor drugs in cats

In acute experiments on anesthetized cats, intravenous injection of the pressor drugs (epinephrine and norepinephrine) and depressor drugs (acetylcholine, histamine, isadrin) caused different changes of right and left atrial pressures. Following catecholamine injection, right atrial pressure decreased in most cases, whereas left atrial pressure increased. In case of injection of the depressor drugs, right atrial pressure increased in most cases, and left atrial pressure decreased. Thus, changes of atrial pressures following intravenous injections of pressor and depressor drugs were reciprocal. The percent changes of the right atrial pressure in case of intravenous injections of pressor drugs were lesser than in the left atrial pressure. In case of intravenous injection of depressor drugs, if both right and left atrial pressures were decreased, then the percent changes of the right atrial pressure were more significant than in the left atrial pressure. If both right and left atrial pressure were increased their percent changes were equal. The increasing of inferior vena cava flow following catecholamine injection was less significant if atrial pressures were increased, whereas in case of depressor drugs injection superior vena cava flow was less significant if atrial pressures were increased. The character of changes of the right and left atrial pressures had no linear correlation with the directions of the shifts of the venous return and cardiac output.     

RV filling modulates LV function by direct ventricular interaction during mechanical ventilation

During mechanical ventilation, phasic changes in systemic venous return modulate right ventricular output but may also affect left ventricular function by direct ventricular interaction. In 13 anesthetized, closed-chest, normal dogs, we measured inferior vena cava flow and left and right ventricular dimensions and output during mechanical ventilation, during an inspiratory hold, and (during apnea) vena caval constriction and abdominal compression. During a single ventilation cycle preceded by apnea, positive pressure inspiration decreased caval flow and right ventricular dimension; the transseptal pressure gradient increased, the septum shifted rightward, reflecting an increased left ventricular volume (the anteroposterior diameter did not change); and stroke volume increased. The opposite occurred during expiration. Similarly, the maneuvers that decreased venous return shifted the septum rightward, and left ventricular volume and stroke volume increased. Increased venous return had opposite effects. Changes in left ventricular function caused by changes in venous return alone were similar to those during mechanical ventilation except for minor quantitative differences. We conclude that phasic changes in systemic venous return during mechanical ventilation modulate left ventricular function by direct ventricular interaction.     

Haemodynamic mechanism of the variety of changes in the right atrial pressure following catecholamines administration

Changes of the right atrial pressure and systemic haemodynamics following action of catecholamines (epinephrine and norepinephrine) were studied in acute experiments on anaesthetised mongrel cats with artificial lung ventilation and opened chest. Maximal changes of the right atrial pressure took place on the 12th-16th second following catecholamine administration. In that case, the atrial pressure could be decreased or increased. At the moment of maximal changes of the right atrial pressure, the venous return and the right ventricular myocardial contractility (the first derivative of the right atrial pressure, dP/dt max) increased more if the right atrial pressure decreased, as compared with the animals whose right atrial pressure augmented. The findings suggest that at the time of the maximal changes of the right atrial pressure following action of catecholamines, there may be a direct connection of the right atrial pressure with interrelation of venous return and the right ventricular contractility. The right atrial pressure, however, is a dependent parameter but it does not determine the venous return.     

Relations between changes of the pulmonary and systemic hemodynamics following neurogenic stimuli

The character and values of changes of the pulmonary and systemic hemodynamics following neurogenic stimuli application on the cardiovascular system were studied in acute experiments on the anesthetized cats. Vagus nerve stimulation reduced the heart rate and decreased myocardial contractility in result, right and left atrial pressure increased, whereas pulmonary pressure and flow, venous return, cardiac output and venous return decreased. Pulmonary pressure reached maximal level and returned to the initial value earlier than the pulmonary flow. On the contrary, pulmonary pressure, following neurogenic pressor stimuli, reached maximal level and returned to the initial value later than the pulmonary flow; the sign of the changes of the pulmonary pressure could be positive or negative, whereas pulmonary flow were always increased. The venous return did not change, and for this reason it could not cause the increasing of pulmonary flow which was elevated following increasing of the heart rate and myocardial contractility. The shifts of the pulmonary pressure were correlated with the pulmonary resistance those, which were increased after the stellate ganglion stimulation and decreased following carotid reflex; they did not change in case of sciatic nerve stimulation. The shifts of the pulmonary pressure did not depended on the decreased right and left atrial pressures. When the pulmonary flow was always increased, the cardiac output following electrical stimulation of the stellate ganglion and sciatic nerve was elevated, and it was decreased following carotid reflex, i. e. linear correlation between these parameters were not found. Pulmonary and systemic arterial pressure changes were more obvious in case of direct neurogenic stimuli application comparing with reflectory ones; in both cases, the positive chrono- and inotropic cardiac effects were similar.     

The role of the cardiac-pulmonary blood volume in the changes in left ventricle output during stimulation of the afferent fibers of somatic nerves

Stimulation of tibial nerve afferent fibers has revealed heterogeneous shifts of left ventricular output, as well as pulmonary artery and posterior vena cava blood flow in anesthetized cats. Uniform changes in left ventricular output and pulmonary artery blood flow were noted in the majority of cases, with venous return most often exceeding pulmonary artery blood flow. beta-adrenoreceptor blockade failed to influence changes in pulmonary artery blood flow. It is concluded that the increase in pulmonary artery blood flow depends on the rise in venous return, but not on neurogenic influence upon the right ventricle. The reduction in left ventricular output is the result of decreased right ventricular outflow due to its overload caused by pulmonary vasoconstriction.     

Large venous compliance in carboxyhemoglobinemia and hemodilutional anemia

Anesthetized dogs were prepared for the measurement of compliance of the inferior vena cava by placement of a catheter for pressure measurement and a pair of ultrasonic dimension transducers for the measurement of transverse diameter. Measurements of compliance were made in a control state, after the induction of carboxyhemoglobinemia or hemodilutional anemia, by measuring pressure changes and diameter changes during brief occlusions of the inferior vena cava downstream from the transducers. Carboxyhemoglobinemia caused an upward shift of the averaged pressure-diameter curve while there was a negligible shift in the hemodiluted group. These results indicate that in carboxyhemoglobinemia a change in the compliance of the vena cava occurs, which favours augmented venous return by improved conductance rather than by a dislocation of blood by constriction of the large venous reservoir. In hemodilutional anemia the change in compliance is insignificant, but venous return is favoured by the reduced viscosity.     

Influence of positive airway pressure on the pressure gradient for venous return in humans.

To study the effect of positive airway pressure (Paw) on the pressure gradient for venous return [the difference between mean systemic filling pressure (Pms) and right atrial pressure (Pra)], we investigated 10 patients during general anesthesia for implantation of defibrillator devices. Paw was varied under apnea from 0 to 15 cmH(2)O, which increased Pra from 7.3 +/- 3.1 to 10.0 +/- 2.3 mmHg and decreased left ventricular stroke volume by 23 +/- 22%. Episodes of ventricular fibrillation, induced for defibrillator testing, were performed during 0- and 15-cmH(2)O Paw to measure Pms (value of Pra 7.5 s after onset of circulatory arrest). Positive Paw increased Pms from 10.2 +/- 3.5 to 12.7 +/- 3.2 mmHg, and thus the pressure gradient for venous return (Pms - Pra) remained unchanged. Echocardiography did not reveal signs of vascular collapse of the inferior and superior vena cava due to lung expansion. In conclusion, we demonstrated that positive Paw equally increases Pra and Pms in humans and alters venous return without changes in the pressure gradient (Pms - Pra).     

Experimental cardiac tamponade: correlation of pressure, flow velocity, and echocardiographic changes

Seven episodes of experimental cardiac tamponade were induced in five anesthetized closed-chest dogs. Simultaneous pericardial and intracavitary pressures were synchronized with superior vena caval and transvalvular pulsed-Doppler flow tracings. The earliest indication of tamponade was the development of a negative transmural right atrial pressure that occurred during early ventricular diastole and was associated with echocardiographic evidence of right atrial collapse. This was also associated with reversal of diastolic flow in the superior vena cava and with diminished early diastolic flow velocity across the tricuspid as well as the mitral valve. During more advanced cardiac tamponade, the transmural right atrial pressure became negative during both early and late ventricular diastole as well as during isovolumic ventricular systole. This was associated with a disappearance of early diastolic ventricular filling and right ventricular diastolic collapse as observed on two-dimensional echocardiography. In hypotensive cardiac tamponade (cardiac output diminished by 70%), the decreased transmural right atrial pressure that developed during ventricular systole was accompanied by diminished antegrade flow in the superior vena cava. In advanced and hypotensive tamponade, ventricular filling occurred mainly during atrial contraction.     

Effects of right atrial stretch on plasma renin activity.

In anaesthetized dog, right atrial stretch leads in the first five minutes to a decrease in plasma renin activity, when measured in inferior vena cava just above the renal veins. Bilateral cervical vagotomy increases plasma renin activity. After vagotomy, atrial stretch no longer has any effect on plasma renin activity. The results support the hypothesis of a control of renin secretion originating from atrial volume receptors.     

The pulmonary hemodynamics changes under experimental myocardial ischemia in rabbits following increased arterial pressure

In acute experiments in anesthetized rabbits, changes of the pulmonary hemodynamics following myocardial ischemia in the region of the descendent left coronary artery were studied in control animals and after the infusion of adrenaline and phenylephrine. The pulmonary artery pressure was increased following infusion of these drugs; however, it decreased to normal level in the condition of myocardial ischemia. Meanwhile the pulmonary vascular resistance was elevated to the same level in both cases. Following adrenaline infusion, the pulmonary artery blood flow and venous return increased and, in the condition of myocardial ischemia, they decreased to normal level, but the left atrial pressure was decreased. Following phenylephrine infusion, the pulmonary artery blood flow and venous return did not change and, in the condition of myocardial ischemia, these parameters decreased lower than normal level but the left atrial pressure was elevated. Thus we concluded that equal values of the pulmonary artery pressure in both cases were caused by changes of different character in the left atrial pressure. The differences of the changes character and values of the pulmonary artery flow under experimental myocardial ischemia following the infusion of adrenaline and phenylephrine were caused by different shifts of the venous return.     

Hemodynamic mechanisms of the pulmonary artery pressure and blood flow changes following vasoactive depressor drugs injection

The character and values of changes of the pulmonary hemodynamics and venous return following acetylcholine, histamine and isoproterenol intravenous injection were studied in acute experiments on the anesthetized cats. After depressor drugs injection the character and values of changes of pulmonary artery pressure and flow were different. In 67% cases the pulmonary artery pressure was decreased, and in 33%--it was elevated, meanwhile the pulmonary artery flow was decreased in 48% cases and it was increased in 52%, i.e., in the equal number of observations. Thus, following depressor drugs intravenous injection, hemodynamic mechanisms of the changes of pulmonary artery pressure and flow are different. The character and values of changes of the pulmonary artery pressure are correlated with the changes of pulmonary vascular resistance and are not dependent with the left atrial pressure shifts. The changes of the pulmonary artery blood flow are caused by the changes of the venous return and are not correlated with the changes of the right and left atrial pressure.     

Effects of water depth on abdominal [correction of abdominails] aorta and inferior vena cava during standing in water

During water immersion bradycardia and increase in stroke volume induce by changing in hydrostatic pressure. We hypothesised that the cardiac alterations with immersion are associates with an increase in venous return from lower body. Because the venous return reflects volume of capacitance vein e.g, inferior vena cava. Therefore, we clarified the effects of water immersion on the size in left ventricle, aorta, and vena cava.     

The pulmonary hemodynamic changes under experimental myocardial ischemia in rabbits following beta-adrenoreceptors blockade

In acute experiments in anesthetized rabbits, changes of the pulmonary hemodynamics following myocardial ischemia in the region of the descendent left coronary artery were studied as well as in control animals and after the blockade of beta-adrenoreceptors. The myocardial ischemia decreased the left ventricular myocardial contractility, cardiac output and arterial pressure, decreased the pulmonary artery pressure and flow. Following myocardial ischemia, the pulmonary artery pressure decreased less than pulmonary artery blood flow as the result of elevating of the left atrial pressure, meanwhile pulmonary vascular resistance was not changed. Following myocardial ischemia in animals after the blockade of the beta-adrenoreceptors, the pulmonary flow decreased the same as in control animals. However, the pulmonary artery pressure was decreased twofold more significantly than in control animals, and its diminishing was in the same degree as the pulmonary artery flow. Following myocardial ischemia after the blockade of the beta-adrenoreceptors, the pulmonary vascular resistance decreased whereas the left atrial pressure did not change significantly because the myocardial contractility decreased less than in control animals.     

Participation of the cava vein blood flow in forming the total venous return under influence of different modality stimuli on the circulation system

Participation of the anterior and posterior veins cava in forming the total venous return under pressor and depressor effects, stimulation of depressing foci of the medulla's ventral part, enhancement of pulmonary ventilation, hypoxia, hypothermia, administration of acetylcholine, histamine, corinfar, was shown to depend on the blood flow shift direction in each of the veins cava, dynamics of shifts' development in time, and intensity of the stimulus. In systemic responses, the blood flow shifts in the vena cava anterior much contribute to the total venous return at the maximum of the systemic arterial pressure rise (r = 0.87) whereas contribution of the vena cava posterior is the greatest during a later occurring increase in the venous return (r = 0.84). Along with increase in the stimulus intensity the vena cava anterior's part in forming the venous return becomes more limited whereas that of the vena cava posterior is enhanced.     

Vagal effects on sinoatrial and atrial conduction studied with epicardial mapping in dogs: the influence of pacemaker shifts on the measurement of sinoatrial conduction time

The influence of pacemaker shifts on sinoatrial conduction time (SACT) was studied by investigating the effects of vagal stimulation on SACT and atrial conduction in anesthetized open-chest dogs. Isochronal maps were drawn from unipolar electrograms simultaneously recorded at 60 epicardial sites on the right atrial free wall and the inferior and superior vena cava. Vagal stimulation caused atrial conduction velocity to increase from 0.99 +/- 0.10 m/s (mean +/- SD) to 1.23 +/- 0.23 m/s (p less than 0.01), and the pacemaker to shift to lower positions along the superior vena cava - right atrial junction. As a result of the changes, the distances and the atrial conduction times from the stimulating and recording electrodes to the pacemaker site varied, and hence, the SACT values obtained indirectly by premature atrial stimulation varied. The isochronal maps were used to measure the atrial conduction times from stimulating to recording electrodes (a), from stimulating electrode to pacemaker site (b), and from pacemaker site to recording electrode (c). Indirect SACT was lengthened by vagal stimulation from 43 +/- 16 to 64 +/- 22 ms (p less than 0.02). After correcting by subtracting the atrial conduction time (b + c - a), these values became 26 +/- 6 ms (control) and 40 +/- 11 ms (vagal stimulation) (p less than 0.01). SACT values measured directly from the electrograms were 27 +/- 7 ms (control) and 42 +/- 10 ms (vagal stimulation) (p less than 0.01). Corrected indirect SACTs were closer to direct SACTs than were the uncorrected indirect SACTs.(ABSTRACT TRUNCATED AT 250 WORDS)     

The constant level of the right atrial pressure and its role in the venous return characteristics]

Dynamics of the central venous pressure, superior and inferior v. cava flow and venous return following action of pressor stimuli were studied in acute experiments on anaesthetised mongrel cats with artificial lung ventilation and opened chest. The central venous pressure returned to the initial level faster as compared with the dynamics of superior and inferior v. cava flow and venous return. The superior v. cava blood flow increased more than that of inferior v. cava. The data suggest that the central venous pressure is controlled near the lower constant level.     

Anatomic Twist to a Straightforward Ablation

Atrioventricular (AV) junction ablation for treatment of refractory atrial fibrillation is a well defined, standardized procedure and the simplest of commonly performed radiofrequency ablations in the field of cardiac electrophysiology. We report successful AV junction ablation using an inferior approach in a case of inferior vena cava interruption. Inability during the procedure to initially pass the ablation catheter into the right ventricle, combined with low amplitude electrograms, led to suspicion of an anatomic abnormality. This was determined to be a heterotaxy syndrome with inferior vena cava interruption and azygos continuation, draining in turn into the superior vena cava. Advancing Schwartz right 0 (SRO) sheath through the venous abnormality into the right atrium allowed adequate catheter stability to successfully induce complete AV block with radiofrequency energy.     

Histamine and H1 -histamine receptors faster venous circulation

The study has analysed the action of histamine in the rabbit venous system and evaluated its potential role in contraction during increased venous pressure. We have found that a great variety exists in histamine sensitivity and H(1) -histamine receptor expression in various types of rabbit veins. Veins of the extremities (saphenous vein, femoral vein, axillary vein) and abdomen (common iliac vein, inferior vena cava) responded to histamine by a prominent, concentration-dependent force generation, whereas great thoracic veins (subclavian vein, superior vena cavas, intrathoracic part of inferior vena cava) and a pelvic vein (external iliac vein) exhibited slight sensitivity to exogenous histamine. The lack of reactivity to histamine was not due to increased activity of nitric oxide synthase (NOS) or heme oxygenase-1. H(1) -histamine receptor expression of veins correlated well with the histamine-induced contractions. Voltage-dependent calcium channels mediated mainly the histamine-induced force generation of saphenous vein, whereas it did not act in the inferior vena cava. In contrast, the receptor-operated channels were not involved in this response in either vein. Tyrosine phosphorylation occurred markedly in response to histamine in the saphenous vein, but not in the inferior vena cava. Histamine induced a prominent ρ kinase activation in both vessels. Protein kinase C and mitogen-activated protein kinase (MAPK) were not implicated in the histamine-induced intracellular calcium sensitization. Importantly, transient clamping of the femoral vein in animals caused a short-term constriction, which was inhibited by H(1) -histamine receptor antagonist in vivo. Furthermore, a significantly greater histamine immunopositivity was detected in veins after stretching compared to the resting state. We conclude that histamine receptor density adapts to the actual requirements of the circulation, and histamine liberated by the venous wall during increased venous pressure contributes to the contraction of vessels, providing a force for the venous return.