Absence of reflex vascular responses from the intrapulmonary circulation in anaesthetised dogs

The aim of this investigation was to determine whether reflex cardiovascular responses were obtained to localised distension of the intrapulmonary arterial and venous circulations in a preparation in which the stimuli to other major reflexogenic areas were controlled and the lung was shown to possess reflex activity. Dogs were anaesthetised with -chloralose, artificially ventilated, the chests widely opened and a cardiopulmonary bypass established. The intrapulmonary region of the left lung was isolated and perfused through the left pulmonary artery and drained through cannulae in the left pulmonary veins via a Starling resistance. Intrapulmonary arterial and venous pressures were controlled by the rate of inflow of blood and the pressure applied to the Starling resistance. Pressures to the carotid, aortic and coronary baroreceptors and heart chambers were controlled. Responses of vascular resistance were assessed from changes in perfusion pressures to a vascularly isolated hind limb and to the remainder of the subdiaphragmatic circulation (flows constant). The reactivity of the preparation was demonstrated by observing decreases in vascular resistance to large step changes in carotid sinus pressure (systemic vascular resistance decreased by -40 +/- 5%), chemical stimulation of lung receptors by injection into the pulmonary circulation of veratridine or capsaicin (resistance decreased by -32 +/- 4%) and, in the four dogs tested, increasing pulmonary stroke volume to 450 ml (resistance decreased by -24 +/- 6%). However, despite this evidence that the lung was innervated, increases in intrapulmonary arterial pressure from 14 +/- 1 to 43 +/- 3 mmHg or in intrapulmonary venous pressure from 5 +/- 2 to 34 +/- 2 mmHg or both did not result in any consistent changes in systemic or limb vascular resistances. In two animals tested, however, there were marked decreases in efferent phrenic nerve activity. These results indicate that increases in pressure confined to the intrapulmonary arterial and venous circulations do not cause consistent reflex vascular responses, even though the preparation was shown to be reflexly active and the lung was shown to be innervated.     

Comparison of the reflex vasomotor responses to separate and combined stimulation of the carotid sinus and aortic arch baroreceptors by pulsatile and non-pulsatile pressures in the dog

1. In the anaesthetized dog the carotid sinuses and aortic arch were isolated from the circulation and separately perfused with blood by a method which enabled the mean pressure, pulse pressure and pulse frequency to be varied independently in each vasosensory area. The systemic circulation was perfused at constant blood flow by means of a pump and the systemic venous blood was oxygenated by an extracorporeal isolated pump-perfused donor lung preparation.2. When the vasosensory areas were perfused at non-pulsatile pressures within the normal physiological range of mean pressures, the reflex reduction in systemic vascular resistance produced by a given rise in mean carotid sinus pressure was significantly greater than that resulting from the same rise of aortic arch pressure.3. On the other hand, when the vasosensory areas were perfused at normal pulsatile pressures and within the normal physiological range of mean pressures, there was no difference in the size of the reflex vascular responses elicited by the same rise in mean pressure in the carotid sinuses and in the aortic arch.4. Whereas the vasomotor responses elicited reflexly by changes in mean carotid sinus pressure are modified by alterations in pulse pressure, those evoked by the aortic arch baroreceptors through changes of mean pressure are only weakly affected by modifications in pulse pressure. Evidence for this was obtained from single stepwise changes of mean pressure in each vasosensory area during pulsatile and non-pulsatile perfusion, and from curves relating the mean pressure in the carotid sinuses or aortic arch and systemic arterial perfusion pressure.5. The vasomotor response elicited by combined stimulation of the carotid sinus and aortic arch baroreceptors was greater than either response resulting from their separate stimulation.6. When the mean perfusion pressures in the two vasosensory areas are changed together, the curve relating mean pressure to systemic arterial pressure during pulsatile perfusion of the areas is considerably flatter than that for non-pulsatile perfusion.7. Increasing the pulse pressure in the carotid sinuses or aortic arch caused a decrease in systemic vascular resistance, the response elicited from the carotid sinuses being the larger.8. Altering the phase angle between the pulse pressure waves in the carotid sinuses and aortic arch had no effect on systemic vascular resistance.9. In both vasosensory areas, increasing the pulse frequency caused a reduction in systemic vascular resistance.     

The role of cardiac sympathetic discharges during the pulmonary depressor reflex.

The role played by the cardiac sympathetic fibers in the pulmonary depressor reflex was analyzed in twenty dogs. The selective perfusion with homologous blood of the inferior lobar vessels of the left lung with pressures of 40 to 60 mmHg decreased the spontaneous background discharges recorded from the left superior or inferior cardiac sympathetic nerves. This decrease was maximal at perfusion pressure of 80-100 mmHg. Following the decrease in the sympathetic discharges, the systolic and diastolic systemic arterial blood pressure decrease about 10 per cent. The changes were reversible when the perfusion pressure was returned to the control. The intravenous injection of atropine sulphate did not change either the systemic hypotension or the responses of the sympathetic efferent discharges induced by elevation of the pressure in the vascular bed of the lung lobe. Thus, it is believed that the systemic arterial blood pressure during this reflex may have fallen due to a diminution of the vascular tone caused by a decrease in the sympathetic efferent discharges. After transection of the vagus nerve ipsilateral to the tested lobe, the reduction of the sympathetic discharges as well as the decrease of the systemic arterial blood pressure were no longer observed. Our results further substantiate the concept that the vagus nerve is the afferent pathway for the pulmonary depressor reflex, and it may be concluded that during this reflex the sympathetic efferent activities are inhibited.     

Neural control of sympathetic nerve response to cardiogenic hypotension in anesthetized cat

The present study was designed to determine effect of the preganglionic splanchnic nerve activity (SNA) on the brief hypotension accompanied with the occlusion of left circumflex coronary artery (CxCAO) in chloralose anesthetized cats. Following CxCAO in animals with neuraxis intact, no significant alterations of SNA occurred despite the significant fall in mean blood pressure (MBP). A significant fall in MBP also occurred in vagotomized animals with arterial baroreceptors intact, but SNA was significantly augmented from 12.9 +/- 2.7 impulses/sec before CxCAO to 24.4 +/- 4.3 impulses/sec 60 sec after the occlusion. In vagotomized animals, in which their carotid sinuses were isolated and perfused with the constant pressure at a level equal to systemic blood pressure (112 +/- 6 mmHg) and with higher pressure (167 +/- 7 mmHg), SNA was not altered significantly during the hypotension due to CxCAO. When the carotid sinuses were perfused with lower pressure (53 +/- 8 mmHg), a significant increase in SNA occurred simultaneously with the decrease in MBP after CxCAO. The peak decreases in blood pressure during the coronary occlusion were significantly greater in the vagotomized group (-46 +/- 5 mmHg) and in the Low-CSP group (-50 +/- 5 mmHg) than in other groups. Onset of this excitatory efferent sympathetic response to the hypotension due to the coronary occlusion in the vagotomized and Low-CSP groups was delayed significantly despite a significant fall in arterial blood pressure. These results show that vagal afferents from the heart may play a role of inhibiting the sympathetic augmentation mediated by arterial baroreceptors during cardiogenic hypotension. An excessive activation of cardiac receptors with sympathetic afferents may be induced by the profound fall in blood pressure, resulting in further impairment of cardiac function due to progressive myocardial ischemia under the condition of high sympathetic tone activated by baroreceptor reflex.     

Reflex vascular responses to changes in left ventricular pressures, heart rate and inotropic state in dogs.

Dogs were anaesthetized with chloralose, artificially ventilated and the chests widely opened. Left ventricular mechanoreceptors, including those in or near the coronary arteries, were stimulated by changing the pressure in the aortic root. The pressures distending the left atrium and the aortic and carotid baroreceptors were controlled. Reflex vascular responses were assessed from changes in perfusion pressures to a hind limb and to the rest of the systemic circulation, which were perfused independently at constant flows. Physiological increases in peak left ventricular and coronary arterial pressures resulted in vasodilatation in both regions. These responses were not influenced by changes in the heart rate. Stimulation of the left cardiac sympathetic nerves resulted in increases in peak ventricular pressure and in the maximal rate of change of pressure (dP/dtmax). This also resulted in increases in perfusion pressures (vasoconstriction) at all levels of peak ventricular pressure although there was little effect on the responses to changes in ventricular pressure. Sympathetic stimulation had little effect on the relationship between perfusion pressures and aortic root pressure. Increases in ventricular filling also resulted in vasoconstriction at all levels of peak ventricular pressure. Increases in filling, however, did not affect the relationship between either perfusion pressure and aortic root pressure. Conversely, decreases in left ventricular filling, by bypassing some of the left atrial blood, resulted in vasodilatation at all levels of peak ventricular pressures but had no effect on the perfusion pressures at any aortic root pressure. The combination of sympathetic stimulation with decreased ventricular filling resulted in little effect on perfusion pressures or on their responses to changes in either aortic root or ventricular systolic pressures. We conclude that the vascular responses to stimulation of left ventricular mechanoreceptors are not enhanced by sympathetic stimulation, decreases in ventricular filling or the combination of the two. The apparent effects of each of these interventions alone on the relationships between perfusion pressures and ventricular, but not aortic root, pressure, could be explained if the receptors responsible were sensitive more to changes in aortic root and coronary arterial pressures than to pressure changes in the ventricle itself.     

Determinants of systemic zero-flow arterial pressure

Thirteen pentobarbital-anesthetized dogs whose carotid sinuses were isolated and perfused at a constant pressure were placed on total cardiac bypass. With systemic venous pressure held at 0 mmHg (condition 1), arterial inflow was stopped for 20 s at intrasinus pressures of 50, 125, and 200 mmHg. Zero-flow arterial pressures under condition 1 were 16.2 +/- 1.3 (SE), 13.8 +/- 1.1, and 12.5 +/- 0.8 mmHg, respectively. In condition 2, the venous outflow tube was clamped at the instant of stopping the inflow, causing venous pressure to rise. The zero-flow arterial pressures were 19.7 +/- 1.3, 18.5 +/- 1.4, and 16.4 +/- 1.2 mmHg for intrasinus pressures of 50, 125, and 200 mmHg, respectively. At all levels of intrasinus pressure, the zero-flow arterial pressure in condition 2 was higher (P less than 0.005) than in condition 1. In seven dogs, at an intrasinus pressure of 125 mmHg, epinephrine increased the zero-flow arterial pressure by 3.0 mmHg, whereas hexamethonium and papaverine decreased the zero-flow arterial pressure by 2 mmHg. Reductions in the hematocrit from 52 to 11% resulted in statistically significant changes (P less than 0.01) in zero-flow arterial pressures. Thus zero-flow arterial pressure was found to be affected by changes in venous pressure, hematocrit, and vasomotor tone. The evidence does not support the literally interpreted concept of the vascular waterfall as the model for the finite arteriovenous pressure difference at zero flow.     

Lack of interaction between adenosine-induced vasodilatation and carotid baroreflex-induced changes in sympathetic activity in dog hindlimb artery

In anaesthetized dogs, a hindlimb was vascularly isolated and perfused at a constant flow rate of 7.7 +/- 1.9 ml min-1 100 g-1 (mean +/- S.E.M.; n = 5) through the femoral artery. The carotid sinuses were isolated and perfused at high (greater than 145 mmHg) or low (less than 75 mmHg) pressure to enable reflex sympathetic tone on the hindlimb vessels to be controlled. Both vagi were sectioned in the neck and mean aortic blood pressure was held constant by connection of the aorta to a reservoir. The responses to infusion of three doses of adenosine at high and low carotid sinus pressures were not significantly different: infusion of 0.60 +/- 0.16 microM-adenosine reduced femoral arterial perfusion pressure (FAPP) by 11.6 +/- 3.2% (n = 6) at high carotid sinus pressure and by 12.6 +/- 5.1% (n = 4) at low carotid sinus pressure, while 4.71 +/- 0.49 microM-adenosine reduced FAPP by 20.8 +/- 4.8% (n = 6) at high carotid sinus pressure and by 20.7 +/- 4.8% (n = 6) at low carotid sinus pressure; 50.1 +/- 7.3 microM-adenosine reduced FAPP by 36.7 +/- 5.5% (n = 6) at high carotid sinus pressure and by 27.7 +/- 7.8% (n = 5) at low carotid sinus pressure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endogenous NO does not regulate baseline pulmonary pressure,but reduces acute pulmonary hypertension in dogs

It has remained unclear whether endogenous production of nitric oxide (NO) plays an important role in the regulation of physiologically normal pulmonary pressures. Severe alveolar hypoxia is accompanied by decreased pulmonary NO production, which could contribute to the development of hypoxic pulmonary hypertension. On the other hand, pharmacological NO inhibition further augments this hypertensive response. AIMS: The aims of the present study were to test: (a) whether NO contributes importantly in the maintenance of baseline pulmonary pressure; and (b) to which degree NO is involved in the pulmonary haemodynamic adjustments to alveolar hypoxia. METHODS: In anaesthetized dogs (n=37), the systemic and pulmonary haemodynamic effects of the NO synthase inhibitor, Nomega-nitro-L-arginine methyl ester (L-NAME, 20 mg kg(-1)) and substrate, L-arginine (200-500 mg kg(-1)), were determined at baseline and during alveolar hypoxia. Constant blood flows were accomplished by biventricular bypass, and systemic normoxaemia was maintained by extracorporeal oxygenation. RESULTS: The primary findings were: (a) L-NAME failed to increase baseline mean pulmonary arterial pressure (10.1 +/- 0.7 vs. 10.5 +/- 0.5 mmHg, P=ns), despite effective NO synthase inhibition as evidenced by robust increases in systemic arterial pressures; (b) L-NAME augmented the pulmonary hypertensive response to alveolar hypoxia (10.2 +/- 0.7 to 19.5 +/- 1.7 with L-NAME vs. 9.9 +/- 1.1 to 15.5 +/- 1.0 mmHg without L-NAME, P<0.05); and (c) L-arginine failed to decrease baseline or elevated pulmonary pressures. Instead, prolonged L-arginine caused increases in pulmonary pressure. CONCLUSION: These findings suggest that NO plays no significant role in the tonic physiological control of pulmonary pressure, but endogenous NO becomes an important vasodilatory modulator during elevated pulmonary pressure.     

Carotid-sinus baroreflex modulation of core and skin temperatures in rats: an open-loop approach

The neural mechanisms of the thermoregulatory control of core and skin temperatures in response to heat and cold stresses have been well clarified. However, it has been unclear whether baroreceptor reflexes are involved in the control of core and skin temperatures. To investigate how the arterial baroreceptor reflex modulates the body temperatures, we examined the effect of pressure changes of carotid sinus baroreceptors on core and skin temperatures in halothane-anesthetized rats. To open the baroreflex loop and control arterial baroreceptor pressure (BRP), we cut vagal and aortic depressor nerves and isolated carotid sinuses. We sequentially altered BRP in 20-mmHg increments from 60 to 180 mmHg and then in 20-mmHg decrements from 180 to 60 mmHg while measuring systemic arterial pressure (SAP), heart rate (HR), and core blood temperature (T(core)) at the aortic arch and skin temperature (T(skin)) at the tail. In response to the incremental change in BRP by 120 mmHg, SAP, HR, and T(core) fell by 90.3 +/- 5.1 mmHg, 60.3 +/- 10.5 beats min(-1), and 0.18 +/- 0.01 degrees C, respectively. T(skin) rose by 0.84 +/- 0.10 degrees C. The maximum rate of change per unit BRP change was -2.1 +/- 0.2 for SAP, -1.5 +/- 0.4 beats min(-1) mmHg(-1) for HR, -0.003 +/- 0.001 degrees C mmHg(-1) for T(core), and 0.011 +/- 0.002 degrees C mmHg(-1) for T(skin). After the administration of hexamethonium or bretylium, these baroreflexogenic responses were completely abolished. We concluded that T(core) and T(skin) are modulated by the arterial baroreceptor reflex.     

Constant flow- vs. constant pressure-perfusion for studies of pulmonary vasoactive responses

We have compared the pulmonary vascular responses to a standardized hypoxic vasoconstrictor stimulus (F_1,0,2=0.02) obtained during 1) constant volume inflow, with pulmonary arterial pressure as the dependent variable, and 2) constant inflow pressure, with flow as the dependent variable. Isolated rat lungs were perfused at different baseline transvascular pressures. The experimental arrangement allowed changes between the two types of perfusion. Hypoxia at constant pressure perfusion gave a higher percentage rise in pulmonary vascular resistance (PVR) at all pressure levels. This advantage was however, more than offset by the finding that a) vascular closure (total or partial) often occurred, particularly below arterial pressure of 3 kPa, making detection of graded responses impossible, and b) the control situation was rarely regained. Responses obtained during constant flow were less reduced by elevations in baseline transvascular pressure, and the control situation was rapidly and completely regained. The observation that hypoxic vascular closure may occur in the pulmonary vascular bed supports the hypothesis that high altitude edema is caused by precapillary occlusion of a major part of the vascular bed, thereby subjecting still perfused regions to very high pressures and flow.     

Sympathoadrenal mechanisms in hemodynamic responses to gastric distension in cats

There is presently little information on the efferent mechanisms responsible for the reflex cardiovascular activation during passive gastric distension. Therefore, 40 cats anesthetized with alpha-chloralose were studied with passive gastric balloon distention before and during 1) two repeated gastric distensions, 2) beta-adrenergic blockade with propranolol, 3) alpha-adrenergic blockade with phentolamine, or 4) bilateral adrenalectomy. Before and during each distension mean arterial pressure, heart rate, cardiac output, rate of rise of left ventricular pressure (dP/dt) at 40 mmHg developed pressure and calculated systemic vascular resistance were determined. Repeated gastric distension caused similar hemodynamic responses without tachyphylaxis. beta-Blockade significantly reduced the increase in dP/dt from 893 +/- 362 to 150 +/- 63 mmHg/s. alpha-Blockade significantly altered the changes in mean arterial pressure from 33 +/- 5.0 to -2 +/- 4.7 mmHg and systemic vascular resistance from 0.114 +/- 0.019 to 0.004 +/- 0.031 peripheral resistance units. Bilateral adrenalectomy significantly diminished the contractile response from 525 +/- 107 to 50 +/- 85 mmHg/s but did not significantly alter the pressor and vasoconstrictor responses. We conclude that, during passive gastric distension in cats, the increase in myocardial contractility is mediated by beta-adrenergic-receptor stimulation, whereas the arterial vasoconstrictor and pressor responses are mediated by alpha-adrenergic receptor stimulation. Additionally, during gastric distension a substantial portion of the contractile response is dependent on the integrity of the adrenal glands.     

Effect of hypoxia on vascular responses to the carotid baroreflex.

The effect of systemic hypoxia on the vascular responses to the carotid baroreflex was studied in anesthetized, vagotomized, artificially ventilated dogs. One hindlimb, kidney, gracilis muscle, and paw were perfused at constant flow, and neurograms were obtained from renal sympathetic fibers. Bilateral carotid occlusions were performed while the animal was breathing a mixture of air and O2 (mean arterial PO2 = 106 mmHg) and again during ventilation with 10% O2 (PO2 = 40 mmHg). With occlusion, the average increase in mean aortic pressure was 36 mmHg greater during hypoxia than during normoxia and the increase in renal perfusion pressure was 87 mmHg greater; the increase in hindlimb perfusion pressure was identical in both situations. Hypoxia did not change the reflex response of the paw to carotid occlusion and increased that of the muscle vessels by only 10%; the increase in renal sympathetic activity averaged 56 plus or minus 10% more with hypoxia than with normoxia. When the carotid chemoreceptors were destroyed, the greater increase in aortic and renal pressure response to carotid occlusion during hypoxia as compared to normoxia was abolished. Thus systemic hypoxia markedly potentiates the reflex renal constriction caused by the baroreflex, and this effect is due to the carotid chemoreceptor afferent input.     

The influence of heart rate on baroreceptor fibre activity in the carotid sinus and aortic depressor nerves of the rabbit

The arterial baroreceptors and their afferent fibres provide the sensory arm of the reflex that regulates systemic arterial pressure. We have examined whether the relationship between mean baroreceptor discharge and mean arterial pressure is altered when heart rate changes. Experiments were performed on pentobarbitone-anaesthetized rabbits. We recorded the activity of single and multifibre preparations of the carotid sinus (CSN) and aortic depressor nerves (ADN). Data were collected under control conditions and while heart rate was increased by approximately 30-35% by right atrial pacing. Baroreceptor regions were exposed to ramps of pressure (from approximately 25 to 140 mmHg, at approximately 0.5-1 mmHg s(-1)), generated by inflation and deflation of cuffs placed around the inferior vena cava and descending thoracic aorta. Response curves relating baroreceptor discharge to mean pressure were constructed and fitted with third-order polynomial expressions. To provide a measure of an effect of an increase in heart rate on the response curve in the region of the normal operating pressure, we calculated the position of the test response curve relative to the position of the control curve at 90 mmHg (deltaBP(90)). For the ADN, the activity of single fibres (presumptive myelinated fibres) was unaffected by increasing heart rate (deltaBP(90) = +0.1 +/- 1.0 mmHg), while single fibres in the CSN showed a small increase in activity (deltaBP(90) = -1.5 +/- 0.3 mmHg). In multifibre preparations there was a small increase in activity that may be attributable to additional activity in unmyelinated fibres (ADN, deltaBP(90) = -3.4 +/- 1.2 mmHg; CSN, deltaBP(90) = -5.2 +/- 0.9 mmHg). We conclude that the mean discharge of arterial baroreceptors remains a reliable index of mean arterial pressure in the presence of substantial changes in heart rate.     

Mechanisms of hypotensive effects of a posture change from seated to supine in humans.

The hypothesis tested was that the hydrostatic stimulation of carotid baroreceptors is pivotal to decrease mean arterial pressure at heart level during a posture change from seated to supine. In eight males, the cardiovascular responses to a 15-min posture change from seated to supine were compared with those of water immersion to the xiphoid process and to the neck, respectively. Left atrial diameter and cardiac output (rebreathing) increased similarly during the posture change and water immersion to the xiphoid process and further so during neck immersion. Mean arterial pressure decreased by 12 +/- 2 mmHg during the posture change, by 5 +/- 1 mmHg during xiphoid immersion, and was unchanged during neck immersion. Arterial pulse pressure increased by 12 +/- 3 mmHg during the posture change (P < 0.05) and less during xiphoid and neck immersion by 7 +/- 3 mmHg (P < 0.05). Total peripheral vascular resistance decreased similarly during the posture change and neck immersion and slightly less during xiphoid immersion (P < 0.05). In conclusion, the hydrostatic stimulation of carotid baroreceptors combined with some additional increase in arterial pulse pressure, which also stimulates aortic baroreceptors, accounts for more than half of the hypotensive response at heart level to a posture change from seated to supine.     

Interplay among carotid sinus, cardiopulmonary, and carotid body reflexes in dogs.

Interactions among vascular reflexes evoked from carotid sinuses, carotid bodies, and cardiopulmonary region were examined in anesthetized, atropinized, and respired dogs with aortic nerves cut. The carotid sinuses were perfused at 220, 150, and 40-50 mmHg; the chemoreceptors were stimulated by perfusion with hypoxic hypercapnic blood. Cardiopulmonary vasomotor inhibition was interrupted by vagal cold block. Measurements were made of arterial blood pressure and of kidney and hindlimb vascular resistance. At sinus pressures less than 170-160 mmHg, cardiopulmonary vasomotor inhibition increased with increase in blood volume. At high sinus pressure, interruption of this augmented cardiopulmonary inhibition was as ineffective in changing vascular resistance as interruption of the lesser inhibition present during normovolemia. Chemoreceptor stimulation increased the response to vagal block at intermediate but not at high or low sinus pressure. The studies demonstrate the dominant role of the carotid sinus reflex when the three systems interact and the ineffectiveness of chemoreceptor stimulation when carotid or cardiopulmonary inhibition is maximal.     

Cardiovascular responses in apnoeic asphyxia: role of arterial chemoreceptors and the modification of their effects by a pulmonary vagal inflation reflex

1. In the spontaneously breathing anaesthetized dog, the systemic circulation was perfused at constant blood flow; there was no pulmonary blood flow and the systemic arterial blood P(O2) and P(CO2) were controlled independently by an extracorporeal isolated pump-perfused donor lung preparation. The carotid and aortic bodies were separately perfused at constant pressure with blood of the same composition as perfused the systemic circulation.2. Apnoeic asphyxia, produced by stopping the recipient animal's lung movements and, at the same time, making the blood perfusing the systemic circulation and the arterial chemoreceptors hypoxic and hypercapnic by reducing the ventilation of the isolated perfused donor lungs, caused an increase in systemic vascular resistance.3. While the systemic arterial blood was still hypoxic and hypercapnic, withdrawal of the carotid and aortic body ;drive' resulted in a striking reduction in systemic vascular resistance. Re-establishing the chemoreceptor ;drive' immediately increased the vascular resistance again.4. Apnoeic asphyxia carried out while the carotid and aortic bodies were continuously perfused with oxygenated blood of normal P(CO2) had little or no effect on systemic vascular resistance.5. The systemic vasoconstrictor response produced by apnoeic asphyxia was reduced or abolished by re-establishing the recipient animal's lung movements, and this effect occurred in the absence of changes in the composition of the blood perfusing the systemic circulation and arterial chemoreceptors. This abolition of the vasoconstriction was due to a pulmonary reflex.6. Apnoeic asphyxia slowed the rate of the beating atria due to excitation of the carotid and aortic body chemoreceptors. This response can be over-ridden by an inflation reflex arising from the lungs.7. It is concluded that the cardiovascular responses observed in apnoeic asphyxia are due, at least in part, to primary reflexes from the carotid and aortic body chemoreceptors engendered by arterial hypoxia and hypercapnia. The appearance of these responses is, however, dependent upon there being no excitation of a pulmonary (inflation) vagal reflex.     

Much more potent baroreflex sympathetic control of vascular resistance in the resting human limb than previously believed

The concept that, in man, the sympathetic control of the resting limb vascular resistance is truly limited and thus strikingly different from animal species, was challenged in the present study. Analyses were performed in healthy male volunteers of reflex forearm vascular resistance changes evoked by lower body negative pressure (LBNP) ranging from low (15 mmHg) to high and barely tolerated (85 mmHg) levels. Graded LBNP was associated with graded increases in resistance. At high 85 mmHg LBNP the responses were pronounced with a rise in forearm resistance to no less than 120 mmHg ml^-1 min 100+ ml soft tissue, on average, corresponding to a 377% increase above control. This drastic response seemed entirely neurogenic in origin and calculations, based on the likely assumption that a similar response occurred in all skeletal muscle and skin/(subcutaneous fat), showed that it permitted a marked increment in total systemic vascular resistance because of the fact that these tissues constitute so large a proportion of the body mass. The conclusion was reached that the studied tissues may serve as main targets for powerful homeostatic reflexes. It is also suggested, in contrast to current views, that the high-pressure arterial rather than the low-pressure cardio-pulmonary baroreceptors may be the main mediators of haemodynamically important vasoconstrictor responses.     

Atrial natriuretic peptide attenuates an increase in pulmonary vascular incremental resistance due to high pulmonary venous pressure.

The aim of this study was to determine whether an elevation of pulmonary venous pressure (PVP) and atrial natriuretic peptide (ANP) affects pulmonary vascular resistance (PVR) and pulmonary vascular incremental resistance (iPVR). We vascularly isolated the left lower lobe of the lung and perfused it with blood using a pulsatile pump. Blood flow (PBF) to the isolated lobe was decreased in 6 to 7 steps from about 8 to 1 ml/(kg.min). PVR was calculated from measurements of PBF and the pressure difference between pulmonary arterial pressure and PVP at four different levels of fixed PVP. iPVR was estimated from a slope of the pressure-flow relationships between effective pulmonary driving pressure and PBF at four different levels of fixed PVP. iPVR was 2.2 +/- 0.2, 2.2 +/- 0.1, 2.4 +/- 0.1, and 2.6 +/- 0.2 mmHg.min.kg/ml, when PVP was 0, 5, 10, and 15 mmHg, respectively. To test whether or not the response of the pulmonary vascular bed to the elevated PVP is modulated by ANP, iPVR was estimated before and after an administration of ANP in the perfusion circuit. Increased iPVR from 2.1 +/- 0.2 to 2.5 +/- 0.2 mmHg.min.kg/ml in response to the elevation of PVP from 0 to 15 mmHg decreased to the control level after the administration of ANP. ANP, however, did not change the control iPVR. PVR decreased with increasing PVP. ANP decreased PVR when PVP was 0 mmHg, but did not change it when PVP was 15 mmHg. These results suggest that ANP decreases PVR and restores the decreased pulmonary vascular compliance.     

Carotid baroreceptor reflexes in humans during orthostatic stress

Orthostatic stress, including standing, head-up tilting and lower body suction, results in increases in peripheral vascular resistance but little or no change in mean arterial pressure. This study was undertaken to determine whether the sensitivity of the carotid baroreceptor reflex was enhanced during conditions of decreased venous return. We studied eight healthy subjects and determined responses of pulse interval (ECG) and forearm vascular resistance (mean finger blood pressure divided by Doppler estimate of brachial artery blood velocity) to graded increases and decreases in carotid transmural pressure, effected by a neck suction/pressure device. Responses were determined with and without the application of lower body negative pressure (LBNP) at -40 mmHg. Stimulus-response curves were determined as the responses to graded neck pressure changes and the differential of this provided estimates of reflex sensitivity. Changes in carotid transmural pressure caused graded changes in R-R interval and vascular resistance. The cardiac responses were unaffected by LBNP. Vascular resistance responses, however, were significantly enhanced during LBNP and the peak gain of the reflex was increased from 1.2 +/- 0.3 (mean +/- S.E.M.) to 2.2 +/- 0.3 units (P < 0.05). The increased baroreflex gain may contribute to maintenance of blood pressure during orthostatic stress and limit the pressure decreases during prolonged periods of such stress.     

An analysis of the reflex systemic vasodilator response elicited by lung inflation in the dog

1. A maintained inflation of the lungs caused a reflex reduction in total systemic vascular resistance in anaesthetized dogs under conditions in which the systemic circulation was perfused at constant blood flow and the arterial blood P(O2) and P(CO2) were maintained constant.2. The fall in systemic arterial perfusion pressure evoked by inflation of the lungs was accompanied by an increase in blood flow to the lower limbs and a reduction in their calculated vascular resistance. Since the fall in resistance occurred when the limb was perfused either at constant pressure or at constant blood flow, it must be due to vasodilatation.3. Lung inflation caused vasodilatation in skin, muscle, and in the splanchnic vascular bed. The responses in vertebral circulation were, however, small and variable.4. The vasodilator responses in the vascular territories studied were reflex in nature, being abolished by cutting the cervical vagosympathetic nerves, in which run the afferent fibres, or by interrupting the sympathetic pathways to the blood vessels.5. In the intact limb, muscle, skin and splanchnic vascular bed, the vasodilator responses to lung inflation were unaffected by atropine or propranolol, but were abolished by hexamethonium, dibenyline and bretylium tosylate, indicating that they were due predominantly to a reduction in the activity in sympathetic adrenergic vasoconstrictor fibres.