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.     

Effects of graded pulsatile pressure on the reflex vasomotor responses elicited by changes of mean pressure in the perfused carotid sinus-aortic arch regions of 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. We have confirmed our previous observations that under steadystate conditions the vasomotor responses elicited reflexly by changes in mean carotid sinus pressure are modified by alterations in carotid sinus pulse pressure, whereas those evoked by changes of mean aortic arch pressure are only weakly affected by modifications of aortic pulse pressure.3. When the carotid sinus and aortic arch regions are perfused in combination at constant pulse frequency (110 c/min), the relationship between mean carotid sinus-aortic arch pressure and systemic arterial perfusion pressure is dependent on the size of the pulse pressure.4. Increasing the pulse pressure alters the curve relating the mean carotid sinus-aortic arch pressure to systemic arterial perfusion pressure in such a way that the perfusion pressure is lower at a given carotid sinus-aortic arch pressure within the range 80-150 mm Hg. The larger the pulse pressure, up to about 60 mm Hg, the greater the fall in systemic arterial perfusion pressure. Above a mean carotid sinus-aortic arch pressure of about 150 mm Hg, alterations of pulse pressure have little effect.5. There is a family of curves representing the relation between mean carotid sinus-aortic arch pressure and systemic vascular resistance, depending on the pulse pressure.     

The role of interoceptors in the regulation of blood coagulation

Summary The role of interoceptors of carotid sinus and of the arch of aorta in acceleration of blood coagulation in acute blood loss was investigated. It was revealed by 29 experiments on rabbits and 10 on dogs that local anemia of sinocarotid zones causes reflex acceleration of blood coagulation. Blood loss in rabbits with denervated carotid sinuses is associated with the weaker response of acceleration of blood coagulation, than in normal animals. With exclusion of the sinus, depressor and vagus nerves the acceleration of the blood coagulation and increase of thrombin titer is not as considerable as following blood loss in the intact animals.Presented by Active Member Acad. Med. Sci. USSR V. V. Parin     

The cause of the difference between the arterial baroreceptor reflex under natural pulsatile circulation and under nonpulsatile systemic circulation

In a previous study we investigated the relation between afferent and efferent activity of the arterial baroreceptor reflex under nonpulsatile systemic circulation using total left heart bypass. The results indicated that the regulation of the arterial baroreceptor reflex was converted under nonpulsatile systemic circulation, and we inferred that a possible reason for this conversion was the transformation in discharge of the afferent activity of the arterial baroreceptor reflex that took place under nonpulsatile systemic circulation. In the present study we tested this hypothesis by sectioning carotid sinus and aortic depressor nerves and electrically stimulating bilateral aortic depressor nerves under anesthesia in five rabbits (400 spikes for 20s, with 0.02ms pulse width and 8 V amplitude), while recording changes in aortic pressure, mean aortic pressure, and heart rate. Continuous stimulation was taken as discharge of the afferent activity of the arterial baroreceptor reflex under nonpulsatile systemic circulation, and periodic stimulation was taken as discharge under natural pulsatile circulation. Aortic pressure, mean aortic pressure, and heart rate decreased under both continous and periodic stimulation. The decreases in mean aortic pressure and heart rate during continuous stimulation were significantly lower than those during periodic stimulation. Our results suggest that the transformation in discharge of the afferent activity of the arterial baroreceptor reflex under nonpulsatile systemic circulation may have played an important causative role in the conversion of the regulation of the arterial baroreceptor reflex under nonpulsatile systemic circulation.     

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.     

Interaction of aortic and carotid sinus baroreceptors: effect of activation times.

Changes in pulse-wave velocity were simulated by changing the relative timing between aortic and carotid sinus barorecptor activity in anesthetized rabbits and dogs. In the rabbit, electrical stimulation was used to vary the timing; in the dog, it was also varied by perfusing the carotid sinuses with externally generated pressure pulses that could be triggered in any portion of the cardiac cycle. Changing the relative delay between aortic and carotid sinsus nerve stimulation did not result in variations of blood pressure or heart rate in the rabbit. Varing the time of electrical stimulation of the carotid sinus nerve caused at most 5 mmHg change of blood pressure in the dog. Delay-related heart-rate changes could be usually observed only when the stimulus consisted of short, high-intensity bursts. When the carotid sinus was externally perfused with pulses of pressure, only one out of five dogs showed delay-related variations in blood pressure (3mmHg) and heart rate (6 beats/min). It is concluded that variations in pulse-wave velocity are unlikely to play a significant role in acute cardiovascular control.     

Comparison of the reflex responses elicited by stimulation of the separately perfused carotid and aortic body chemoreceptors in the dog

1. In dogs under chloralose and urethane anaesthesia, the carotid and aortic bodies were isolated from the circulation and separately perfused with blood, the composition of which could be controlled at will. The remainder of the systemic circulation was perfused at constant blood flow, thereby enabling the reflex vascular responses to be determined. The systemic venous blood was oxygenated in the isolated perfused lungs of a second dog and the P(O2) and P(CO2) of the systemic arterial blood was maintained constant.2. Using hypoxic hypercapnic blood to stimulate the arterial chemoreceptors, carotid body excitation in spontaneously breathing animals caused an increase in respiratory minute volume approximately seven times larger than that evoked by stimulation of the aortic bodies. Whereas the hyperpnoea of carotid body origin is due to an increase in rate and depth of breathing, that from the aortic bodies is due predominantly to an increase in respiratory frequency.3. Stimulation of the carotid bodies in spontaneously breathing animals caused small variable changes in systemic vascular resistance, whereas stimulation of the aortic bodies invariably increased the vascular resistance.4. When pulmonary ventilation was maintained constant, the vascular response to stimulation of the carotid bodies was considerably modified in that constriction invariably occurred; that from the aortic bodies, however, was little affected. There was now no significant difference in the size of responses from the two groups of chemoreceptors. These constrictor responses represent the primary vascular effects.5. A similar modification of the carotid body vascular response occurred in the spontaneously breathing animal after denervation of the lungs, and is due to abolition of a lung-inflation vasodilator reflex.6. The size of the primary vasoconstrictor responses from the carotid and aortic bodies is reduced by lowering the arterial blood P(CO2).7. The results indicate that there is a fundamental difference in the functions of the carotid and aortic bodies. They exert a quantitatively similar primary control of the ;vasomotor centre' which is in striking contrast to the relatively more powerful influence on respiration by the carotid bodies. In the spontaneously breathing animal, however, the primary vasoconstrictor response from the carotid bodies is offset to a varying degree by the lung-inflation vasodilator reflex initiated by the concomitant hyperpnoea. This is not evident with the aortic bodies because of the relatively weaker respiratory response they evoke.     

Der Einfluß einer konstanten Herzfrequenz auf den Carotis-Sinus-Reflex am wachen Hund

Summary In healty, conscious dogs the heart rate was kept constant at 144 to 146 beats per minute either by vagal blockade with Atropine (0,5 mg/kg i.v.) or by electrical pacing of the heart. In the resting dog a carotid-sinus-reflex was elicited clamping both common carotid arteries with implanted pneumatic cuffs. Velocity in the ascending aorta (electromagnetic flowmeter), pressure in the descending thoracic aorta (implanted miniature pressure transducer) and pressure in the right carotid sinus using a catheter were measured. By analogue processing acceleration in the ascending aorta, stroke volume and stroke work of the left ventricle, and mean values were derived. Compared to the reflex under normal resting heart rates (64 beats per minute) the results show, that with a constant heart rate (144–146 beats per minute) blood pressure rises by about the same amount induced by a larger increase of the peripheral resistance. Because the fast increase of cardiac output regularly observed under normal conditions was eliminated, the time course of pressure elevation was slower when heart rate was kept constant. The elevated stroke work of the left ventricle during carotid occlusion cannot be explained by an increase of contractility due to enhanced sympathetic activity, because no such increase in contractility was found.It is suggested, that a low control heart rate allows fast reflex adjustment of blood pressure mediated by increases of cardiac output due to vagal inhibition. In contrast, when heart rate is high due to vagal blockade or electrical pacing, the reflex response is determined by slow changes of the total peripheral resistance.

Mit dankenswerter Unterstützung der Deutschen Forschungsgemeinschaft (S.F.B. 90).     

Central actions of angiotensin II on heart rate and blood pressure in mongrel dogs

Angiotensin II is produced physiologically in response to renal ischaemia due to hypotension. It's effect on heart rate and blood pressure were studied on anaesthetised mongrel dogs. Angiotensin II was given in different concentrations, by intravenous, intraarterial in carotid artery and intracerebroventricular routes. Cervical vagotomy and carotid sinus inactivation were done is abolish the reflex inhibition produced by baroreflexes. Rise of B.P. is due to mainly peripheral vasopressor action of angiotensin II, however it is shown to have a central component as well. This is demonstrated by ICV injections. Tachycardia due to central action is also demonstrated in this study. Both actions are significant. This study also confirm the earlier findings that angiotensin II passes the blood brain barrier.     

Evidence for central reorganization of ventilatory chemoreflex pathways in the cat during regeneration of visceral afferents in the carotid sinus nerve

There are two sets of peripheral arterial chemoreceptors in the cat, the carotid bodies innervated by the carotid sinus nerve and the aortic bodies with afferents in the aortic depressor nerves. Reflex stimulation of ventilation in response to hypoxia is abolished acutely after interrupting the sensory pathway from the carotid body chemoreceptors in the cat even though the reflex pathway from the aortic body chemoreceptors is intact. However, in chronically maintained preparations, there is a restoration of the hypoxic response which is mediated by the aortic chemoreflex pathway. It was proposed that restoration was due to a ‘central reorganization’ of chemoreflex pathways which followed interruption of the sensory pathway from the carotid bodies and that the reorganization enhanced the efficacy of the aortic ventilation chemoreflex. This proposal was tested in the present experiments by measuring reflex ventilatory and cardiovascular responses to electrical stimulation of the sensory nerves containing aortic and carotid chemoreceptor afferents following bilateral interruption of carotid sinus nerves and carotid body resection. Responses measured acutely (1–6 h) after interruption were compared with those measured 60–80 and 110–140 days later. At 60–80 days, a chemoreflex response (increase in tidal volume of ventilation) to stimulation of the interrupted carotid sinus sensory pathway was markedly attenuated while the response to stimulation of the uninterrupted pathway in aortic depressor nerves was enhanced. At 110–140 days, the tidal volume response to carotid sinus nerve stimulation was greatly enhanced while the aortic depressor nerve response declined from the elevated level. There were significant but less pronounced changes in the response of other ventilatory and cardiovascular variables to aortic depressor nerve and carotid sinus nerve stimulation.The results support the idea that there is a ‘central reorganization’ of chemoreflex pathways which is reflected functionally by changes in the efficacy of reflexes evoked from aortic depressor nerve and carotid sinus nerve. The changes are analagous to those occurring in somatic reflexes during regeneration of sensory nerves. It is suggested that the changes in efficacy of carotid sinus nerve reflexes are due to a degenerative loss of synapses of the central projections of interrupted carotid sinus nerve sensory axons (degenerative atrophy) and subsequent regenerative like changes (regenerative proliferation) in the central projections. The changes in the efficacy of aortic depressor nerve reflexes may be attributed to formation of new synapses by converging central projections of this uninterrupted pathway (reactive synaptogenesis) and subsequent regression of the newly formed synapses.     

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)     

Transitory cardiovascular responses to rapid infusion of blood into aorta of rabbit

Blood (5 to 15 ml) was infused into aorta of the anesthetized rabbit through the carotid artery or femoral artery at a constant rate (0.55 to 8.3 ml/s). The carotid sinuses were occluded. The systemic arterial pressure (SAP) began to rise immediately at the onset of the infusion and dropped gradually in most cases during the infusion. SAP continued to decline after the infusion and in many cases became lower than the preinfusion pressure. Within seconds, SAP tapered off to its lowest point and resumed a gradual rise, leveling off higher than its initial pressure. A depressor effect caused by the rapid infusion of blood into the aorta (DRIA) was observed in every rabbit. DRIA was not suppressed much by the section of aortic or vagal nerves. DRIA was markedly suppressed by the administration of alpha-adrenergic blockade, but beta-adrenergic blockade had little effect on DRIA. By using a hydraulic model of the closed circulatory system, a theoretical analysis was made on the basis of the "theory of active fluid element," a theory developed by Hatakeyama, one of the authors, and it was demonstrated that DRIA must not be considered to be a passive hemodynamic phenomenon. The results obtained suggest that a nervous regulatory mechanism--rather than the reflex via the carotid sinus or aortic baroreceptors, or other mechanoreceptors--plays an important part in the venous and the cardiac regions.     

Degenerative and regenerative changes in central projections of glossopharyngeal and vagal sensory neurons after peripheral axotomy in cats: a structural basis for central reorganization of arterial chemoreflex pathways

Hypoxic hyperventilation in cats is a reflex normally initiated by afferent impulses originating in the carotid body and conducted to the brain stem by the carotid sinus nerves. The reflex response is abolished acutely after section of carotid sinus nerves and excision of the carotid bodies; but, chronically, there is a chemoreflex restoration which is mediated by the aortic body via the aortic depressor nerves. The restoration is associated temporally with changes in efficacy of ventilatory reflexes elicited by electrically stimulating carotid sinus and aortic depressor nerves, and these changes are postulated to reflect a central reorganization of the reflex pathways. In the present study, histological and ultrastructural techniques were used to investigate the neuroanatomical basis of the reorganization. The brain stem of the cat was examined using the Fink-Heimer silver stain to determine if degenerating axons were present following section of the carotid sinus nerve peripheral to its sensory ganglion. Degeneration was found 4-15 days postoperatively and the distribution of the axons corresponded with that reported for central projections of carotid sinus nerves labeled by transganglionic transport of horseradish peroxidase. The fine structure of nerve terminals in nucleus tractus solitarius was then examined with electron microscopy after cutting the vagus and glossopharyngeal nerves unilaterally peripheral to the sensory ganglia. Structural changes consistent with nerve terminal degeneration were observed 4-91 days postoperatively, and presumptive axonal sprouts were seen at 56-91 days.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dependence of blood pressure changes in cats during acute hypoxic hypoxia on the type of carotid sinus reflex

The type and degree of blood pressure changes in cats were studied in acute experiments under conditions of acute hypoxic hypoxia (40% decrease in oxygen partial pressure). During hypoxia, blood pressure increased in cats with pressor type of the carotid sinus reflex and decreased in animals with depressor type of this reflex. Our results indicate that the direction and degree of hypoxic changes in blood pressure in animals coincide with variations in this parameter in response to the carotid sinus reflex. __________ Translated from Byulleten’ Eksperimental’noi Biologii i Meditsiny, Vol. 142, No. 11, pp. 490–493, November, 2006     

The effect of time of electrical stimulation of the carotid sinus on the amount of reduction in arterial pressure

Summary On narcotised dogs, the carotid sinus nerve was stimulated by means on electrical R-wave-triggered pulse trains when depressor nerves were either intact or cut.The stimulation was begun in the range from 0–210 msec after the R-wave. The effectiveness of pulse trains was determined by the level of reduction in mean arterial pressure.In the time range studied, the level of reduction in pressure versus time of stimulation shows two maxima of reduction at 30 and 90 msec and a plateau from 110–150 msec. Stimuli applied later than 150 msec after the R-wave, display a contnuous reduction in effectiveness.The occurrence of the maxima is considered to be due to a coincidence of the pressor afferences from heart, aortic arch and carotid sinus, arriving at the circulatory centres spaced in time with the electrical stimuli.The times at which the maxima of reduction are found to occur could be significant in programming baropacers.     

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.     

Arterial baroreceptors have minimal physiological effects on adrenal medullary secretion

The influence of arterial baroreceptors on secretion of catecholamines from the adrenal medulla was evaluated by several methods. Conscious mongrel dogs with surgically denervated hearts were hemorrhaged until an estimated 16% of their blood volume had been removed. On a separate day they were anesthetized and their blood pressure was lowered with intravenous nitroglycerin. Neither of these maneuvers produced appreciable increases in heart rate in these dogs. In contrast, in a group of sham-operated control dogs, hemorrhage induced a mean increase in heart rate of 20 beats/min (P less than 0.05), and nitroglycerin-induced hypotension induced an increase of 50 beats/min (P less than 0.05). In a separate group of conscious dogs with aortic arch denervation but intact cardiac nerves, occlusion of the common carotid arteries for 5 min increased blood pressure and heart rate significantly but elicited only small, insignificant increases in plasma epinephrine and norepinephrine; the peak concentration of epinephrine achieved was considerably less than the amount necessary to cause appreciable effects on blood pressure and heart rate as determined in another experiment by infusing varying amounts of epinephrine into conscious, cardiac-denervated dogs. We conclude that the arterial baroreceptor reflex, within the range of activity likely to occur during most physiological and pathophysiological adjustments in the conscious dog, exerts only minimal effects on the secretion of catecholamines from the adrenal medulla.     

Left ventricular inotropic and peripheral vasomotor responses from independent changes in pressure in the carotid sinuses and cerebral arteries in anaesthetized dogs

1. The pressure perfusing the isolated carotid sinuses and the pressure perfusing the cerebral circulation were changed independently, and the resulting inotropic responses in the left ventricle and peripheral vasomotor responses were determined.2. Inotropic responses were assessed by measuring changes in the maximum rate of change of left ventricular pressure (dP/dt max) with heart rate and mean aortic pressure held constant. Vascular resistance changes were usually assessed by perfusing the descending thoracic aorta at constant flow and measuring changes in perfusion pressure.3. Decreases in carotid sinus pressure over the baroreceptor sensitivity range resulted in a 45% increase in dP/dt max and a 59% increase in vascular resistance.4. Unless arterial oxygen tension was abnormally low, lowering cerebral perfusion pressure to 50 mm Hg resulted in little or no inotropic and vasomotor responses. In the presence of hypoxaemia (P(a,O2) < 60 mm Hg), lowering cerebral perfusion pressure to below about 80 mm Hg resulted in marked responses.5. These experiments suggest that, unless arterial oxygen tension is abnormally low, the carotid sinus reflex and not cerebral hypotension is important in the control of the inotropic state of the heart and of vasomotor activity. With hypoxaemia, responses from cerebral hypotension may also be important.     

Interactions between carotid sinus mechanoreceptor and chemoreceptor reflex loops

Summary Our experiments were designed to evaluate the combined influence of the mechanoreceptor and chemoreceptor control loops on the cardiovascular and respiratory systems. Both carotid sinus areas were isolated by a complete blind sac preparation in chloralose anesthetized dogs in which a flow probe had been implanted previously on the ascending aorta. The following variables were continuously monitored: central aortic pressure, heart rate, cardiac output, vascular resistance of a hind limb, tidal volume, respiratory rate, and oxygen consumption. While one sinus was submitted to step changes of pressure, the opposite sinus was kept at constant mean pressure. In addition, one sinus was perfused with either oxygenated of deoxygenated blood at constant flow rate.These studies show a definite interaction between the control loops initiated by the carotid sinus mechanoreceptors and those initiated by the chemoreceptors. The influence of the chemoreceptors is most marked in the peripheral beds, where it shifts the whole response curve of the mechanoreceptor control loop upward. This response accounts for most of the upward shift of the pressure response curve.On the other hand, the mechanoreceptor loop affects the ventilation, but this effect is range dependent, being most marked for the low pressure perfusion of the carotid sinus.This work has been supported in part by PHS Research grant HL 11747