Rapid resetting of low pressure vagal receptors in the superior vena cava of the rat

Multiple sensor theory in cardiovascular mechanosensory units

Multiple sensor theory (MST) has advanced our understanding of how lung mechanosensors operate. That is, single lung units contain multiple homogeneous or heterogeneous sensors. Each detects sensor-specific mechanical information and interacts with other sensors lying within the unit sending integrated information to the brain to evoke reflexes. MST explains numerous controversial issues in the respiratory system. Recent studies in baroreceptors (BRs), along with reinterpretation of recordings appearing in the literature, indicate MST also operates in the cardiovascular (CV) system. This review outlines evidence supporting MST in the CV system and provides examples to apply the theory. Longstanding controversies surrounding the CV sensors are also considered.

Regulation of breathing by cardiopulmonary afferents

This chapter broadly reviews cardiopulmonary sympathetic and vagal sensors and their reflex functions during physiologic and pathophysiologic processes. Mechanosensory operating mechanisms, including their central projections, are described under multiple sensor theory. In addition, ways to interpret evidence surrounding several controversial issues are provided, with detailed reasoning on how conclusions are derived. Cardiopulmonary sensory roles in breathing control and the development of symptoms and signs and pathophysiologic processes in cardiopulmonary diseases (such as cough and neuroimmune interaction) also are discussed.

Electrophysiological characterisation of atrial volume receptors using ex vivo models of isolated rat cardiac atria

NEW FINDINGS

What is the central question of this study? What ex vivo preparation of the rat's cavoatrial junction is efficient for characterising atrial mechanoreceptors? What is the main finding and its importance? Of four different ex vivo preparations, static pressure, flow, open and euthermic, the optimal preparation was the euthermic one and involved direct recording from the right cardiac vagal branch with a Langendorff style perfusion at 37°C. Type A receptors were most common, and appeared insensitive to stretch and sensitive to atrial contraction. Type B and intermediate receptors were not isolated at 20°C but were observed closer to 37°C. The findings may suggest that type A and B receptors utilise different molecular transduction mechanisms.

ABSTRACT

Atrial volume receptors are a family of afferent neurons whose mechanically sensitive endings terminate in the atria, particularly at the cavoatrial junctions. These mechanosensors form the afferent limb of an atrial volume receptor reflex that regulates plasma volume. The prevailing functional classification of atrial receptors arose as a result of in vivo recordings in the cat and dog and were classified as type A, B or intermediate according to the timing of peak discharge during the cardiac cycle. In contrast, there have been far fewer studies of the common small laboratory mammals such as the rat. Using several ex vivo rat cavoatrial preparations, a total of 30 successful single cavoatrial mechanosensory recordings were obtained. These experiments show that the rat possesses type A, B and intermediate atrial mechanoreceptors as described for larger mammals. Recording these cavoatrial receptors proved challenging from the main vagus, but direct recording from the cardiac vagal branch greatly increased the yield of mechanically sensitive single units. In contrast to type A units, type B atrial mechanoreceptor activity was never observed at room temperature but required elevation of temperature to a more physiological range in order to be detected. The adequate stimulus for these receptors remains unclear; however, type A atrial receptors appear insensitive to direct atrial stretch when applied using a programmable positioner. The findings may suggest that type A and type B atrial receptors utilise different molecular transduction mechanisms.

The role of supraspinal vasopressin and glutamate neurones in an increase in renal sympathetic activity in response to mild haemorrhage in the rat

This study investigated the importance of supraspinal vasopressin and glutamate neurones in regulating renal sympathetic activity as part of the response to an acute reduction in blood volume. Wistar rats anaesthetized with chloralose and urethane were instrumented to record arterial blood pressure, heart rate and left renal sympathetic nerve activity. Pharmacological agonists and antagonists to glutamate and vasopressin were applied to the renal outflow of the spinal cord via an intrathecal catheter inserted at the foramen magnum and with the tip at the level of T10. Both glutamate and vasopressin increased renal sympathetic activity, and these actions were shown to be selectively blocked by their respective antagonists. Removing 1 ml of venous blood from a femoral venous catheter elicited an increase of 26 +/- 2% in renal sympathetic activity. This response to mild haemorrhage was halved to 13 +/- 4% by prior intrathecal application of a selective V1a antagonist. Similarly, prior intrathecal application of kynurenic acid reduced the response to the mild haemorrhage from 28 +/- 2 to 12.6 +/- 2.8%. Intrathecal application of both antagonists together reduced the haemorrhage response even further to 8 +/- 3%. All the changes were statistically significant at P < 0.01. It is concluded that a small reduction in blood volume induces an increase in renal sympathetic activity dependent on vasopressin and glutamate release from terminals of supraspinal neurones. It is suggested that the vasopressin neurones most probably originate from the paraventricular nucleus of the hypothalamus.

Activity of cardiopulmonary baroreceptors, peripheral resistance and cutaneous microcirculation in patients with peripheral obstructive arterial disease

OBJECTIVES

To assess the effects of cardiopulmonary baroreceptors on the haemodynamics of the humeral and common carotid arteries in patients suffering from peripheral artery disease (PAD) and to discover whether the stimulation of these receptors modifies the cutaneous microcirculation in the forearm.

DESIGN

We studied a group of patients suffering from peripheral artery disease and two groups as controls.

SETTING

Patients were examined at the ambulatory for Vascular Research, Division of Vascular Medicine and Rehabilitation, University of Verona.

PATIENTS

We studied 15 patients with peripheral artery disease of the lower limbs at Fontaine stage II (group C), 10 free of arterial pathologies (group B) and 10 young people (group A).

MAIN OUTCOME MEASURES

We subjected the patients to passive elevation of the legs and the trunk in a horizontal position with pressure monitoring and measurement of the calibre and flow in the brachial and common carotid arteries using a colourDoppler ultrasound. We also studied the cutaneous microcirculation with laserDoppler flowmetry.

RESULTS

During the test, arterial pressure and cardiac frequency remained constant in group A, systolic pressure values showed a slight, but statistically significant increase in group B, whilst the increase in systolic pressure values at this stage was marked in group C. Diastolic pressure values and cardiac frequency remained unchanged in all groups. The calibre of the humeral artery increased in the control groups. Carotid resistance was unchanged in the three groups. Humeral resistance during the test decreased in the two control groups whilst it increased in group C. The number of perfusion units felt in the control groups; no variations in group C.

CONCLUSIONS

Our study demonstrates, in patients with peripheral artery disease, a reduction in the activity of the cardiopulmonary baroreceptors with an increase in the humeral resistance during the test and impairment of the mechanisms of cutaneous microcirculatory vasoregulation in the forearm.

Effect of cardiac receptor stimulation on renal vascular resistance in the pregnant rat

Stimulation of cardiac receptors (CR) evokes blunted reflex reductions in mean arterial pressure (MAP) in pregnant compared with virgin rats. Because CR-mediated sympathoinhibition has preferential effects on the kidney, we tested whether, during pregnancy, renal vascular resistance (RVR) changes less in response to CR stimulation and investigated possible mechanisms. MAP, right atrial pressure, renal sympathetic nerve activity (RSNA), renal blood flow (RBF), and RVR were measured in anesthetized animals in response to CR stimulation by graded atrial injections of saline. Baseline MAP and RVR and reflex changes in these variables during CR stimulation were reduced in late-pregnant vs. virgin rats (P<0.05). Reflex changes in RSNA were attenuated in pregnant rats, but changes in RBF as a function of RSNA were similar in both groups. ANG II AT(1)-receptor blockade increased basal RBF more in virgin rats (P<0.05), but between-group differences in reflex changes in MAP, RSNA, and RVR were maintained after AT(1) blockade. Thus during CR simulation, reflex changes in RVR were reduced in pregnant versus virgin rats. This difference does not appear to involve differential effects of ANG II.

Pregnancy alters cardiac receptor afferent discharge in rats

Reflex effects of cardiac receptor (CR) stimulation are attenuated in pregnant rats. We tested whether CR afferent discharge is reduced during pregnancy by measuring single fiber activity in response to increases in right atrial pressure (RAP) in anesthetized pregnant and virgin rats with sinoaortic denervation. Single fiber activity was isolated from fine filaments of the right cervical vagus nerve. Changes in CR discharge, RAP, and arterial pressure were recorded in response to atrial saline injections (25-300 microl). Resting RAP was similar between groups, and spontaneous CR discharge was similar in pregnant rats (1.95+/-0.21 Hz) and in low-frequency (LF) receptors in virgin rats (1.30+/-0.2 Hz). In virgin, but not pregnant rats, a subset (24%) of CR had higher-frequency (HF) spontaneous discharge (9.91+/-1.19 Hz). During stimulation, the level of RAP above which CR firing increased was significantly higher in pregnant rats, but CR activity was clustered into an LF discharge range. Thus gestation appears to reduce the activity of CR afferents, possibly by increasing stimulus threshold or by selective inactivation of a subset of HF discharging receptors.

Blood pressure regulation in baroreceptor-denervated rats

1. Arterial baroreceptor denervation produces acute hypertension, but chronically denervated animals have an average arterial pressure that is similar to that of baroreceptor intact animals. 2. Although cardiopulmonary baroreceptors and renal compensations have been suggested to mediate the restoration of a normal average arterial pressure in sino-aortic denervated rats, such mechanisms are inconsistent with the available data. 3. At present the processes involved in the restoration and long-term maintenance of a normal average arterial pressure in chronic baroreceptor denervated animals are not known. An understanding of the regulation of arterial pressure that occurs in the absence of arterial baroreceptor reflexes may provide important new insights into the mechanisms underlying the long-term regulation of arterial pressure.

An atrial natriuretic factor analogue at low doses attenuates forearm reflex vasoconstriction to cardiopulmonary receptor deactivation in patients with hypertension

Contrasting data exist about a possible modulation of the autonomic function by atrial natriuretic factor (ANF) in human beings, particularly at low, biologically, significant concentrations. We have evaluated that possibility by increasing plasma ANF levels through the infusion of a synthetic analogue (WY-47,663, anaritide) in five male patients with mild to moderate uncomplicated hypertension. Nonhypotensive lower body negative pressure (-10 mm Hg x 5 min) was used to selectively deactivate cardiopulmonary receptors and to stimulate sympathetic efferent tone reflexogenically. ANF was given at either a low rate (0.005 micrograms/kg/min x 60 min, which was previously shown to increase plasma ANF in a range compatible with physiologic stimuli) or at a high rate (0.05 micrograms/kg/min x 60 min, each). Administration of ANF was preceded and followed by vehicle infusion (Haemacell x 30 min). Forearm blood flow (venous plethysmography), intraarterial blood pressure, and heart rate were monitored continuously, and venous immunoreactive ANF, plasma renin activity, aldosterone level, and venous hematocrit were measured at the end of both control and infusion periods. Arterial norepinephrine values, an indirect index of sympathetic discharge, were measured at rest and during lower body negative pressure conditions. Graded systemic ANF infusion increased immunoreactive ANF and venous hematocrit, decreased aldosterone level and plasma renin activity, whereas resting norepinephrine levels, blood pressure, and heart rate did not change. Lower body negative pressure decreased forearm blood flow during vehicle infusion, but it lost its vasoconstrictor effect during infusion of ANF. To identify the site of that inhibitory action, ANF was also infused into the brachial artery at rates that raised local but not systemic levels of immunoreactive ANF.(ABSTRACT TRUNCATED AT 250 WORDS)

Peripheral and central mechanisms of baroreflex resetting

1. A change in the arterial pressure-sympathetic activity or heart rate relation (baroreflex resetting) can result from resetting of baroreceptors ('peripheral' resetting) or from an altered coupling within the central nervous system of afferent baroreceptor to efferent nerve activities ('central' resetting). 2. 'Peripheral' resetting involves a shift in the pressure-baroreceptor activity curve in the direction of the prevailing level of arterial pressure, e.g. after elevations in pressure, the baroreceptor pressure threshold (Pth) is increased and activity reduced at equivalent pressures and vascular strains. 3. 'Peripheral' resetting occurs during the diastolic phase of a cardiac cycle (instantaneous resetting), after brief exposure to elevated pressure (acute resetting), and during chronic hypertension or when chronic structural changes in the vasculature have occurred (chronic resetting). 4. Mechanisms include: (i) changes in the mechanical properties of the vessel wall that may alter the tension on the receptors; (ii) ionic mechanisms operating at the neuronal membrane such as activation of Na+,K+-ATPase; and (iii) release of endothelial factors that may modulate baroreceptor sensitivity. 5. Acute resetting of baroreceptors can be prevented or attenuated when the sustained elevations in pressure are pulsatile rather than static. Increases in flow increase carotid sinus nerve activity at constant pressure and strain and decrease the Pth of baroreceptors. 6. 'Central' resetting can involve neural-humoral interactions or an altered responsiveness of central neurons mediating the baroreflex to changes in afferent baroreceptor activity. 7. During static pressure, the continuous baroreceptor discharge causes significant 'central' resetting, i.e. sympathetic activity escapes from baroreflex inhibition. In contrast, during pulsatile pressure, the pulse phasic baroreceptor discharge minimizes 'central' resetting causing sustained sympathetic inhibition.

Mechanisms of resetting of arterial baroreceptors: an overview

Arterial baroreceptors are reset when their afferent nerve activity is reduced at an equivalent arterial pressure and vascular strain. Resetting occurs as a result of stretch of the baroreceptors, usually during an acute or chronic rise in arterial pressure. It may be seen during the diastolic phase of a cardiac cycle (instantaneous resetting), after brief exposure to a sustained elevation of pressure (acute resetting), and after chronic elevation of pressure or in physiologic or pathologic states associated with structural changes in the vascular regions of baroreceptors (chronic resetting). The mechanisms reviewed here include mechanical, ionic and chemical factors. Viscoelastic properties of the carotid sinus and aortic arch may explain the instantaneous resetting that occurs with each cardiac cycle when activity begins in early systole and stops in early diastole. Viscoelastic properties and ionic mechanisms may play a role in acute resetting. Inhibition of Na+K+ ATPase reduces the magnitude of acute resetting. The release of chemicals from the endothelium may modulate baroreceptor activity. Exogenous prostacyclin suppresses and indomethacin augments acute resetting in the rabbit, suggesting that the release of endogenous prostacyclin during a rise in arterial pressure attenuates resetting. Changes in pulsatility and blood flow also may modulate baroreceptor activity. The addition of pulsatile pressure at an increased mean pressure attenuates resetting.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of 60-minute head-down tilt on arterial baroreflex function in anesthetized dogs

Arterial baroreflex control of heart rate was assessed in 6 anesthetized dogs with a bolus infusion of phenylephrine before and during cardiopulmonary receptor stimulation by 6 degrees head-down tilt (HDT) for 60 min. No difference in arterial baroreflex function was observed between the control and HDT conditions. It appears that the attenuation of baroreflex function that occurs during acute stimulation of cardiopulmonary baroreceptors disappears when cardiopulmonary baroreceptors reset after prolonged stimulation.

Atrial receptors, vasopressin and blood volume in the dog

Recent work has clarified the relationship between stimulation of left atrial receptors and plasma vasopressin concentration (pAVP) and has allowed a rational explanation of a number of previously anomalous findings. There is now good evidence that mitral obstruction causes a decrease in pAVP and that the decreases in pAVP can occur within a normal range of pAVP in anaesthetized and unanaesthetized animals. A stimulus which is localised to the left atrial receptors also causes a decrease in pAVP and it is likely that this is due to stimulation of the complex unencapsulated endings in the atrium, with myelinated afferent fibres. Evidence is lacking that changes in the stimulus to ventricular receptors or to cardio-pulmonary receptors with C-fibre afferents influences pAVP. The diuretic response to left atrial distension is two-fold, an increase in free water clearance and a natriuresis. The increase in free water clearance is due to the decrease in pAVP; the cause of the natriuresis is unknown. The changes in pAVP occur rapidly in response to atrial distension (within 5 min). The stimulus provided to atrial receptors by atrial distension and the decrease in pAVP is maintained for at least 90 min. pAVP is also modulated in response to small changes in blood volume (+/- 10%). The changes in pAVP that occur over this range of blood volume are likely to be in the range of 1-10 pg/ml and to have their effects on renal water excretion rather than on vascular resistance. The much larger changes in pAVP which occur with greater degrees of blood loss, and which can affect vascular resistance are likely to be produced by changes in the stimulus to other receptors, but a low input from atrial receptors may be permissive for these stimuli to be effective. More work is needed to clarify the relationship between inputs from different receptor types.