Aortic baroreceptor discharge during nonhypotensive hemorrhage in anesthetized dogs

Hakumäki, M. O. K.; Wang, B. C.; Sundet, W. D.; Goetz, K. L.

doi:10.1152/ajpheart.1985.249.2.h393

Cited by 19 publications

(17 citation statements)

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“…Heart rate was not altered, despite the overall sympathetic activation. This profile has not always been observed after blood donation or a mild drop in blood volume [2,[17][18][19][20]. Our results also contrast with those observed after a plasmaphoresis [21].…”

Section: Discussioncontrasting

confidence: 99%

“…A mild drop in blood volume is usually considered to be a specific stimulus of low pressure cardiopulmonary baroreceptors [4]. However, non-hypotensive haemorrhage decreases the activity of aortic baroreceptors, regardless of whether there is a decrease in the mean aortic pressure [19]. Our protocol with its mild drop in blood volume and increased systolic and mean blood pressures probably did not involve arterial baroreceptors.…”

Section: Discussionmentioning

confidence: 86%

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Human cardiovascular variability, baroreflex and hormonal adaptations to a blood donation

Fortrat

Nasr²,

Duvareille

et al. 1998

Clinical Science

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1. We studied cardiovascular variability, baroreflex and blood volume regulating hormones to determine the relative roles of autonomic regulation and hormones during blood donation.2. The sympathetic response was studied by measuring the R-R interval and systolic blood pressure variability using coarse graining spectral analysis in eight blood donors. Beat-by-beat R-R intervals and blood pressure were recorded for 20 min before and 5 min after a whole-blood donation of 480+/-10 ml (about 7 ml/kg of blood volume, over 4 min). Plasma catecholamines, vasopressin, atrial natriuretic peptide, endothelin, active renin, osmolality, Na+, K+, haemoglobin and haematocrit were measured just before and after blood withdrawal.3. Blood donation led to increases in the plasma catecholamines (adrenaline, 21+/-2 versus 35+/-3 pg/ml; noradrenaline, 229+/-26 versus 323+/-37 pg/ml; dopamine, 34+/-3 versus 66+/-9 pg/ml) and in systolic blood pressure (130+/-6 versus 140+/-5 mmHg). These changes were independent of ionic or slow endocrine mechanisms. Heart rate, cardiovascular variability and the spontaneous baroreflex sensitivity did not change despite the increase in blood pressure and catecholamines. Thus the peripheral vascular control was probably involved.4. We conclude that the absence of any change in heart rate usually observed during non-hypotensive hypovolaemic stress is probably due to the sympathetic activation being counterbalanced by the high supine vagal tone at the heart and not to the heterogeneous nature of the sympathetic neural response or to changes in sympathetic and parasympathetic activity without any change in autonomic balance.

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Section: Discussioncontrasting

confidence: 99%

Section: Discussionmentioning

confidence: 86%

Human cardiovascular variability, baroreflex and hormonal adaptations to a blood donation

Fortrat

Nasr²,

Duvareille

et al. 1998

Clinical Science

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“…To introduce the fast vagal effects seen in tilt back, vagal efference is pulsatile, allowing a possible large effect within the same beat. Our baroreflex model is not only sensitive to the pressure level but also to P pulse (18). Sympathetic activity occurs in the diastolic silence of the baroreceptors (7,56).…”

Section: Reflex Modelmentioning

confidence: 99%

“…Only when Ppulse was taken into account could the increase in HR be related to the decreased input (1). The role of changes in Ppulse in the baroreflex has been reported previously (18,48). The input to our baroreflex model is a combination of the systolic pressure and the integral of the pressure at the level of the receptors over the time of opening of the aortic valve (Eq.…”

Section: Reflex Modelmentioning

confidence: 99%

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Mathematical modeling of gravitational effects on the circulation: importance of the time course of venous pooling and blood volume changes in the lungs

Heusden

Gisolf

Stok

et al. 2006

American Journal of Physiology-Heart and Circulatory Physiology

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A dip in blood pressure (BP) in response to head-up tilt (HUT) or active standing might be due to rapid pooling in the veins below the heart (preload) or muscle activation-induced drop in systemic vascular resistance (afterload). We hypothesized that, in the cardiovascular response to passive HUT, where, in contrast to active standing, little BP dip is observed, features affecting the preload play a key role. We developed a baroreflex model combined with a lumped-parameter model of the circulation, including viscoelastic stress-relaxation of the systemic veins. Cardiac contraction is modeled using the varying-elastance concept. Gravity affects not only the systemic, but also the pulmonary, circulation. In accordance with the experimental results, model simulations do not show a BP dip on HUT; the tilt-back response is also realistic. If it is assumed that venous capacities are steady-state values, the introduction of stress-relaxation initially reduces venous pooling. The resulting time course of venous pooling is comparable to measured impedance changes. When venous pressure-volume dynamics are neglected, rapid (completed within 30 s) venous pooling leads to a drop in BP. The direct effect of gravity on the pulmonary circulation influences the BP response in the first ϳ5 s after HUT and tilt back. In conclusion, the initial BP response to HUT is mainly determined by the response of the venous system. The time course of lower body pooling is essential in understanding the response to passive HUT. baroreflex; cardiovascular system; modeling; tilt table A MODELING APPROACH to the study of the blood circulation and its response to postural changes can provide insight into the underlying physiology. Existing models approximate certain aspects of the circulation and its response to orthostatic stress, but the transients seen on passive head-up tilt (HUT) have proven difficult to capture.Transient response of the cardiovascular system to active standing and passive HUT has been the focus of various studies (3,34,45,47,51,59). The steady-state response to active standing and HUT is usually comparable, but there is a difference in the blood pressure (BP) and heart rate (HR) responses in the first 30 s (Fig. 1). On passive HUT, Rossberg and Martinez (34) found initial increases in HR comparable to the response to active standing. In later studies, however, a BP dip on active standing was reduced (3, 47) or absent (45,51,59) in passive HUT responses. The initial BP dip on standing is thought to be due to a decrease in peripheral resistance resulting from the active part of the maneuver (45). Sprangers et al. (45) point out two mechanisms: 1) the central (autonomic) command that accompanies active muscle contraction and 2) the displacement of large amounts of venous blood to the right atrium by the massive muscle action induced by active standing, eliciting a cardiopulmonary (CP) reflex effect on the systemic circulation. In passive tilt, if abrupt muscle contraction in response to sudden tilt maneuvers is avoided, perip...

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Spatially and temporally differentiated patterns ofc‐fosexpression in brainstem catecholamilriergic cell groups induced by cardiovascular challenges in the rat

Chan

Sawchenko

1994

J of Comparative Neurology

292

223

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Brainstem catecholaminergic neurons have been implicated as mediating adaptive autonomic and neuroendocrine responses to cardiovascular challenges. To clarify the nature of this involvement, immuno- and hybridization histochemical methods were used to follow c-fos expression in these neurons in response to acute stimuli that differentially affect blood pressure and volume. From low basal levels, hypotensive hemorrhage (15%) provoked a progressive increase in the number and distribution of Fos-immunoreactive (ir) nuclei in the nucleus of the solitary tract (NTS), the A1 and C1 cell groups of the ventrolateral medulla, and in the pontine A5, locus coeruleus, and lateral parabrachial cell groups peaking at 2.0-2.5 hours after the challenge. Fos-ir ventrolateral medullary neurons, subsets of which were identified as projecting to the paraventricular hypothalamic nucleus or spinal cord, were predominantly aminergic, whereas most of those in the NTS were not. Infusion of an angiotensin II antagonist blunted hemorrhage-induced Fos expression in the area postrema, and attenuated that seen elsewhere in the medulla and pons. Nitroprusside-induced isovolemic hypotension yielded a pattern of c-fos induction similar to that seen following hemorrhage, except in the area postrema and the A1 cell group, where the response was muted or lacking. Phenylephrine-induced hypertension stimulated a restricted pattern of c-fos expression, largely limited to induced hypertension stimulated a restricted pattern of c-fos expression, largely limited to non-aminergic neurons, whose distribution in the NTS conformed to the termination patterns of primary baroreceptor afferents, and in the ventrolateral medulla overlapped in part with those of vagal cardiomotor and depressor neurons. These findings underscore the importance of brainstem catecholaminergic neurons in effecting integrated homeostatic responses to cardiovascular challenges and their ability to responding strategically to specific modalities of cardiovascular information. They also foster testable predictions as to effector neuron populations that might be recruited to respond to perturbations in individual circulatory parameters.

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Aortic baroreceptor discharge during nonhypotensive hemorrhage in anesthetized dogs

Cited by 19 publications

References 0 publications

Human cardiovascular variability, baroreflex and hormonal adaptations to a blood donation

Human cardiovascular variability, baroreflex and hormonal adaptations to a blood donation

Mathematical modeling of gravitational effects on the circulation: importance of the time course of venous pooling and blood volume changes in the lungs

Spatially and temporally differentiated patterns ofc‐fosexpression in brainstem catecholamilriergic cell groups induced by cardiovascular challenges in the rat

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