What sets the long-term level of sympathetic nerve activity: is there a role for arterial baroreceptors?

Malpas, Simon C.

doi:10.1152/ajpregu.00496.2003

Cited by 43 publications

(45 citation statements)

References 93 publications

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“…Because technical limitations have precluded an understanding of the role of baroreflexes in long-term control of sympathetic activity and arterial pressure, the present findings are particularly important because they present a perspective that is diametrically opposite from studies using SAD. Furthermore, they are consistent with emerging evidence that the natural activation of the baroreflex in hypertension has sustained effects on cardiovascular function by chronically inhibiting sympathetic activity (1,13,17,19).…”

Section: Perspectivessupporting

confidence: 87%

“…Both modifications were based on the arterial pressure and sympathetic responses to SAD, the most commonly used approach for studying the role of the baroreflex in long-term control of arterial pressure. The transient sympathetic activation and hypertension following SAD are often interpreted to indicate the unimportance of baroreflexes in long-term control of arterial pressure (4,13,17,19). In marked contrast, studies during 1 wk of electrical stimulation of the carotid sinus demonstrate a sustained effect of baroreflex activation to suppress sympathetic activity and arterial pressure.…”

Section: Protocol Modificationsmentioning

confidence: 99%

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Sustained suppression of sympathetic activity and arterial pressure during chronic activation of the carotid baroreflex

Lohmeier

Iliescu

Dwyer

et al. 2010

American Journal of Physiology-Heart and Circulatory Physiology

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Lohmeier TE, Iliescu R, Dwyer TM, Irwin ED, Cates AW, Rossing MA. Sustained suppression of sympathetic activity and arterial pressure during chronic activation of the carotid baroreflex. Am J Physiol Heart Circ Physiol 299: H402-H409, 2010. First published May 28, 2010; doi:10.1152/ajpheart.00372.2010.-Following sinoaortic denervation, which eliminates arterial baroreceptor input into the brain, there are slowly developing adaptations that abolish initial sympathetic activation and hypertension. In comparison, electrical stimulation of the carotid sinus for 1 wk produces sustained reductions in sympathetic activity and arterial pressure. However, whether compensations occur subsequently to diminish these responses is unclear. Therefore, we determined whether there are important central and/or peripheral adaptations that diminish the sympathoinhibitory and blood pressure-lowering effects of more sustained carotid sinus stimulation. To this end, we measured whole body plasma norepinephrine spillover and ␣ 1-adrenergic vascular reactivity in six dogs over a 3-wk period of baroreflex activation. During the first week of baroreflex activation, there was an ϳ45% decrease in plasma norepinephrine spillover, along with reductions in mean arterial pressure and heart rate of ϳ20 mmHg and 15 beats/min, respectively; additionally, plasma renin activity did not increase. Most importantly, these responses during week 1 were largely sustained throughout the 3 wk of baroreflex activation. Acute pressor responses to ␣-adrenergic stimulation during ganglionic blockade were similar throughout the study, indicating no compensatory increases in adrenergic vascular reactivity. These findings indicate that the sympathoinhibition and lowering of blood pressure and heart rate induced by chronic activation of the carotid baroreflex are not diminished by adaptations in the brain and peripheral circulation. Furthermore, by providing evidence that baroreflexes have long-term effects on sympathetic activity and arterial pressure, they present a perspective that is opposite from studies of sinoaortic denervation. blood pressure; sympathetic nervous system; renin-angiotensin system THE RECENT DEVELOPMENT OF technology allowing chronic electrical stimulation of the carotid sinus has provided greater insight into the mechanisms that mediate the chronic blood pressure-lowering effects of baroreflex activation. Experimental studies using chronic stimulation of the carotid sinus have demonstrated that prolonged baroreflex activation (PBA) produces sustained and controllable reductions in mean arterial pressure (MAP), concomitant with suppression of plasma norepinephrine (NE) concentration (12, 14 -16, 18). Thus these studies suggest that sustained activation of the baroreflex has the capacity to produce substantial long-term reductions in MAP by inhibiting centrally generated sympathetic outflow.One limitation of these initial findings studies of PBA is their relatively short duration, lasting only 1 wk. The potential significance of this limitatio...

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Section: Perspectivessupporting

confidence: 87%

Section: Protocol Modificationsmentioning

confidence: 99%

Sustained suppression of sympathetic activity and arterial pressure during chronic activation of the carotid baroreflex

Lohmeier

Iliescu

Dwyer

et al. 2010

American Journal of Physiology-Heart and Circulatory Physiology

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“…In this regard, there has been a long-standing controversy as to whether baroreflexes play a role in the pathogenesis of hypertension. 9,13,14 This controversy stems from the paucity of techniques available to assess the long-term effects of the baroreflex on sympathetic activity, organ function, and arterial pressure. Solid arguments have been advanced to discount the role of baroreflexes in long-term control of sympathetic activity and arterial pressure.…”

mentioning

confidence: 99%

Influence of Prolonged Baroreflex Activation on Arterial Pressure in Angiotensin Hypertension

et al. 2005

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Abstract-Despite recent evidence indicating sustained activation of the baroreflex during chronic infusion of angiotensin II (Ang II), sinoaortic denervation does not exacerbate the severity of the hypertension. Therefore, to determine whether Ang II hypertension is relatively resistant to the blood pressure-lowering effects of the baroreflex, the carotid baroreflex was electrically activated bilaterally for 7 days in 5 dogs both in the presence and absence of a continuous infusion of Ang II (5 ng/kg per minute) producing high physiological plasma levels of the peptide. Under control conditions, basal values for mean arterial pressure (MAP) and plasma norepinephrine concentration (NE) were 93Ϯ1 mm Hg and 99Ϯ25 pg/mL, respectively. By day 7 of baroreflex activation, MAP and NE were reduced to 72Ϯ4 mm Hg (Ϫ21Ϯ3 mm Hg) and 56Ϯ15 pg/mL, respectively, but PRA was unchanged (controlϭ0.41Ϯ0.06 ng ANG I/mL per hour). All values returned to basal levels by the end of a 7-day recovery period. After 7 days of Ang II infusion, MAP increased from 93Ϯ3 to 129Ϯ3 mm Hg, whereas NE fell from 117Ϯ15 to 86Ϯ23 pg/mL. During the next 7 days of baroreflex activation/Ang II infusion, further reductions in NE were not statistically significant, and on the final day of baroreflex activation, the reduction in MAP was only 5Ϯ1 mm Hg, compared with 21Ϯ3 mm Hg in the control normotensive state.

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“…We propose that these be used as the standard equations for calculating threshold and saturation values when a logistic sigmoid function is used to model the open-loop baroreflex function curve. mathematical modeling; input-output relationship; baroreflex operating range; regression analysis THE BARORECEPTOR REFLEX is the major feedback control system regulating arterial blood pressure in the short term (5,14), and possibly also in the longer term (15,27). Numerous studies in humans and animals have demonstrated that the baroreceptor reflex can be reset under physiological conditions such as exercise (6 -8, 12, 17, 19 -24, 26, 28), sleep (18), heat stress (3), or pregnancy (4) and also pathological conditions such as hypertension (9,11) and cardiovascular deconditioning (10).…”

mentioning

confidence: 99%

Calculation of threshold and saturation points of sigmoidal baroreflex function curves

McDowall¹,

Dampney²

2006

American Journal of Physiology-Heart and Circulatory Physiology

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McDowall, Lachlan M., and Roger A. L. Dampney. Calculation of threshold and saturation points of sigmoidal baroreflex function curves. Am J Physiol Heart Circ Physiol 291: H2003-H2007, 2006. First published May 19, 2006 doi:10.1152/ajpheart.00219.2006The logistic sigmoid function curve provides an accurate description of the baroreflex input-output relationship and is the most commonly used equation for this purpose. The threshold (Thr) and saturation (Sat) values for the baroreflex are commonly defined as the values of mean arterial pressure (MAP) at which the reflexly controlled variable (e.g., heart rate or sympathetic nerve activity) is within 5% of the upper or lower plateau, respectively, of the sigmoid function. These values are referred to here as Thr 5% and Sat5%. In many studies, Thr and Sat are calculated with the equations Thr ϭ A3 Ϫ 2.0/A2 and Sat ϭ A3 ϩ 2.0/A2, where A3 is the value of MAP at the point where the reflexly controlled variable is at the midpoint of its range and A2 is the gain coefficient. Although it is commonly stated that the values of Thr and Sat calculated with these equations represent Thr 5% and Sat5%, we show here that instead they are significantly greater and less than Thr5% and Sat5%, respectively. Furthermore, the operating range (difference between Thr and Sat) calculated with these equations is 32% less than the difference between Thr5% and Sat5%. We further show that the equations that provide correct values of Thr5% and Sat5% are Thr5% ϭ A3 Ϫ 2.944/A2 and Sat5% ϭ A3 ϩ 2.944/A2. We propose that these be used as the standard equations for calculating threshold and saturation values when a logistic sigmoid function is used to model the open-loop baroreflex function curve. mathematical modeling; input-output relationship; baroreflex operating range; regression analysis THE BARORECEPTOR REFLEX is the major feedback control system regulating arterial blood pressure in the short term (5, 14), and possibly also in the longer term (15,27). Numerous studies in humans and animals have demonstrated that the baroreceptor reflex can be reset under physiological conditions such as exercise (6 -8, 12, 17, 19 -24, 26, 28), sleep (18), heat stress (3), or pregnancy (4) and also pathological conditions such as hypertension (9, 11) and cardiovascular deconditioning (10). To quantify the changes in baroreflex function that occur under different conditions, many investigators have used a mathematical equation to describe the relationship between input [e.g., mean arterial pressure (MAP)] and output (e.g., heart rate or sympathetic nerve activity). In some cases, where the carotid sinus pressure can be controlled independently of systemic arterial pressure, the input is carotid sinus pressure and the output is systemic arterial pressure.Kent et al. (13) first proposed that a logistic sigmoid function curve be used to describe baroreflex function, according to the following equation:where Y is the output (dependent) variable (e.g., heart rate, sympathetic nerve activity, or systemic arterial...

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What sets the long-term level of sympathetic nerve activity: is there a role for arterial baroreceptors?

Cited by 43 publications

References 93 publications

Sustained suppression of sympathetic activity and arterial pressure during chronic activation of the carotid baroreflex

Sustained suppression of sympathetic activity and arterial pressure during chronic activation of the carotid baroreflex

Influence of Prolonged Baroreflex Activation on Arterial Pressure in Angiotensin Hypertension

Calculation of threshold and saturation points of sigmoidal baroreflex function curves

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