Influence of ventilation and hypocapnia on sympathetic nerve responses to hypoxia in normal humans

Somers, Virend K.; Mark, Allyn L.; Zavala, Donald C.; Abboud, François M.

doi:10.1152/jappl.1989.67.5.2095

Cited by 324 publications

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“…Increased ventilation acts as a powerful restraint on the sympathetic response to chemoreflex stimulation. 14 Nevertheless, the increase in sympathetic activity in subjects with faster breathing rate was still comparable to that seen in subjects with slower breathing rate, despite the higher ventilation. Thus, potentiation of the chemoreflex response in subjects with faster breathing rates appears to affect both the ventilatory and sympathetic efferent limbs of the reflex.…”

Section: Narkiewicz Et Al Breathing Rate and Sympathetic Trafficmentioning

confidence: 83%

“…The protocol used to determine chemoreflex responses to isocapnic hypoxia and hyperoxic hypercapnia was identical to that used in previous studies. 14,15 Subjects were exposed to a hypoxic gas mixture to induce peripheral chemoreflex activation (10% oxygen in nitrogen with carbon dioxide titrated to maintain isocapnia) and a hypercapnic gas mixture to induce central chemoreflex activation (7% oxygen/93% carbon dioxide). During hypoxic stimulation of peripheral chemoreceptors, perturbation of central chemoreceptors was minimized by the maintenance of isocapnia.…”

Section: Protocol and Proceduresmentioning

confidence: 99%

“…[7][8][9][10] Several studies have shown that respiration contributes importantly to short-term modulation of sympathetic nerve traffic. [11][12][13][14][15] MSNA increases at end expiration and decreases to minimum levels at end inspiration. 11 Little is known about the contribution of spontaneous respiratory rate to baseline MSNA burst frequency.…”

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confidence: 95%

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Sympathetic Neural Outflow and Chemoreflex Sensitivity Are Related to Spontaneous Breathing Rate in Normal Men

et al. 2006

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Abstract-Respiration contributes importantly to short-term modulation of sympathetic nerve activity. However, the relationship between spontaneous breathing rate, chemoreflex function, and direct measures of sympathetic traffic in healthy humans has not been studied previously. We tested the hypothesis that muscle sympathetic nerve activity and chemoreflex sensitivity are linked independently to respiratory rate in normal subjects. We studied 69 normal male subjects aged 29.6Ϯ8.1 years. Subjects were subdivided according to the tertiles of respiratory rate distributions. Mean respiration rate was 10.6 breaths/min in the first tertile, 14.8 breaths/min in the second tertile, and 18.0 breaths/min in the third tertile. Subjects from the third tertile (faster respiratory rate) had greater sympathetic activity than subjects from the first tertile (slower respiratory rate; 29Ϯ3 versus 17Ϯ2 bursts/min; PϽ0.001).Stepwise multiple linear regression analysis revealed that only respiratory rate was linked independently to sympathetic activity (rϭ0.42; PϽ0.001). In comparison to subjects with slow respiratory rate, subjects with fast respiratory rate had greater increases in minute ventilation during both hypercapnia (7.3Ϯ0.8 versus 3.2Ϯ1.0 L/min; Pϭ0.005) and hypoxia (5.7Ϯ0.8 versus 2.4Ϯ0.7 L/min; Pϭ0.007). Muscle sympathetic nerve activity and chemoreflex sensitivity are linked to spontaneous respiratory rate in normal humans. Faster respiratory rate is associated with higher levels of sympathetic traffic and potentiated responses to hypoxia and hypercapnia. Spontaneous breathing frequency, central sympathetic outflow, and chemoreflex sensitivity exhibit significant and hitherto unrecognized interactions in the modulation of neural circulatory control. Key Words: autonomic nervous system Ⅲ sympathetic nervous system Ⅲ blood pressure Ⅲ heart rate T he sympathetic nervous system plays a central role in cardiovascular regulation in both health and disease. Sympathetic activation has been implicated in the pathogenesis of hypertension, obstructive sleep apnea, and congestive heart failure. [1][2][3][4] In healthy humans, muscle sympathetic nervous activity (MSNA) varies widely across subjects but is relatively reproducible within the same individual. 5,6 The substantial between-subject variance in sympathetic traffic can be only partially explained by age, body mass index, blood pressure, reflex mechanisms, and genetic factors. [7][8][9][10] Several studies have shown that respiration contributes importantly to short-term modulation of sympathetic nerve traffic. 11-15 MSNA increases at end expiration and decreases to minimum levels at end inspiration. 11 Little is known about the contribution of spontaneous respiratory rate to baseline MSNA burst frequency. It has been proposed that respiration affects timing but not tonic levels of sympathetic nervous activity. 12 However, in congestive heart failure, MSNA is related to spontaneous respiratory rate. Patients with rapid breathing, a pattern commonly observed in heart failure,...

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Section: Narkiewicz Et Al Breathing Rate and Sympathetic Trafficmentioning

confidence: 83%

Section: Protocol and Proceduresmentioning

confidence: 99%

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Sympathetic Neural Outflow and Chemoreflex Sensitivity Are Related to Spontaneous Breathing Rate in Normal Men

et al. 2006

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“…In fact, the augmented sympathetic drive occurs in the face of a potentiated ventilatory response that might be expected to attenuate the sympathetic response due to negative feedback from pulmonary afferents (Somers et al 1989). In addition, central input from the CB provides a tonic excitatory influence on sympathetic outflow in rabbits with established CHF since hyperoxia reduces resting sympathetic nerve activity in CHF but not sham animals (Sun et al 1999a), and selective CB denervation attenuates the elevated resting sympathetic nerve activity and plasma norepinephrine normally observed in CHF rabbits (Fig.…”

Section: Chemoreflex Control Of Sympathetic Function In Heart Failurementioning

confidence: 99%

Carotid body function in heart failure

Schultz

2007

Respiratory Physiology & Neurobiology

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In this review, we summarize the present state of knowledge of the functional characteristics of the carotid body (CB) chemoreflex with respect to control of sympathetic nerve activity (SNA) in chronic heart failure (CHF). Evidence from both CHF patients and animal models of CHF has clearly established that the CB chemoreflex is enhanced in CHF and contributes to the tonic elevation in SNA. This adaptive change derives from altered function at the level of both the afferent and central nervous system (CNS) pathways of the reflex arc. At the level of the CB, an elevation in basal afferent discharge occurs under normoxic conditions in CHF rabbits, and the discharge responsiveness to hypoxia is enhanced. Outward voltage-gated K + currents (I K ) are suppressed in CB glomus cells from CHF rabbits, and their sensitivity to hypoxic inhibition is enhanced. These changes in I K derive partly from downregulation of nitric oxide synthase (NOS) / NO signaling and upregulation of angiotensin II (Ang II) / Ang II receptor (AT 1 R) signaling in glomus cells. At the level of the CNS, interactions of the enhanced input from CB chemoreceptors with altered input from baroreceptor and cardiac afferent pathways and from central Ang II further enhance sympathetic drive. In addition, impaired function of NO in the paraventricular nucleus of the hypothalamus participates in the increased SNA response to CB chemoreceptor activation. These results underscore the principle that multiple mechanisms involving Ang II and NO at the level of both the CB and CNS represent complementary and perhaps redundant adaptive mechanisms to enhance CB chemoreflex function in CHF.

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“…In previous studies, changes in PWA were measured by photoplethysmography in relation to arousals induced by acoustical stimulus in healthy subjects [6,10]. In sleeprelated breathing disorders, blood gas disturbances and other factors potentially further modulate activation-related autonomic activity [16,17] and could modify this cardiovascular response. If reliable changes in PWA could be detected in relation to obstructive sleep respiratory events, the photoplethysmography could become an interesting screening method for detecting respiratory events and for assessing sleep fragmentation in obstructive sleep apnea patients.…”

Section: Introductionmentioning

confidence: 99%

Obstructive sleep apnea syndrome: effect of respiratory events and arousal on pulse wave amplitude measured by photoplethysmography in NREM sleep

et al. 2005

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Obstructive sleep apnea syndrome: effect of respiratory events and arousal on pulse wave amplitude measured by photoplethysmography in NREM sleep Abstract The objective of the study is to evaluate changes in finger pulse wave amplitude (PWA), as measured by photoplethysmography, and heart rate (HR), related to obstructive respiratory events and associated arousals during sleep. We analyzed 1,431 respiratory events in NREM sleep from 12 patients according to (1) the type of event (apnea, hypopnea, upper airway resistance episode) and (2) the duration of the associated EEG arousal (>10, 3-10, <3 s). Obstructive respiratory events provoked a relative bradycardia and vasodilation followed by HR increase and vasoconstriction. Relative PWA changes were significantly greater than HR changes. These responses differed significantly according to EEG-arousal grades (time×arousal interaction, p<0.0001), with longer arousals producing greater responses, but not to the type of respiratory event (time×event interaction, p = ns). Obstructive respiratory events provoke HR and PWA changes, the magnitude seemingly related to the intensity of central nervous activation, with PWA changes greater than HR. PWA obtained from a simple pulse oxymeter might be a valuable method to evaluate sleep fragmentation in sleep breathing disorders.

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Influence of ventilation and hypocapnia on sympathetic nerve responses to hypoxia in normal humans

Cited by 324 publications

References 0 publications

Sympathetic Neural Outflow and Chemoreflex Sensitivity Are Related to Spontaneous Breathing Rate in Normal Men

Sympathetic Neural Outflow and Chemoreflex Sensitivity Are Related to Spontaneous Breathing Rate in Normal Men

Carotid body function in heart failure

Obstructive sleep apnea syndrome: effect of respiratory events and arousal on pulse wave amplitude measured by photoplethysmography in NREM sleep

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