Skin sympathetic outflow during head-down neck flexion in humans

1997 ◽  
Vol 273 (3) ◽  
pp. R1142-R1146 ◽  
Author(s):  
C. A. Ray ◽  
K. M. Hume ◽  
T. L. Shortt
Keyword(s):  
Heart Rate ◽  
Blood Flow ◽  
Arterial Pressure ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Sympathetic Outflow ◽  
Neck Flexion ◽  
Nerve Activity ◽  
Calf Blood Flow

We have previously demonstrated increases in muscle sympathetic nerve activity during head-down neck flexion (HDNF). The purpose of the present study was to determine if HDNF also activates skin sympathetic nerve activity (SSNA). SSNA, heart rate, arterial pressure, skin blood flow, calf blood flow, and calculated calf vascular resistance (mean arterial pressure/calf blood flow) were determined in 12 subjects during 3 min of baseline (lying prone with chin supported) and 3 min of HDNF. There were no significant changes in heart rate and arterial pressures during HDNF; however, diastolic and mean arterial pressure tended to increase slightly. Calf blood flow decreased 22% and calf vascular resistance increased 46% during HDNF. SSNA did not significantly change during HDNF. In three subjects we measured both muscle and skin sympathetic nerve activity during HDNF. In these trials, muscle sympathetic nerve activity consistently increased, but SSNA did not. The results indicate that HDNF in humans activates muscle sympathetic nerve activity, but does not activate SSNA. Thus vestibular stimulation may elicit differential activation of sympathetic outflow in humans.

Spectral analysis of heart rate, arterial pressure, and muscle sympathetic nerve activity in normal humans

1998 ◽  
Vol 274 (4) ◽  
pp. H1211-H1217 ◽  
Author(s):  
Akio Nakata ◽  
Shigeo Takata ◽  
Toyoshi Yuasa ◽  
Atsuhiro Shimakura ◽  
Michiro Maruyama ◽  
...  
Keyword(s):  
Heart Rate ◽  
Spectral Analysis ◽  
Arterial Pressure ◽  
Sympathetic Nerve ◽  
Autoregressive Model ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Model Fitting ◽  
Power Spectral Analysis ◽  
Nerve Activity

We investigated the frequency components of fluctuations in heart rate, arterial pressure, respiration, and muscle sympathetic nerve activity (MSNA) in 11 healthy women using an autoregressive model and examined the relation among variables using Akaike’s relative power contribution analysis with multivariate autoregressive model fitting. Power spectral analysis of MSNA revealed two peaks, with low-frequency (LF) and high-frequency (HF) components. The LF component of MSNA was a major determinant of the LF component of arterial pressure and R-R interval variability (0.70 ± 0.07 and 0.18 ± 0.05, respectively). The effect of the LF component of MSNA on arterial pressure showed no change in response to propranolol but was diminished (0.35 ± 0.08) by phentolamine ( P < 0.02). The effect of the LF component of MSNA on R-R interval was not altered by pharmacological sympathetic nerve blockade. The HF component of MSNA did not influence other variables but was influenced by R-R interval, arterial pressure, and respiration. These findings indicate that the LF component of MSNA reflects autonomic oscillations, whereas the HF component is passive and influenced by other cardiovascular variables.

Effects of intravenous infusions of angiotensin II on muscle sympathetic nerve activity in humans

1991 ◽  
Vol 261 (3) ◽  
pp. R690-R696 ◽  
Author(s):  
T. Matsukawa ◽  
E. Gotoh ◽  
K. Minamisawa ◽  
M. Kihara ◽  
S. Ueda ◽  
...  
Keyword(s):  
Angiotensin Ii ◽  
Mean Arterial Pressure ◽  
Arterial Pressure ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Sympathetic Outflow ◽  
Ang Ii ◽  
Nerve Activity ◽  
Intravenous Infusions

The effect of angiotensin II (ANG II) on the sympathetic outflow was examined in normal humans. The mean arterial pressure and muscle sympathetic nerve activity (MSNA) were measured before and during intravenous infusions of phenylephrine (0.5 and 1.0 micrograms.kg-1.min-1) or ANG II (5, 10, and 20 ng.kg-1.min-1) for 15 min at 30-min intervals. The baroreflex slope for the relationship between the increases in mean arterial pressure and the reductions in MSNA was significantly less acute during the infusions of ANG II than during the infusions of phenylephrine. When nitroprusside was infused simultaneously to maintain central venous pressure at the basal level, MSNA significantly increased during the infusions of ANG II (5 ng.kg-1.min-1 for 15 min) but not during the infusions of phenylephrine (1.0 micrograms.kg-1.min-1 for 15 min), with accompanying attenuation of the elevation in arterial pressure induced by these pressor agents. These findings suggest that ANG II stimulates the sympathetic outflow without mediating baroreceptor reflexes in humans.

Isometric handgrip training reduces arterial pressure at rest without changes in sympathetic nerve activity

2000 ◽  
Vol 279 (1) ◽  
pp. H245-H249 ◽  
Author(s):  
Chester A. Ray ◽  
Dario I. Carrasco
Keyword(s):  
Heart Rate ◽  
Arterial Pressure ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Cardiovascular Responses ◽  
Voluntary Contraction ◽  
Isometric Handgrip ◽  
Nerve Activity ◽  
Muscle Ischemia

The purpose of this study was to determine whether isometric handgrip (IHG) training reduces arterial pressure and whether reductions in muscle sympathetic nerve activity (MSNA) mediate this drop in arterial pressure. Normotensive subjects were assigned to training ( n = 9), sham training ( n = 7), or control ( n = 8) groups. The training protocol consisted of four 3-min bouts of IHG exercise at 30% of maximal voluntary contraction (MVC) separated by 5-min rest periods. Training was performed four times per week for 5 wk. Subjects' resting arterial pressure and heart rate were measured three times on 3 consecutive days before and after training, with resting MSNA (peroneal nerve) recorded on the third day. Additionally, subjects performed IHG exercise at 30% of MVC to fatigue followed by muscle ischemia. In the trained group, resting diastolic (67 ± 1 to 62 ± 1 mmHg) and mean arterial pressure (86 ± 1 to 82 ± 1 mmHg) significantly decreased, whereas systolic arterial pressure (116 ± 3 to 113 ± 2 mmHg), heart rate (67 ± 4 to 66 ± 4 beats/min), and MSNA (14 ± 2 to 15 ± 2 bursts/min) did not significantly change following training. MSNA and cardiovascular responses to exercise and postexercise muscle ischemia were unchanged by training. There were no significant changes in any variables for the sham training and control groups. The results indicate that IHG training is an effective nonpharmacological intervention in lowering arterial pressure.

Assessing static and dynamic sympathetic transduction using microneurography

2021 ◽  
Author(s):  
Michael M. Tymko ◽  
Lindsey F. Berthelsen ◽  
Rachel J. Skow ◽  
Andrew R. Steele ◽  
Graham M. Fraser ◽  
...  
Keyword(s):  
Blood Pressure ◽  
Heart Rate ◽  
Blood Flow ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Peripheral Resistance ◽  
Analytical Techniques ◽  
Nerve Activity ◽  
Physiological Outcomes

The relationship between sympathetic nerve activity and the vasculature has been of great interest due to its potential role in various cardiovascular-related disease. This relationship, termed "sympathetic transduction", has been quantified using several different laboratory and analytical techniques. The most common method is to assess the association between relative changes in muscle sympathetic nerve activity, measured via microneurography, and physiological outcomes (e.g., blood pressure, total peripheral resistance, and blood flow etc.) in response to a sympathetic stressor (e.g. exercise, cold stress, orthostatic stress). This approach, however, comes with its own caveats. For instance, elevations in blood pressure and heart rate during a sympathetic stressor can have an independent impact on muscle sympathetic nerve activity. Another assessment of sympathetic transduction was developed by Wallin and Nerhed in 1982, where alterations in blood pressure and heart rate were assessed immediately following bursts of muscle sympathetic nerve activity at rest. This approach has since been characterized and further innovated by others, including the breakdown of consecutive burst sequences (e.g., singlet, doublet, triplet, and quadruplet), and burst height (quartile analysis) on specific vascular outcomes (e.g., blood pressure, blood flow, vascular resistance). The purpose of this review is to provide an overview of the literature that has assessed sympathetic transduction using microneurography and various sympathetic stressors (static sympathetic transduction) and using the same or similar approach established by Wallin and Nerhed at rest (dynamic neurovascular transduction). Herein, we discuss the overlapping literature between these two methodologies and highlight the key physiological questions that remain.

Increase in sympathetic outflow by paraventricular nucleus stimulation in awake rats

1989 ◽  
Vol 256 (6) ◽  
pp. R1325-R1330 ◽  
Author(s):  
H. Kannan ◽  
Y. Hayashida ◽  
H. Yamashita
Keyword(s):  
Heart Rate ◽  
Arterial Pressure ◽  
Paraventricular Nucleus ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Sympathetic Outflow ◽  
Nerve Activity ◽  
Renal Sympathetic Nerve Activity ◽  
Renal Sympathetic Nerve ◽  
Renal Sympathetic

Our previous studies demonstrated that stimulation of the hypothalamic paraventricular nucleus (PVN) in anesthetized rats evoked a depressor response accompanied with a decrease in sympathetic outflow (H. Kannan, A. Niijima, and H. Yamashita, J. Auton. Nerv. Syst. 19: 83-86, 1987; H. Yamashita, H. Kannan, M. Kasai, and T. Osaka, J. Auton. Nerv. Syst. 19: 229-234, 1987). Because anesthesia may alter cardiovascular responses, we examined in conscious rats the effects of PVN stimulation on arterial pressure, heart rate, and renal sympathetic nerve activity. Electrical stimulation through chronically implanted electrodes evoked increases in arterial pressure and renal sympathetic nerve activity with a slight decrease in heart rate. The magnitude of responses was dependent on the frequency and the intensity of the stimulus. Latency of the excitatory response of the renal sympathetic nerve activity was approximately 70 ms. Microinjection of L-glutamate (0.5 M, 200 nl) into the PVN area also elicited increases in blood pressure and renal sympathetic nerve activity. These results suggest that activation of PVN neurons in conscious rats produces pressor responses due to an increase in the sympathetic outflow. These findings contrast with those obtained previously in anesthetized rats.

scholarly journals Respiratory influences on muscle sympathetic nerve activity and vascular conductance in the steady state

2013 ◽  
Vol 304 (12) ◽  
pp. H1615-H1623 ◽  
Author(s):  
Jacqueline K. Limberg ◽  
Barbara J. Morgan ◽  
William G. Schrage ◽  
Jerome A. Dempsey
Keyword(s):  
Blood Pressure ◽  
Blood Flow ◽  
Steady State ◽  
Arterial Pressure ◽  
Sympathetic Nerve ◽  
Sympathetic Activity ◽  
Sympathetic Nerve Activity ◽  
Muscle Sympathetic Nerve Activity ◽  
Vascular Conductance ◽  
Nerve Activity

In patients with hypertension, volitional slowing of the respiratory rate has been purported to reduce arterial pressure via withdrawal of sympathetic tone. We examined the effects of paced breathing at 7, 14, and 21 breaths/min, with reciprocal changes in tidal volume, on muscle sympathetic nerve activity, forearm blood flow, forearm vascular conductance, and blood pressure in 21 men and women, 8 of whom had modest elevations in systemic arterial pressure. These alterations in breathing frequency and volume did not affect steady-state levels of sympathetic activity, blood flow, vascular conductance, or blood pressure (all P > 0.05), even though they had the expected effect on sympathetic activity within breaths (i.e., increased modulation during low-frequency/high-tidal volume breathing) ( P < 0.001). These findings were consistent across subjects with widely varied baseline levels of sympathetic activity (4-fold), mean arterial pressure (78–110 mmHg), and vascular conductance (15-fold), and those who became hypocapnic during paced breathing vs. those who maintained normocapnia. These findings challenge the notion that slow, deep breathing lowers arterial pressure by suppressing steady-state sympathetic outflow.

scholarly journals Disruption of phase synchronization between blood pressure and muscle sympathetic nerve activity in postural vasovagal syncope

2013 ◽  
Vol 305 (8) ◽  
pp. H1238-H1245 ◽  
Author(s):  
Christopher E. Schwartz ◽  
Elisabeth Lambert ◽  
Marvin S. Medow ◽  
Julian M. Stewart
Keyword(s):  
Blood Pressure ◽  
Heart Rate ◽  
Sympathetic Nerve ◽  
Sympathetic Nerve Activity ◽  
Phase Synchronization ◽  
Vasovagal Syncope ◽  
Muscle Sympathetic Nerve Activity ◽  
Nerve Activity ◽  
Control Subjects ◽  
Late Stages

Withdrawal of muscle sympathetic nerve activity (MSNA) may not be necessary for the precipitous fall of peripheral arterial resistance and arterial pressure (AP) during vasovagal syncope (VVS). We tested the hypothesis that the MSNA-AP baroreflex entrainment is disrupted before VVS regardless of MSNA withdrawal using the phase synchronization between blood pressure and MSNA during head-up tilt (HUT) to measure reflex coupling. We studied eight VVS subjects and eight healthy control subjects. Heart rate, AP, and MSNA were measured during supine baseline and at early, mid, late, and syncope stages of HUT. Phase synchronization indexes, measuring time-dependent differences between MSNA and AP phases, were computed. Directionality indexes, indicating the influence of AP on MSNA (neural arc) and MSNA on AP (peripheral arc), were computed. Heart rate was greater in VVS compared with control subjects during early, mid, and late stages of HUT and significantly declined at syncope ( P = 0.04). AP significantly decreased during mid, late, and syncope stages of tilt in VVS subjects only ( P = 0.001). MSNA was not significantly different between groups during HUT ( P = 0.700). However, the phase synchronization index significantly decreased during mid and late stages in VVS subjects but not in control subjects ( P < .001). In addition, the neural arc was significantly affected more than the peripheral arc before syncope. In conclusion, VVS is accompanied by a loss of the synchronous AP-MSNA relationship with or without a loss in MSNA at faint. This provides insight into the mechanisms behind the loss of vasoconstriction and drop in AP independent of MSNA at the time of vasovagal faint.

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