Muscle Sympathetic Nerve Activity In Humans Research Articles

Central alpha-2 adrenergic mechanisms affect human sympathetic neuronal discharge strategies

The central neural mechanisms affecting sympathetic neuronal discharge strategies supporting homeostatic adjustments in human muscle sympathetic nerve activity (MSNA) remain unclear. This study investigated the hypothesis that central alpha-2 adrenergic mechanisms affect sympathetic action potential (AP) discharge, recruitment, and latency patterns within human MSNA (peroneal nerve microneurography and continuous wavelet transform). An alpha-2 adrenergic agonist (dexmedetomidine) was infused in eight healthy male and female participants (5 females; 28 ± 7years). Data were recorded during a 5-minute resting control condition, a 10-minute intravenous dexmedetomidine loading dose (0.225 μg/kg), and a dexmedetomidine maintenance dose (~0.1 μg/kg/hr). Data are reported as mean (SD) for the 5-minute control condition and 2-minutes of the dexmedetomidine infusion when MSNA bursting activity was demonstrably reduced. Two-tailed paired t-tests were performed. Dexmedetomidine reduced mean pressure (92 ± 7 to 80 ± 8 mmHg; P < 0.01) but did not affect heart rate (61 ± 13 to 60 ± 14 bpm; P = 0.75). Dexmedetomidine reduced integrated MSNA burst frequency (14 ± 6 to 4 ± 3 bursts/min; P < 0.01), sympathetic AP frequency (75 ± 46 to 16 ± 14 AP/min; P < 0.01), APs per burst (5 ± 1 to 4 ± 1 AP/burst; P = 0.01), AP clusters per burst (3.5 ± 0.7 to 3.0 ± 0.7 clusters/burst; P = 0.03), and de-recruited the largest AP clusters (12 ± 3 to 7 ± 2 AP clusters; P < 0.01). Despite de-recruiting large AP clusters with short conduction times, dexmedetomidine elicited shorter sympathetic AP conduction times (1.18 ± 0.12 to 1.14 ± 0.13 s; P = 0.03). Six participants performed a Valsalva Maneuver (20 s, 40 mmHg mouth pressure) during the control condition and during the dexmedetomidine maintenance dose. Data are reported as mean (SD) change (Δ) from the 2-minute period preceding the Valsalva Maneuver to the Valsalva Maneuver for each condition. During the control condition, Valsalva Maneuver increased AP frequency (Δ 311 ± 317 AP/min; P = 0.048), recruited larger previously silent AP clusters (Δ 2 ± 1 AP clusters; P < 0.01), and elicited shorter AP conduction times (Δ ‑0.09 ± 0.07 s; P = 0.02). Compared to the control condition, Valsalva Maneuver performed during the dexmedetomidine maintenance dose condition elicited lesser increases in AP frequency (Δ 116 ± 189 AP/min; P vs. control = 0.02) and lesser recruitment of larger previously silent AP clusters (Δ 0 ± 1 AP clusters; P vs. control = 0.02). Dexmedetomidine did not affect the latency reduction elicited by Valsalva Maneuver (Δ ‑0.07 ± 0.14 s; P vs. control = 0.61). These data suggest that human central alpha-2 adrenergic mechanisms affect: i) sympathetic postganglionic neuronal discharge and recruitment patterns, and ii) synaptic delays within the sympathetic neurocircuitry influencing AP latency. This work was supported by the Natural Sciences and Engineering Research Council of Canada (NSERC) and the National Institutes of Health (NIH). This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Interactive effects of apneic and baroreflex stress on neuronal coding strategies in human muscle sympathetic nerve activity

The sympathetic nervous system exhibits patterns of action potential (AP) discharge in human muscle sympathetic nerve activity that suggest coding strategies express reflex specificity. This study explored the interactive effects of baroreceptor unloading using lower body negative pressure (LBNP) and volitional end-expiratory apnea (APN) on sympathetic postganglionic neuronal discharge patterns inferred from the firing patterns of differently sized sympathetic AP clusters. Seven individuals were studied using multiunit microneurography (fibular) and a continuous wavelet approach to quantify AP discharge probability, recruitment, and latency during APN performed under ambient conditions, -10, and -40 mmHg LBNP. Compared with the ambient condition, LBNP increased AP discharge rate at -10 and -40 mmHg and recruited larger previously silent sympathetic neurons at -40 mmHg. Compared with spontaneous breathing, APN increased AP discharge when performed during the ambient condition (Δ351 ± 132 AP/min), -10 mmHg (Δ423 ± 184 AP/min), and -40 mmHg (Δ355 ± 278 AP/min; main effect APN: P < 0.01; LBNP-by-APN interaction: P = 0.55). APN recruited larger previously silent AP clusters during the ambient condition (Δ4 ± 3; P < 0.02) and -10 mmHg (Δ4 ± 3; P < 0.01), but not -40 mmHg (Δ0 ± 2; P = 0.53; LBNP-by-APN: P < 0.01). LBNP did not affect AP latency. However, APN reduced AP latency similarly during all conditions (ambient pressure: Δ-0.04 ± 0.04s, -10 mmHg: Δ-0.03 ± 0.03s, -40 mmHg: Δ-0.03 ± 0.04s; main effect APN: P < 0.01; LBNP-by-APN: P = 0.48). These data indicate that apneic and baroreflex mechanisms appear to additively modify the axonal discharge rate of previously active sympathetic postganglionic neurons and interact to affect recruitment of previously silent sympathetic neurons. Reductions in AP latency due to apneic stress were not impacted by baroreflex unloading.NEW & NOTEWORTHY Discrete physiological stressors differentially affect sympathetic postganglionic neuronal rate-, population-, and temporal-coding strategies. When performing end-expiratory apnea (APN) during graded baroreflex unloading via lower body negative pressure (LBNP), we found: 1) augmented sympathetic axonal firing probability, 2) recruitment of larger and previously silent sympathetic postganglionic neurons at ambient and -10 mmHg, but not -40 mmHg LBNP, and 3) APN reduced axonal discharge latency similarly across all conditions, independent of the level of baroreflex unloading.

Action potential subpopulations within human muscle sympathetic nerve activity: Discharge properties and governing mechanisms.

Sympathetic emissions directed towards the skeletal muscle circulation - muscle sympathetic nerve activity (MSNA) - represent a key mechanism for maintaining homeostasis and supporting human survival during physiological stress. Pulse-rhythmic bursts formed by the synchronous discharge of differently-sized sympathetic action potentials (APs) represent the primary characteristic of MSNA. Of the APs firing under baseline conditions (reflecting low-threshold c-fibre activity), a range of subpopulations exists, of which three general categories can be discussed based on their peak-to-peak amplitude in the filtered raw neurogram - small, medium, and large. These subpopulations express nonuniform discharge, recruitment, and synchronization patterns. The subpopulation of medium APs fires synchronously in most bursts, while the subpopulations of small and large APs fire less often. However, 30% of total AP discharge occurs asynchronously between sympathetic bursts, a pattern expressed most often by small APs. In response to physiological stress (e.g., baroreflex unloading), the subpopulation of medium APs exhibits the largest increase in firing probability and a subpopulation of previously-silent larger and faster-conducting APs (reflecting high-threshold c-fibre activity) becomes recruited. Heterogeneous discharge, synchronization, and recruitment thresholds among AP subpopulations stem from differential regulation within the sympathetic organization including the arterial baroreflex and paravertebral ganglia. Indeed, the arterial baroreflex strongly regulates medium APs at baseline and enhances its control over this subpopulation during periods of baroreflex unloading. Conversely, small and large APs express weak baroreflex control. Trimethaphan infusion has revealed that ganglionic processes including nicotinic and non-nicotinic mechanisms may contribute to heterogenous firing behaviours among low-threshold AP subpopulations. This review highlights recent work revealing new insight to the discharge properties expressed by, and mechanisms governing, AP subpopulations within human MSNA.

Within-breath sympathetic baroreflex sensitivity is modulated by lung volume but unaffected by acute intermittent hypercapnic hypoxia in men.

Muscle sympathetic nerve activity (MSNA) exhibits well-described within-breath respiratory modulation, but the interactive contributions of the arterial baroreflex remain unclear. The present study assessed 1) within-breath modulation of sympathetic baroreflex sensitivity (BRS) and 2) the effect of acute intermittent hypercapnic hypoxia (IHH) on within-breath sympathetic BRS and respiratory-sympathetic entrainment. Seventeen men (24 ± 4 yr) underwent an 8- to 10-min spontaneously breathing baseline while continuous measures of blood pressure (BP), heart rate, MSNA, ventilation, and end-tidal gases were collected. A subset of 12 participants subsequently underwent a 40-min IHH exposure composed of 40 consecutive 1-min breathing cycles: 40 s of hypercapnic hypoxia and 20 s of normoxia. Data were compared between inspiration and expiration and low and high lung volume (calculated from the integral of spirometry-derived flow). Sympathetic BRS was determined by the slope of the weighted linear regression between diastolic BP and MSNA burst incidence. Respiratory-sympathetic entrainment was quantified as percentage of MSNA bursts during each respiratory epoch relative to the total burst count. Sympathetic BRS was similar between inspiration and expiration (-3.9 ± 2.0 vs. -3.6 ± 1.8 bursts·100 heartbeats-1·mmHg-1; P = 0.61) but greater during low versus high lung volumes (-4.6 ± 2.3 vs. -2.1 ± 1.6 bursts·100 heartbeats-1·mmHg-1; P < 0.01). High (r = -0.64; P < 0.01)- but not low (r = -0.24; P = 0.35)-lung volume sympathetic BRS was associated with resting MSNA. IHH increased resting MSNA burst frequency (15 ± 7 vs. 20 ± 7 bursts/min; P < 0.01) and diastolic BP (68 ± 5 vs. 77 ± 9 mmHg; P = 0.02), without altering resting or within-breath sympathetic BRS or respiratory-sympathetic entrainment (all P > 0.05). These findings provide novel insight into the mechanisms controlling within-breath modulation of sympathetic outflow in humans.NEW & NOTEWORTHY In resting spontaneously breathing men, the present study observed that sympathetic baroreflex sensitivity (BRS) was higher during low versus high lung volumes but not different between inspiration and expiration. High- but not low-lung volume BRS was negatively associated with resting muscle sympathetic nerve activity (MSNA). Acute intermittent hypercapnic hypoxia increased resting MSNA and diastolic blood pressure, without altering within-breath BRS. These findings provide novel insight into mechanisms controlling within-breath modulation of MSNA in humans.

Baroreflex Resetting of Sympathetic Action Potential Subpopulations During Fatiguing Isometric Handgrip and Post‐Exercise Circulatory Occlusion

The arterial baroreflex exerts heterogeneous control over the varying‐sized action potential (AP) subpopulations active within human muscle sympathetic nerve activity (MSNA) under baseline conditions. How baroreflex control of sympathetic AP discharge becomes reset to facilitate sympathoexcitation during physical exercise remains to be investigated. Therefore, we quantified the baroreflex gain for each sympathetic AP cluster (i.e., reflecting different c‐fibres) within the MSNA filtered neurogram (microneurography and continuous wavelet transform) during baseline conditions (BSL), the last 2‐min of a 5‐min fatiguing isometric handgrip (20% of max; IHG), and during post‐exercise circulatory occlusion (PECO) in six healthy young participants (3 females, 23–31 years). Baroreflex gain was measured as the slope of the linear function between AP probability (%) versus diastolic blood pressure (DBP; Finometer). We classified AP clusters based on peak‐to‐peak amplitude using the following allocations: small (clusters 1–2), medium (clusters 3–8) and large (clusters 9–15). During BSL, medium AP clusters (e.g., cluster 3: −9.4 ± 2.7 %/mmHg) expressed the greatest baroreflex gains while small (e.g., cluster 1: −1.9 ± 0.4 %/mmHg) and large (e.g., cluster 9: −2.4 ± 0.9 %/mmHg) clusters expressed lesser gains (both P &lt; 0.05 vs. cluster 3). Compared to BSL, baroreflex functions for most AP clusters during IHG and PECO were reset upwards to greater firing probabilities (both Condition‐by‐Cluster Interactions: P &lt; 0.05) and rightwards to higher DBP (BSL: 69 ± 4, IHG: 81 ± 3, PECO: 79 ± 2 mmHg; both P &lt; 0.05 vs. BSL). However, compared to BSL, the gains of the AP cluster baroreflex functions remained unchanged with IHG (e.g., cluster 1: −1.6 ± 0.4, cluster 3: −8.2 ± 2.9, cluster 9: −4.3 ± 1.8 %/mmHg, Main Effect: P &gt; 0.05). Nonetheless, AP cluster gains were augmented above BSL during PECO (e.g., cluster 1: −2.6 ± 1.0, cluster 3: −16.0 ± 4.4, cluster 9: −5.5 ± 1.8 %/mmHg; Main Effect: P &lt; 0.05). IHG (e.g., cluster 15: −1.6 ± 0.5 %/mmHg) and PECO (e.g., cluster 15: −0.6 ± 0.3 %/mmHg) recruited a subpopulation of previously silent larger and faster conducting APs that expressed weak baroreflex gains. These data suggest that during fatiguing isometric handgrip exercise the interaction between the central command feature and the skeletal muscle metaboreflex resets baroreflex control of discrete AP subpopulations to higher blood pressures and greater levels of discharge. In addition to resetting the baroreflex functions, independent activation of the muscle metaboreflex augments the strength of baroreflex control over subpopulations of previously active APs.Support or Funding InformationSupported by the Natural Sciences and Engineering Research Council (NSERC) of Canada.

Asynchronous action potential discharge in human muscle sympathetic nerve activity

What strategies are employed by the sympathetic system to communicate with the circulation? Muscle sympathetic nerve activity (MSNA) occurs in bursts of synchronous action potential (AP) discharge, yet whether between-burst asynchronous AP firing exists remains unknown. Using multiunit microneurography and a continuous wavelet transform to isolate APs, we studied AP synchronicity within human MSNA. Asynchronous APs were defined as those which occurred between bursts. Experiment 1 quantified AP synchronicity in eight individuals at baseline (BSL), -10 mmHg lower body negative pressure (LBNP), -40 mmHg LBNP, and end-expiratory apnea (APN). At BSL, 33 ± 12% of total AP activity was asynchronous. Asynchronous discharge was unchanged from BSL (67 ± 37 AP/min) to -10 mmHg LBNP (69 ± 33 AP/min), -40 mmHg LBNP (83 ± 68 AP/min), or APN (62 ± 39 AP/min). Across all conditions, asynchronous AP probability and frequency decreased with increasing AP size. Experiment 2 examined the impact of the ganglia on AP synchronicity by using nicotinic blockade (trimethaphan). The largest asynchronous APs were derecruited from BSL (11 ± 4 asynchronous AP clusters) to the last minute of the trimethaphan infusion with visible bursts (7 ± 2 asynchronous AP clusters). However, the 6 ± 2 smallest asynchronous AP clusters could not be blocked by trimethaphan and persisted to fire 100 ± 0% asynchronously without forming bursts. Nonnicotinic ganglionic mechanisms affect some, but not all, asynchronous activity. The fundamental behavior of human MSNA contains between-burst asynchronous AP discharge, which accounts for a considerable amount of BSL activity.NEW & NOTEWORTHY Historically, sympathetic nerve activity destined for the blood vessels supplying skeletal muscle (MSNA) has been characterized by spontaneous bursts formed by synchronous action potential (AP) discharge. However, this study found a considerable amount (~30% during baseline) of sympathetic AP discharge to fire asynchronously between bursts of human MSNA. Trimethaphan infusion revealed that nonnicotinic ganglionic mechanisms contribute to some, but not all, asynchronous discharge. Asynchronous sympathetic AP discharge represents a fundamental behavior of MSNA.

Epidural Spinal Cord Stimulation Acutely Reduces Efferent Postganglionic Sympathetic Nerve Activity in Humans

Evidence in clinical and animal studies demonstrates that epidural spinal cord stimulation (SCS) mimics the effects of sympathetic block or sympathectomy and increases peripheral blood flow. However, the extent to which SCS lowers sympathetic nerve activity in humans remains unclear because no studies have directly assessed muscle sympathetic nerve activity (MSNA) responses to SCS. We tested the hypothesis that acute SCS (60 min) at the lower thoracic spine would 1) lead to reduced MSNA in the peroneal nerve, and 2) increase blood flow in the legs, but not the arms. Twelve patients (54 ± 3 yrs, 5 men/7 women) that previously underwent surgical implantation of a SCS device for management of neuropathic pain were studied. Following 48 hours of no SCS, femoral and brachial artery blood flow was assessed using Doppler ultrasound at baseline and at 15, 30, 45, 60 min of SCS, and 15 min post SCS. MSNA was assessed using microneurography under the same conditions during a second visit (n=5). Femoral artery blood flow was significantly increased throughout SCS and 15 min post SCS (15 min: 26 ± 1%, 30 min: 32 ± 14%, 45 min: 30 ± 13%, 60 min: 26 ± 13%, 15 min post SCS: 40 ± 14% ml/min, P=0.02), but no change in brachial artery blood flow was observed (15 min: 4 ± 6%, 30 min: 5 ± 8%, 45 min: 5 ± 7%, 60 min: 7 ± 7% ml/min, 15 min post SCS: 6 ± 11% ml/min, P=0.86). MSNA was progressively reduced during SCS, reaching significance at 45 and 60 min, and returned toward baseline following SCS (15 min: −1 ± 6%, 30 min: −13 ± 4%, 45 min: −17 ± 6%, 60 min: −21 ± 7%, 15 min post SCS: −4 ± 5% bursts/100heartbeats, P=0.01). Similar results were observed for MSNA total activity (AU/min) (P&lt;0.042). During measures of MSNA, self‐reported neuropathic pain was low at baseline and not significantly changed by SCS (scale 0–10; BL: 2.8 ± 0.8, 15 min: 1.7 ± 0.9, 30 min: 1.5 ± 1, 45 min: 1.7 ± 1, 60 min: 1.5 ± 1, P=0.07), suggesting that reductions in MSNA were SCS‐mediated and not primarily a result of pain relief. These preliminary results demonstrate proof of principle that acute lower thoracic SCS significantly reduces peroneal MSNA in humans.Support or Funding InformationAHA 17POST33440101, T32 HL07121, NHLBI (P01HL014388), U54 TR001356 and AHA (13DG143400012)This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Sympathetic Nerve Activity in Monozygotic Twins: Identical at Rest but Not During Arousal.

Microneurographic recordings of human muscle sympathetic nerve activity responses to sudden sensory stimuli (ie, arousal) have revealed 2 intraindividually reproducible response profiles in healthy young males that predict different neural and blood pressure responses to more sustained stress. Approximately 50% of subjects inhibit muscle sympathetic nerve activity during arousal, whereas the remaining 50% do not, and the latter group displays a markedly greater blood pressure increase in response to arousal, as well as during and after 3 minutes of mental arithmetic. Studying a group of monozygotic twins (10 pairs, 2 excluded from analysis), the aim of the present study was to evaluate the degree of genetic determination of these sympathetic response profiles. Muscle sympathetic burst incidence at rest was similar in twins, with a within-pair burst incidence ratio of 0.87±0.02 (SEM) compared with 0.73±0.07 found in unrelated pairs (P=0.002), confirming a previous study from our laboratory. In contrast, the sympathetic responses to arousal showed large twin within-pair variance (arousal inhibition ratio 0.56±0.11), which did not significantly differ (P=0.939) from the variance in pairs of unrelated subjects (0.46±0.11). The finding that human muscle sympathetic nerve responses to arousal are less determined by genotype than the resting level of corresponding sympathetic nerve activity suggests that the arousal response pattern is more prone to be altered by environmental factors. This raises the possibility that these intraindividually reproducible sympathetic neural response profiles can be modified in a positive direction from a cardiovascular risk perspective.

Human muscle sympathetic nerve responses to urocortin-2 in health and stable heart failure.

Sympatholytic and vasodilator drugs have been of major therapeutic benefit in patients with heart failure (HF). Urocortin-2 (Ucn2) is a small corticotrophin-related peptide distributed throughout the cardiovascular system which inhibits cardiac sympathetic nerve activity (CSNA) and is also a powerful vasodilator. This study analysed the effects of a 60-min infusion of Ucn2 (25μg) on muscle sympathetic nerve activity (MSNA) recorded from the lower limb in eight healthy men and four men with stable HF. During Ucn2 infusion, mean arterial pressure fell to a nadir of 84±2 compared to 95±2mmHg during placebo (P=0.001) and heart rate increased to a maximum of 74±1 compared to 64±1b.p.m. (P<0.001). Total peripheral resistance fell by 23±4% compared with an increase of 23±4% (P<0.001) and cardiac output increased by 22±4 compared to 4±4% (P=0.001). The MSNA burst frequency increased by 9±2 compared to 1±2 burst/min (P=0.005) and burst area/min by 133±7 vs 107±7% (P=0.01). Burst incidence and baroreflex sensitivity were not significantly altered. Qualitatively similar changes were observed in stable HF patients. Ucn2-induced vasodilatation increased MSNA in humans, as opposed to the decrease in CSNA we observed in sheep. Therefore, if Ucn2 has a central inhibitory effect on MSNA, it was over-run by off-loading the cardiovagal baroreflex. Alternatively, CSNA may be less responsive to baroreflex off-loading than MSNA.

Distension of central great vein decreases sympathetic outflow in humans

Classic canine studies suggest that central great vein distension evokes an autonomic reflex tachycardia (Bainbridge reflex). It is unclear whether central venous distension in humans is a necessary and sufficient stimulus to evoke a reflex increase in heart rate (HR), blood pressure (BP), and muscle sympathetic nerve activity (MSNA). Prior work from our laboratory suggests that limb venous distension evokes a reflex increase in BP and MSNA in humans. We hypothesized that in humans, compared with the limb venous distension, inferior vena cava (IVC) distension would evoke a less prominent increase in HR and MSNA. IVC distension (monitored with ultrasonography) was induced by two methods: 1) head-down tilt (HDT, N = 13); and 2) lower-body positive pressure (LBPP, N = 10). Two minutes of HDT induced IVC distension (Δ2.6 ± 0.2 mm, P < 0.001, ~27% in cross-sectional area), slightly increased mean BP (Δ2.3 ± 0.7 mmHg, P = 0.005), decreased MSNA (Δ5.2 ± 0.8 bursts/min, P < 0.001, N = 10), and did not alter HR (P = 0.37). LBPP induced similar IVC distension, increased BP (Δ2.0 ± 0.7 mmHg, P < 0.01), and did not alter HR (P = 0.34). Thus central venous distension leads to a rapid increase in BP and a subsequent fall in MSNA. Central venous distension does not evoke either bradycardia or tachycardia in humans. The absence of a baroreflex-mediated bradycardia suggests that the Bainbridge reflex is engaged. Clearly, this reflex differs from the powerful sympathoexcitation peripheral venous distension reflex described in humans.

Sympathetic neural tone: large and in charge throughout pregnancy

Sympathetic neural tone: large and in charge <i>throughout</i> pregnancy

Baroreflex mechanisms regulating the occurrence of neural spikes in human muscle sympathetic nerve activity

This study tested the hypothesis that the discharge patterns of action potentials (APs) within bursts of postganglionic muscle sympathetic nerve activity (MSNA) are subject to arterial baroreflex control but in a manner that varies inversely with AP size. MSNA data were collected over 5 min of supine rest in 15 young and healthy individuals (8 males; 24 ± 4 yr of age; means ± SD). The baroreflex threshold and sensitivity diagrams were constructed for both the integrated sympathetic bursts and for the AP clusters. For the integrated bursts, a strong linear relationship between burst probability and diastolic blood pressure (DBP) was observed (P < 0.05). There was little relationship between integrated burst strength (amplitude) and DBP. On average, 12 AP clusters were observed across individuals. Larger APs tended to appear in the larger bursts. Linear regression analysis was used to study the baroreflex threshold (probability of AP cluster occurrence vs. DBP) as well as the baroreflex sensitivity (AP cluster size vs. DBP). A significant reflex threshold relationship was observed in 75-100% of AP clusters across all individuals. In contrast, significant reflex sensitivity relationships were observed in only 9 of 15 individuals and for limited APs. Overall, the slope of the AP baroreflex threshold relationship was greater for the small-medium sized AP clusters than that of the larger APs. Therefore, within each burst, the small-medium sized APs are governed by the baroreflex mechanism. However, the large APs, which tend to appear in the large integrated bursts, are weakly associated with a baroreflex control feature. The variable impact of baroreflex control over AP occurrence provides a plausible explanation for the overall weak baroreflex control over integrated burst strength, a feature that is determined by both the number and size of the AP complement.

Baroreflex mechanisms regulating the occurrence of sympathetic action potentials in human muscle sympathetic nerve activity

Baroreflex mechanisms regulating the occurrence of sympathetic action potentials in human muscle sympathetic nerve activity

Relationship between size and latency of action potentials in human muscle sympathetic nerve activity

We employed a novel action potential detection and classification technique to study the relationship between the recruitment of sympathetic action potentials (i.e., neurons) and the size of integrated sympathetic bursts in human muscle sympathetic nerve activity (MSNA). Multifiber postganglionic sympathetic nerve activity from the common fibular nerve was collected using microneurography in 10 healthy subjects at rest and during activation of sympathetic outflow using lower body negative pressure (LBNP). Burst occurrence increased with LBNP. Integrated burst strength (size) varied from 0.22 ± 0.07 V at rest to 0.28 ± 0.09 V during LBNP. Sympathetic burst size (i.e., peak height) was directly related to the number of action potentials within a sympathetic burst both at baseline (r = 0.75 ± 0.13; P < 0.001) and LBNP (r = 0.75 ± 0.12; P < 0.001). Also, the amplitude of detected action potentials within sympathetic bursts was directly related to the increased burst size at both baseline (r = 0.59 ± 0.16; P < 0.001) and LBNP (r = 0.61 ± 0.12; P < 0.001). In addition, the number of detected action potentials and the number of distinct action potential clusters within a given sympathetic burst were correlated at baseline (r = 0.7 ± 0.1; P < 0.001) and during LBNP (r = 0.74 ± 0.03; P < 0.001). Furthermore, action potential latency (i.e., an inverse index of neural conduction velocity) was decreased as a function of action potential size at baseline and LBNP. LBNP did not change the number of action potentials and unique clusters per sympathetic burst. It was concluded that there exists a hierarchical pattern of recruitment of additional faster conducting neurons of larger amplitude as the sympathetic bursts become stronger (i.e., larger amplitude bursts). This fundamental pattern was evident at rest and was not altered by the level of baroreceptor unloading applied in this study.

Spike detection in human muscle sympathetic nerve activity using a matched wavelet approach

AbstractSympathetic nerve recordings associated with blood pressure regulation can be recorded directly using microneurography. A general characteristic of this signal is spontaneous burst activity of spikes (action potentials) separated by silent periods against a background of considerable Gaussian noise. During measurement with electrodes, the raw muscle sympathetic nerve activity (MSNA) signal is amplified, band-pass filtered, rectified and integrated. This integration process removes information regarding action potential content and their discharge properties. This paper proposes a new method for detecting action potentials from the raw MSNA signal to enable investigation of post-ganglionic neural discharge properties.The new method is based on the design of a mother wavelet that is matched to an actual mean action potential template extracted from a real raw MSNA signal. To detect action potentials, the new matched wavelet is applied to the MSNA signal using a continuous wavelet transform following a thresholding procedure and finding of a local maxima that indicates the location of action potentials. The performance of the proposed method versus two previous wavelet-based approaches was evaluated using (1) real MSNA recorded from seven healthy participants and, (2) simulated MSNA. The results show that the new matched wavelet performs better than the previous wavelet-based methods that use a non-matched wavelet in detecting action potentials in the MSNA signal.

P2.8 Action potential content in human muscle sympathetic nerve activity

P2.8 Action potential content in human muscle sympathetic nerve activity

Modulation of muscle sympathetic nerve activity to muscle heating during dynamic exercise

Previous studies from our laboratory have demonstrated that altering muscle temperature of the exercising forearm can elicit changes in muscle sympathetic nerve activity (MSNA) during ischemic isometric handgrip. The purpose of the current study was to determine the interactive effect of muscle temperature and blood flow on MSNA responses during dynamic handgrip (DHG). Eight subjects performed two bouts of graded DHG to fatigue followed by 2 min of postexercise muscle ischemia (PEMI). Local heating of the forearm increased muscle temperature from 33.6 +/- 0.3 to 38.3 +/- 0.5 degrees C (P < 0.05). Mean arterial pressure and heart rate increased in a linear fashion during graded DHG (P < 0.05) but were not affected by muscle temperature. MSNA (burst frequency and total activity) at fatigue and PEMI were elevated in all conditions (P < 0.05). However, MSNA responses were not different between temperature conditions. To ascertain the effect of blood flow, eight additional subjects completed two trials of ischemic DHG under control or warm conditions followed by 2 min of PEMI. MSNA, expressed as burst frequency and total activity, was significantly greater in warm compared with the control trial (Delta14 +/- 3 and Delta9 +/- 2 bursts/30 s, and Delta1,234 +/- 260 and Delta751 +/- 199 units/30 s, respectively). This finding supports the concept that muscle heating sensitizes skeletal muscle afferents during muscle contractions and augments MSNA in humans. However, on the basis of these findings, we conclude that muscle blood flow modulates the effect of muscle temperature on MSNA during exercise.

Spike detection in human muscle sympathetic nerve activity using the kurtosis of stationary wavelet transform coefficients

The accurate assessment of autonomic sympathetic function is important in the diagnosis and study of various autonomic and cardiovascular disorders. Sympathetic function in humans can be assessed by recording the muscle sympathetic nerve activity, which is characterized by synchronous neuronal discharges separated by periods of neural silence dominated by colored Gaussian noise. The raw nerve activity is generally rectified, integrated, and quantified using the integrated burst rate or area. We propose an alternative quantification involving spike detection using a two-stage stationary wavelet transform (SWT) de-noising method. The SWT coefficients are first separated into noise-related and burst-related coefficients on the basis of their local kurtosis. The noise-related coefficients are then used to establish a threshold to identify spikes within the bursts. This method demonstrated better detection performance than an unsupervised amplitude discriminator and similar wavelet-based methods when confronted with simulated data of varying burst rate and signal to noise ratio. Additional validation on data acquired during a graded head-up tilt protocol revealed a strong correlation between the mean spike rate and the mean integrate burst rate (r=0.85) and burst area rate (r=0.91). In conclusion, the kurtosis-based wavelet de-noising technique is a potentially useful method of studying sympathetic nerve activity in humans.

Muscle Sympathetic Nerve Activity During a Sodium and Volume Load

Animal models demonstrate a strong association between plasma osmolality and sympathetic outflow. The purpose of this study was to determine if a stepwise increase in plasma osmolality causes parallel increases in blood pressure and muscle sympathetic nerve activity. Eight healthy, normotensive subjects (24±2 years) completed both a 60-minute hypertonic (3% NaCl; HSI) and normal (0.9% NaCl; NSI) saline infusion (0.15ml/kg/min) at random separated by one month. Heart rate (ECG), mean arterial pressure (Finometer; MAP) and muscle sympathetic nerve activity (MSNA) were assessed at baseline, 20, 40, and 60 minutes. Sodium, osmolality, and hematocrit (Hct) were assessed throughout the infusion. A 2-way repeated measures ANOVA was used to determine statistical significance. Results are reported as mean±SE. Osmolality increased during the HSI (pre=289±1, post=297±1 mOsm/kg; p<0.03) but not during the NSI (pre=290±1, post=290±1 mOsm/kg; p>0.40). Hct declined during the HSI (42±1 to 37±1%) and the NSI (41±1 to 39±1%). There was a time and treatment interaction for burst frequency (p=0.03): burst frequency initially increased from 15±3 to 19±2 during the HSI, and declined from 14±3 to 12±2 bursts/min during the NSI (post hoc at the 20-minute time point; p<0.01) before returning to baseline values. There was a time (p=0.003) but no treatment effect for MAP. Preliminary results suggest that increases in osmolality may cause acute increases in MSNA in humans. Supported by NIH grant R15 HL074851-01

Is obstructive sleep apnea the cause of sympathetic nervous activation in human obesity?

based on findings in experimental models of obesity, the sympathetic nervous system has commonly been assumed to have a determining role in obesity development through its influence on the regulation of energy expenditure. An earlier hypothesis was that sympathetic nervous activity was low in