The “Unsympathetic” Nervous System of Heart Failure
2002; Lippincott Williams & Wilkins; Volume: 105; Issue: 15 Linguagem: Inglês
10.1161/01.cir.0000013788.71817.16
ISSN1524-4539
Autores Tópico(s)Heart Failure Treatment and Management
ResumoHomeCirculationVol. 105, No. 15The "Unsympathetic" Nervous System of Heart Failure Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBThe "Unsympathetic" Nervous System of Heart Failure John S. Floras, MD, DPhil John S. FlorasJohn S. Floras From University Health Network and Mount Sinai Hospital, Department of Medicine, and the University of Toronto, Toronto, Canada. Originally published16 Apr 2002https://doi.org/10.1161/01.CIR.0000013788.71817.16Circulation. 2002;105:1753–1755Sympathetic activation in heart failure is intimately linked to disease progression and to adverse outcome.1–3 Contemporary management of heart failure relies on three antiadrenergic strategies, predicated on the hypothesis that interventions that counter sympathetic overactivity will improve both symptoms and prognosis. First, excessive central sympathetic outflow to the heart and periphery can be reduced by normalizing elevated cardiac filling pressures,4 by abolishing coexisting obstructive sleep apnea with nocturnal continuous positive airway pressure,5 or by attenuating sympathoexcitatory reflexes activated by exercising muscle through conditioning. Although rational, thus far these interventions have not been proven to improve survival.See p 1797A second approach has been to modulate the neural regulation of norepinephrine (NE) release. Examples include digitalis glycosides, which appear to sensitize acutely and therefore increase the discharge of arterial baroreceptors, and ACE inhibitors, which should diminish or block the prejunctional facilitatory effects of angiotensin II on NE release. However, the impact of ACE inhibitors on plasma NE (PNE) concentrations is relatively modest,6,7 suggesting that their mortality benefit accrues primarily through nonadrenergic mechanisms.Third, sympathetic activation may be addressed indirectly, by blocking the actions of catecholamines on postjunctional adrenergic receptors. A series of placebo-controlled trials has demonstrated the symptomatic, hemodynamic, and mortality benefits of β-adrenoceptor antagonists.8–10 β1 blockade, as exerted by metoprolol or bisoprolol, may be sufficient to achieve these effects. Whether concomitant β2-adrenoceptor antagonism, as with carvedilol or bucindolol, confers any additional benefit is the subject of an ongoing comparative mortality trial. Although carvedilol is also classified as an α1 antagonist, this action does not appear to be functionally important during long-term treatment.11 Thus, long-term β-blockade leaves α-adrenoceptor–mediated vasoconstriction and renal sodium retention unopposed. Moreover, β-blockade does not shield the heart and periphery from neuropeptide Y or ATP, vasoconstrictor neurotransmitters coreleased by noradrenergic nerves.A more effective approach might be to attenuate central sympathetic outflow directly, by stimulating α2 plus imidazoline I1 receptors located within the rostroventrolateral reticular nucleus. Clonidine, an α2 and I1 receptor agonist, has been used for this purpose. Grassi et al12 have recently reported a 26% reduction in muscle sympathetic burst frequency and a 47% fall in PNE concentrations after 2 months of 0.1 mg clonidine daily, administered by transdermal patch. More selective I1 agonists, such as rilmenidine and moxonidine, have fewer side effects than clonidine. The hope has been that this strategy might confer greater long-term clinical benefit and patient acceptance than β-adrenoceptor blockade.In this issue of Circulation, Swedberg et al13 report the results of their multicenter Moxonidine Safety and Efficacy (MOXSE) trial. The principal objective of this double-blind, dose-response study, involving 268 subjects, was to determine the effect of a sustained-release (SR) preparation of moxonidine on PNE concentrations in class II-IV heart failure. Patients with an ejection fraction ≤35% were randomly allocated placebo or one of 5 target doses of SR moxonidine (0.3, 0.6, 0.9, 1.2, or 1.5 mg BID). Background therapy included ACE inhibition or angiotensin II antagonism. β-Blocker use within the previous 30 days was an exclusion criterion. PNE was measured at baseline, at weekly visits during dose titration, and before and 4 hours after drug administration after 7 and 19 weeks of treatment. PNE was also assessed daily, for 3 days, after drug withdrawal. Ambulatory ECG recordings were obtained at baseline, at 19 weeks, and at the end of the washout period. In American centers where radionuclide angiography was available, left ventricular ejection fraction (LVEF) was quantified at baseline and at 19 weeks of treatment. Tolerability and safety data were also acquired.The key finding was a remarkable dose-related decrease in PNE at the 19th week of therapy (P 50%. In addition, there was a significant dose-related increase in LVEF (P=0.015). Demonstration of a marked reduction in this (albeit indirect) marker of sympathetic activity, coupled with increases in LVEF analogous to those obtained with long-term β-blockade would therefore appear, on first reading, to validate the concept of central sympathoinhibition in heart failure. However, there was a concerning dose-related increase in the number of patients who had serious adverse events (P=0.038). Of the 10 deaths recorded, 9 occurred in the 140 patients assigned doses of 0.9 mg BID or higher and none in placebo-treated patients.The importance of the MOXSE study therefore extends beyond these particular observations to the context and insights these data bring to the interpretation of the subsequent Moxonidine Congestive Heart Failure (MOXCON) trial. Although not yet published, the primary end point of this trial (led by many of the same investigators) has been widely reported at scientific forums. In MOXCON, patients with class II-IV symptoms and LVEF ≤35% were randomly assigned to placebo or 1.5 mg SR moxonidine BID. The primary end point was all-cause mortality. Randomization began on May 25, 1998. With only 1993 of the anticipated 4533 patients recruited, the trial was terminated prematurely on March 12, 1999, on the recommendation of the Data Monitoring Board. There was an excess of deaths (both sudden and those caused by progressive pump failure) in the active treatment group (54 versus 32; P=0.005).What can this mortality rate excess be attributed to? The MOXSE data suggest three potential hypotheses above and beyond the play of chance.At baseline, median values for PNE in those assigned placebo and moxonidine were 369 pg/mL (2.18 nmol/L) and 394 pg/mL, respectively (Table 213). For comparison, the median value (with 25% to 75% confidence intervals) for PNE in younger but healthy control subjects in the Studies of Left Ventricular Dysfunction (SOLVD) trial was 317 (242 to 450) pg/mL. Corresponding values for patients recruited to the SOLVD (asymptomatic) prevention and treatment study arms were 422 (312 to 566) and 507 (368 to 644) pg/mL, respectively.14 Thus, the first possibility is that a considerable number of the patients recruited to MOXSE were not sympathetically activated (probably as a result of appropriate medical therapy) and therefore were unlikely to benefit from central adrenergic inhibition. This concern might have been avoided had trial subjects been selected or stratified on the basis of a screening PNE.Although the MOXSE investigators chose not to relate events in their pilot study to reductions in PNE, a second possibility is that in some patients, the higher moxonidine doses may have been inappropriately sympathoablative. Table 213 in the MOXSE article reveals that 19 weeks of 1.5 mg SR moxonidine BID (the MOXCON study dose) lowered median values for PNE to 249 pg/mL. This corresponds to the 25th percentile of PNE values reported for healthy control subjects in the SOLVD study. The impact of this dose of moxonidine on sympathetic discharge directed at the heart, kidney, and other important vascular beds has not been reported and cannot be determined from these venous PNE concentrations, which reflect primarily the neural release of NE from forearm sympathetic nerves. However, responses to 0.1 mg clonidine IV have been documented.15 These include reductions in arterial NE concentrations, cardiac NE spillover, and LV+dP/dt of 47%, 58%, and 15%, respectively. Thus, in some moxonidine-treated patients, residual sympathetic outflow might have been insufficient to support cardiac output or peripheral resistance, leading to progressive pump failure.In their Introduction, the authors propose an additional potential advantage of central inhibition with moxonidine over other forms of antiadrenergic therapy: "the degree of blockade can be quantified by monitoring PNE levels and thus individualizing treatment to maintain clinically appropriate levels of antiadrenergic effect." Although intuitively attractive, this hypothesis was not tested. It is based on several key assumptions. The first is that a single PNE determination can provide a meaningful representation of the extent of sympathetic activation in a specific patient. However, as illustrated by microneurographic recordings, sympathetic nerve discharge in heart failure exhibits dynamic short-term variation. Effects on sympathetic discharge to the heart and kidney cannot be inferred reliably from changes in PNE. Thus, a single value for PNE may be as representative of the cumulative daily impact of sympathetic discharge on the heart and periphery as is a single clinic measurement of 24-hour ambulatory blood pressure. The second assumption is that patients with heart failure share quantitatively similar mechanisms of sympathetic activation and that it is therefore possible to determine a "clinically appropriate level" for each individual. Although a baroreceptor-mediated reflexive increase in sympathetic outflow (in response to decreases in stroke volume, ventricular inotropy, and blood pressure) may be common to all patients with LV systolic dysfunction, the magnitude of this response will differ from patient to patient. Additional sympathoexcitatory stimuli such as elevated atrial pressure, pulmonary congestion, coexisting sleep-related breathing disorders, and chemoreceptor or muscle metaboreceptor afferent activity will also vary considerably between patients. Without characterizing the extent of these several mechanisms of sympathetic activation, one cannot be certain that PNE in a particular patient is appropriate to their heart failure state or excessive, and if the latter, a target for judicious central sympathoinhibition. A third assumption is that any reduction in PNE must be due to sympatholysis. However, changes in cardiac output will also affect the plasma concentration of NE by altering its neuronal and extraneuronal clearance. Thus, PNE-directed heart failure management is likely to remain an elusive goal.The dynamic nature of sympathetic discharge in heart failure is best illustrated by the section on moxonidine withdrawal, which may be the most important aspect of this study. Increases in heart rate, blood pressure, and PNE during the withdrawal phase of the MOXSE trial were greatly in excess of corresponding reductions achieved by active treatment. This may not have been anticipated, because a comparative study in hypertensive patients reported less rebound with moxonidine than with clonidine.16 In subjects assigned the highest moxonidine dose, heart rate fell by ≈7 beats/min with treatment but increased, on washout, by >14 beats/min; 20% to 30% more ventricular ectopy was also noted at this time. Moxonidine did not affect systolic blood pressure, but a mean increase of 9 mm Hg occurred on its withdrawal. PNE rose significantly within a day of stopping moxonidine. By the third day, PNE increased, on average, by 709 pg/mL (+275%), reaching absolute levels associated, in previous studies, with a >40% 6-month mortality rate.1,9 The rebound increases in PNE reported in Table 213 might have been even greater had the Data Monitoring Board not recommended cautious "dose tapering to avoid the potential of rebound when moxonidine SR was acutely discontinued" "after observing the signs and symptoms of the first 55 patients during this acute withdrawal phase." At the end of the dose maintenance phase, patients who were receiving >0.6 mg BID of moxonidine were downtitrated to 0.6 mg BID for 1 week before receiving placebo. Thus, when considering the MOXCON trial of 1.5 mg SR moxonidine BID, marked noradrenergic rebound during brief periods of nonadherence must be considered a plausible mechanism of sudden death in some patients receiving active treatment.The fundamental question raised by these observations is whether death in the MOXSE and MOXCON studies should be attributed to excessive sympatholysis (as has been invoked to explain the anomalous result of the bucindolol trial17); to intense rebound surges in sympathetic drive, heart rate, and blood pressure, in occasionally noncompliant patients; or to both of these dose-related mechanisms. Until this dilemma is resolved, further investment in this once-promising class of drugs for heart failure is unlikely. Unfortunately, the MOXCON trial was initiated before these MOXSE study data were analyzed and available for consideration. A different trial design, recruiting only patients with clear evidence for excessive sympathetic drive, or testing a lower or individualized dose of SR moxonidine, might have yielded a less discouraging outcome.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.The author is the recipient of a Career Investigator Award from the Heart and Stroke Foundation of Ontario.FootnotesCorrespondence to Dr John S. Floras, 1614–600 University Ave, Toronto, ON M5G 1X5 Canada. E-mail [email protected] References 1 Cohn JN, Levine TB, Olivari MT, et al. Plasma norepinephrine as a guide to prognosis in patients with chronic congestive heart failure. N Engl J Med. 1984; 311: 819–824.CrossrefMedlineGoogle Scholar2 Floras JS. Clinical aspects of sympathetic activation and parasympathetic withdrawal in heart failure. J Am Coll Cardiol. 1993; 22: 72A–84A.CrossrefMedlineGoogle Scholar3 Kaye DM, Lefkovits J, Jennings GL, et al. Adverse consequences of high sympathetic nervous activity in the failing human heart. J Am Coll Cardiol. 1995; 26: 1257–1263.CrossrefMedlineGoogle Scholar4 Azevedo ER, Newton GE, Floras JS, et al. Reducing cardiac filling pressure lowers cardiac norepinephrine spillover in patients with chronic heart failure. Circulation. 2000; 101: 2053–2059.CrossrefMedlineGoogle Scholar5 Bradley TD, Floras JS. Pathophysiologic and therapeutic implications of sleep apnea in congestive heart failure. J Card Fail. 1996; 2: 223–240.CrossrefMedlineGoogle Scholar6 Benedict CR, Francis GS, Shelton B, et al. Effect of long-term enalapril therapy on neurohormones in patients with left ventricular dysfunction: SOLVD Investigators. Am J Cardiol. 1995; 75: 1151–1157.CrossrefMedlineGoogle Scholar7 Swedberg K, Eneroth P, Kjekshus J, et al. Hormones regulating cardiovascular function in patients with severe congestive heart failure and their relation to mortality: CONSENSUS trial study group. Circulation. 1990; 82: 1730–1736.CrossrefMedlineGoogle Scholar8 Packer M, Coats AJ, Fowler MB, et al. Effect of carvedilol on survival in severe chronic heart failure. N Engl J Med. 2001; 344: 1651–1657.CrossrefMedlineGoogle Scholar9 CIBIS-II Investigators and Committees. The cardiac insufficiency bisoprolol study II (CIBIS II): a randomized trial. Lancet. 1999; 353: 9–13.CrossrefMedlineGoogle Scholar10 MERIT-HF Study Group. Effect of metoprolol CR/XL in chronic heart failure: Metoprolol CR/XL randomized intervention trial in congestive heart failure (MERIT-HF). Lancet. 1999; 353: 2001–2007.CrossrefMedlineGoogle Scholar11 Kubo T, Azevedo ER, Newton GE, et al. Lack of evidence for alpha 1-adrenoceptor blockade during long-term treatment of heart failure with carvedilol. J Am Coll Cardiol. 2001; 38: 1463–1469.CrossrefMedlineGoogle Scholar12 Grassi G, Turri C, Seravalle G, et al. Effects of chronic clonidine administration on sympathetic nerve traffic and baroreflex function in heart failure. Hypertension. 2001; 38: 286–291.CrossrefMedlineGoogle Scholar13 Swedberg K, Bristow M, Cohn JN, et al. The effects of moxonidine SR, an imidazoline agonist, on plasma norepinephrine in patients with chronic heart failure. Circulation. 2002; 105: 1797–1803.LinkGoogle Scholar14 Francis GS, Benedict C, Johnstone DE, et al. Comparison of neuroendocrine activation in patients with left ventricular dysfunction with and without congestive heart failure. Circulation. 1990; 82: 1724–1729.CrossrefMedlineGoogle Scholar15 Azevedo ER, Newton GE, Parker JD. Cardiac and systemic sympathetic activity in response to clonidine in human heart failure. J Am Coll Cardiol. 1999; 33: 186–191.CrossrefMedlineGoogle Scholar16 Planitz V. Crossover comparison of moxonidine and clonidine in mild to moderate hypertension. Eur J Clin Pharmacol. 1984; 27: 147–152.CrossrefMedlineGoogle Scholar17 Braunwald E. Expanding indications for beta-blockers in heart failure. N Engl J Med. 2001; 344: 1711–1712.CrossrefMedlineGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Lymperopoulos A, Cora N, Maning J, Brill A and Sizova A (2021) Signaling and function of cardiac autonomic nervous system receptors: Insights from the GPCR signalling universe, The FEBS Journal, 10.1111/febs.15771, 288:8, (2645-2659), Online publication date: 1-Apr-2021. Sklerov M, Dayan E and Browner N (2018) Functional neuroimaging of the central autonomic network: recent developments and clinical implications, Clinical Autonomic Research, 10.1007/s10286-018-0577-0, 29:6, (555-566), Online publication date: 1-Dec-2019. 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