Combined sympathetic suppression and angiotensin-converting enzyme inhibition in congestive heart failure

Optimizing treatment and outcomes in acute heart failure: beyond initial triage

Heart failure contributes substantially to health care costs in the United States due to its prevalence and frequent necessity for repeat hospitalizations to manage episodes of acute decompensation. Heart failure overwhelmingly impacts Medicare costs, as the highest proportion of heart failure patients are older than 65 years of age. Efforts to reduce morbidity, mortality, and health care resource utilization have been achieved successfully through emergency department-based heart failure observation units. For select patients, the observation unit can provide care with effective oral agents, including angiotensin-converting enzyme inhibitors, beta-adrenergic receptor blockers, and diuretics, as well as administration of other vasoactive agents, followed by a discharge plan of effective heart failure education and rigorous follow-up management. As advanced pharmacologic and diagnostic therapies continue to emerge, the observation unit staff can play an integral role in the critical education and self-management tools that are needed by the patient to ultimately improve outcomes and quality of life.

Measurement of sympathetic nervous system activity in heart failure: the role of norepinephrine kinetics

Recent demonstration that the level of sympathetic nervous drive to the failing heart in patients with severe heart failure is a major determinant of prognosis, and that mortality in heart failure is reduced by beta-adrenergic blockade, indicate the clinical relevance of heart failure neuroscience research. The cardiac sympathetic nerves are preferentially stimulated in severe heart failure, with the application of isotope dilution methods for measuring cardiac norepinephrine release to plasma indicating that in untreated patients cardiac norepinephrine spillover is increased as much as 50-fold, similar to levels of release seen in the healthy heart during near maximal exercise. This preferential activation of the cardiac sympathetic outflow contributes to arrhythmia development and to progressive deterioration of the myocardium, and has been linked to mortality in both mild and severe cardiac failure. Although the central nervous system mechanisms involved in the sympathetic nervous activation at present remain uncertain, increased intracardiac diastolic pressure seems to be one peripheral reflex stimulus, and increased forebrain norepinephrine turnover an important central mechanism.Additional neurophysiological abnormalities present in the failing human heart include release of the sympathetic cotransmitters, epinephrine and neuropeptide Y, at high levels more typical of their release during exercise in healthy subjects, and the possible presynaptic augmentation of norepinephrine release from the cardiac sympathetic nerves by the regionally released epinephrine. Following on the demonstrable benefit of beta-adrenergic blockade in heart failure, additional antiadrenergic measures (central suppression of sympathetic outflow with imidazoline binding agents such as clonidine, blocking of norepinephrine synthesis by dopamine-beta-hydroxylase inhibition, antagonism of neuropeptide Y) are now under active investigation.

Heart failure observation units: optimizing care

Heart failure causes substantial morbidity and mortality in the United States and accounts for a higher proportion of Medicare costs than any other disease. Most of these costs result from the high rate of hospital admissions and protracted length of stay associated with episodes of acute decompensation of heart failure. Thus, effective clinical strategies to obviate hospitalization and readmission can result in substantial savings. A specialized heart failure observation unit, in which patients receive rapid, goal-directed emergency care for heart failure symptoms, can be a critical component in this effort, providing intensive therapeutic monitoring and education. In institutions with specialized heart failure observation units, patients are triaged to this setting shortly after presentation to the emergency department (ED), and clinic referrals can be directed to this unit after minimal ED evaluation. Aggressive follow-up is also arranged at discharge. Recent additions to the therapeutic armamentarium and future advances in diagnostics and monitoring will continue to improve patient care and prevent avoidable hospitalizations.

Hypotension Due to Interaction Between Lisinopril and Tizanidine

OBJECTIVE

To report a case in which significant hypotension occurred after initiation of tizanidine in a patient using the antihypertensive agent lisinopril.

CASE SUMMARY

A 48-year-old woman was admitted due to cerebral hemorrhage at the midbrain and pons, with extension to the fourth ventricle. Consciousness disturbance (Glasgow coma scale 4) with a decerebrate posture improved 5 days after stroke onset. As the BP was fairly high, antihypertensive agents, including lisinopril, were initiated. Three weeks later, the decerebrate rigidity and high BP remained, and tizanidine was initiated to see whether the decrease in muscle tone could facilitate hypertension control and motor recovery. However, the BP dropped dramatically within 2 hours after the first dose of tizanidine. The tizanidine and all of the antihypertensive medications were withdrawn. Tizanidine was used again after her BP had stabilized, but did not produce similar problems.

DISCUSSION

A similar event was reported in 2000. The reaction in our patient appeared after tizanidine initiation and improved after both lisinopril and tizanidine were discontinued. According to the Naranjo probability scale, this was classified as a possible drug interaction. This kind of reaction is seldom mentioned as occurring during co-administration with tizanidine. With its characteristics, tizanidine has the potential to compromise hemodynamic stability during concomitant angiotensin-converting enzyme inhibitor use.

CONCLUSIONS

Based upon the literature review, the hypotension in this patient was possibly due to the interaction between tizanidine and lisinopril.

Effect of Clonidine on Cardiac Norepinephrine Spillover in Isolated Rat Heart

The purpose of this study is to determine the effect of clonidine on cardiac norepinephrine spillover utilizing an isolated rat heart preparation with attached cardiac sympathetic nerves. Following a 20-minute stabilization period, the sympathetic ganglion for each heart preparation was electrically stimulated with 10V and 2 Hz for 30 seconds (S1: 60 pulses). Heart rate, left ventricular developed pressure, and coronary perfusion pressure was allowed to return to baseline and the perfusate was randomly switched to Krebs buffer containing one of two treatments: placebo or clonidine (1 microM). After 10 minutes of treatment, the sympathetic ganglion was again electrically stimulated with 10V and 2 Hz for 30 seconds (S2: 60 pulses). The perfusate exiting the heart before, during, and after each electrical stimulation was collected for the determination of cardiac norepinephrine spillover. Clonidine administration significantly reduced cardiac norepinephrine spillover by approximately 50% (P < 0.05) and was associated with a 36% reduction in heart rate (P < 0.05). These findings provide evidence that clonidine can directly suppress NE spillover from cardiac sympathetic nerve terminals. Thus, suppression of cardiac NE by clonidine may be due to stimulation of presynaptic alpha2-adrenergic receptors or imidazoline subtype I receptors located on cardiac sympathetic nerve terminals. Results from our study demonstrate a reduction in cardiac NE spillover by clonidine and provide additional evidence that it can directly suppress peripheral sympathetic activity in that our results were obtained utilizing an isolated perfused heart preparation with attached cardiac sympathetic nerves devoid of any CNS input.

Presynaptic modulation of evoked NE release contributes to sympathetic activation after pressure overload

Activation of the sympathetic nervous system is well documented in heart failure. Our previous studies demonstrated an increase in evoked norepinephrine (NE) release from left ventricle (LV) slices at 10 days of pressure overload. The purpose of this study was to test the hypothesis that presynaptic modulation of NE release contributes to sympathetic activation after pressure overload. We examined the functional status of the presynaptic α2- and β2-receptors and ANG II subtype 1 (AT1) receptors in LV slices from 10-day aortic constricted (AC) and sham-operated (SO) rats. Evoked 3H overflow from LV slices preloaded with [3H]NE was increased in AC rats. The α2-agonist UK-14,304 decreased evoked 3H overflow with no differences between groups. The β2-agonist salbutamol increased evoked 3H overflow with greater sensitivity in slices from AC rats. The β-antagonist propranolol decreased evoked 3H overflow from LV slices of AC rats but not controls. ANG II increased evoked 3H overflow with greater sensitivity in slices from AC rats. These data support the hypothesis that aberrant presynaptic modulation of catecholamine release contributes to sympathetic activation after pressure overload.

Does it make sense to develop new centrally acting cardiovascular drugs?

1. The autonomic nervous system plays a pivotal role in modulating all the components of the cardiovascular regulation. Therefore, one can assume that drugs targeting this system may be useful in the management of several cardiovascular diseases. 2. Drugs acting on central nervous system centres seem to be modulators rather than blockers; as such, they are expected to preserve the contraregulatory processes and to generate only a few side effects. 3. Because the sympathetic nervous system is largely involved in the regulation of vasomotor tone, centrally acting antihypertensive drugs were developed first. 4. Recently, new leader compounds selective for non- adrenergic imidazoline recepetors have been synthetized. Although such drugs have no capacity to activate alpha2-adrenoceptors, they have been proven to be hypotensive. These drugs are expected to be even better tolerated than the currently available centrally active drugs. They may also have additional beneficial effects. 5. Here, the experimental evidence suggesting that such drugs may be useful in the management of some cardiac arrhythmias and/or left ventricular dysfunction will be reviewed.

The alpha2 -adrenergic receptors in hypertension and heart failure: experimental and clinical studies

This is a brief overview of experimental and clinical studies exploring the hemodynamic functions of the alpha2A and alpha2B adrenergic receptor (AR) subtypes in animals submitted to genetic manipulations or gene treatment, as well as the clinical effects of central sympathetic suppression with the alpha2-AR agonist clonidine in patients with ischemic heart disease and/or heart failure. The animal experiments have led us to conclude that the sympathetic outflow is regulated by activation of the presynaptic alpha2A-AR subtype, which is the predominant alpha2-AR subtype in the central nervous system and exerts a sympathoinhibitory (hypotensive) action; on the contrary, activation of the central alpha2B-AR elicits a sympathoexcitatory response (such as seen in salt-induced hypertension, which requires functionally intact alpha2B-AR). Since there are no selective pharmacologic agents yet capable of discriminating among alpha2-AR subtypes, clinical studies utilize clonidine, the central sympathetic suppressant effect of which has been used for 35 years to treat hypertension. In small clinical trials, clonidine was used successfully for treatment of acute or chronic heart failure, acute myocardial infarct or hypertensive cardiomyopathy with subclinical diastolic dysfunction. We speculate that future development of agents capable of selectively activating the alpha2A-AR or blocking the alpha2B-AR may further improve our capability to treat hypertension, ischemic heart disease and heart failure.

Sympathetic nervous system activation in essential hypertension, cardiac failure and psychosomatic heart disease

Regional sympathetic activity can be studied in humans using electrophysiological methods measuring sympathetic nerve firing rates and neurochemical techniques providing quantification of noradrenaline spillover to plasma from sympathetic nerves in individual organs. Essential hypertension: Such measurements in patients with essential hypertension disclose activation of the sympathetic outflows to skeletal muscle blood vessels, the heart and kidneys, particularly in younger patients. This sympathetic activation, in addition to underpinning the blood pressure elevation, most likely also contributes to left ventricular hypertrophy, and to the commonly associated metabolic abnormalities of insulin resistance and hyperlipidaemia. Antihypertensive drugs, such as moxonidine, which act primarily by inhibiting the sympathetic nervous system, should have additional clinical benefits beyond those attributable to blood pressure reduction, in protecting against hypertensive complications. Obesity-related hypertension: Understanding the neural pathophysiology of hypertension in the obese has been difficult. In normotensive obesity, renal sympathetic tone is doubled, but cardiac noradrenaline spillover (a measure of sympathetic activity in the heart) is only 50% of normal. In obesity-related hypertension, there is a comparable elevation of renal noradrenaline spillover, but without suppression of cardiac sympathetics (cardiac sympathetic activity being more than double that of normotensive obese and 25% higher than in healthy volunteers). Increased renal sympathetic activity in obesity may be a 'necessary' cause for the development of hypertension (and predisposes to hypertension development), but apparently is not a 'sufficient' cause. The discriminating feature of the obese who develop hypertension is the absence of the adaptive suppression of cardiac sympathetic tone seen in the normotensive obese. Heart failure: In cardiac failure, the sympathetic nerves of the heart are preferentially stimulated. Noradrenaline release from the failing heart at rest in untreated patients is increased as much as 50-fold, similar to the level seen in the healthy heart during near-maximal exercise. Activation of the cardiac sympathetic outflow provides adrenergic support to the failing myocardium, but at a cost of arrhythmia development and progressive myocardial deterioration. Psychosomatic heart disease: No more than 50% of clinical coronary heart disease is explicable in terms of classical cardiac risk factors. There is gathering evidence that psychological abnormalities, particularly depressive illness, anxiety states, including panic disorder and mental stress, are involved here, 'triggering' clinical cardiovascular events, and possibly also contributing to atherosclerosis development. The mechanisms of increased cardiac risk attributable to mental stress and psychiatric illness are not entirely clear, but activation of the sympathetic nervous system seems to be of prime importance.

Chronic sympathetic suppression in the treatment of chronic congestive heart failure

Previous short-term studies demonstrated that treatment with clonidine produced significant hemodynamic improvement in patients with congestive heart failure (CHF). In this study we followed 12 CHF patients (10 M, 2 F age 63+/-11, 10 with ischemic cardiomyopathy and 2 with dilated cardiomyopathy) treated with 0.15 or 0.075 mg oral clonidine twice daily for 13+/-5 months (range 6-23). with functional evaluation at baseline, 6 weeks and 6 months. There was suppression of circulating catecholamines, associated with significant ameliorations in NYHA class, in duration of exercise tolerance (from 246+/-68 sec to 362+/-30 and 459+/-70 sec, respectively p < 0.02), in ejection fraction (from 32+/-7% to 35+/-5 and 39+/-7% p < 0.04) and in left ventricular enlargement as assessed echocardiographically. There were also improvements in a number of electrophysiologic parameters calculated by computerized analysis of ambulatory ECG tapes, such as heart rate variability, indicating diminished propensity to malignant arrhythmias, as confirmed by decreases in the numbers of isolated premature ventricular contractions, couplets and episodes of non-sustained ventricular tachycardia. The data suggest that chronic central sympathetic suppression with clonidine in CHF results in significant functional amelioration and improved electrophysiologic stability.

Autonomic nervous system as a target for cardiovascular drugs

1. Drugs acting within the autonomic nervous system (ANS) are of particular interest when autonomic abnormalities are implicated in the development and maintenance of various cardiovascular pathologies. For example, it has been documented that in the early stages of hypertensive disease (i.e. hyperkinetic borderline hypertension) a sympathetic hyperactivity associated with a decreased parasympathetic activity results in increased cardiac output and heart rate. 2. Several classes of drugs acting within the central, as well as the peripheral ANS, are very efficient in treating hypertensive disease. One of these classes of drugs, the second generation of centrally acting drugs, has proved beneficial in this respect because, in addition to their therapeutic efficacy, these drugs are well tolerated. 3. The central nervous system may also be the target for drugs with the potential to treat other cardiovascular diseases. Some recent experimental and clinical data supporting such new perspectives concerning idiopathic dysrhythmias, angina pectoris and congestive heart failure will be summarized.