Norepinephrine cardiac effects

Tricyclic Antidepressants (TCAs). The TCAs have been nsed to treat ADHD for 30 or more years. Most often used are imipramine (Tofranil) and desipramine (Norpramin), mainly becanse they are the TCAs that most specihcally increase norepinephrine activity. Remember, boosting norepinephrine activity in the brain shonld improve attention. Other TCAs, namely, amitriptyline (Elavil, Endep) and nortriptyline (Pamelor), have been used, though they also increase norepinephrine activity. TCAs do offer a modest benefit for both the inattention and the hyperactivity of ADHD. In addition, they are often effective at doses mnch lower than those required to treat depression. However, their effectiveness nsnally falls short of the stimulant medications. In addition, TCAs have considerable side effects including dry mouth, constipation, drowsiness, weight gain, and adverse cardiac effects. 

The mechanisms by which 2-PAM exerts its cardiac effects have been studied in experimental animals. At least three classes of action have been attributed to the effects of altered calcium metabolism on autonomic ganglia. A sympathomimetic action of 2-PAM was postulated to explain the increase in blood pressure and the augmented myocardial contractility by one or more of the following mechanisms 2-PAM may not block the release of the endogenous compounds, but may prevent the uptake of catecholamine 1 it may stimulate the release of norepinephrine it Increases myocardial contractility by directly stimulating beta receptors and it increases blood pressure by directly stimulating alpha receptors. 5... 

Inhibits uptake of serotonin and norepinephrine quinidine-like cardiac effects... 

The Class I agents decrease excitability, slow conduction velocity, inhibit diastoHc depolarization (decrease automaticity), and prolong the refractory period of cardiac tissues (1,2). These agents have anticholinergic effects that may contribute to the observed electrophysiologic effects. Heart rates may become faster by increasing phase 4 diastoHc depolarization in SA and AV nodal cells. This results from inhibition of the action of vagaHy released acetylcholine [S1-84-3] which, allows sympathetically released norepinephrine [51-41-2] (NE) to act on these stmctures (1,2). 

Evidence from a number of systems suggests that ion flux plays a role in palytoxin action. In a wide range of systems, palytoxin effects are accompanied by a change in intracellular cation levels. For example, the influx of Na and/or Ca is associated with palytoxin-stimulated contraction of cardiac and smooth muscle, the release of norepinephrine by rat pheochromocytoma (PC12) cells, and the depolarization of excitable membranes 12—15). Palytoxin also induces K efflux from erythrocytes and thus alters ion flux in a nonexcitable membrane system as well 16-19). In both excitable and nonexcitable membranes, the ultimate action of palytoxin has been shown to be dependent on extracellular cations. The palytoxin-induced effects on smooth muscle and erythroctyes can be inhibited by removing Ca from the media, and the palytoxin-induced release of norephinephrine from PC12 cells can be blocked in Na" free media (ii, 14y 18, 20, 21)... 

The answer is local anesthetic properties it can block the initiation or conduction of a nerve impulse. It is biotransformed by plasma esterases to inactive products. In addition, cocaine blocks the reuptake of norepinephrine. This action produces CNS stimulant effects including euphoria, excitement, and restlessness Peripherally, cocaine produces sympathomimetic effects including tachycardia and vasoconstriction. Death from acute overdose can be from respiratory depression or cardiac failure Cocaine is an ester of benzoic acid and is closely related to the structure of atropine. 

The answer is b. (Kn.lzu.ng, p 5.38.) Crack is the free-base (nonsalt) form of the alkaloid cocaine. It is called crack because, when heated, it makes a crackling sound. Heating crack enables a person to smoke it the drug is readily absorbed through the lungs and produces an intense euphoric effect in seconds Use has led to seizures and cardiac arrhythmias. Some of cocaine s effects (sympathomimetic) are due to blockade of norepinephrine reuptake into presynaptic terminals it does not block receptors. Flashbacks can occur with use of LSD and mescaline but have not been associated with the use of cocaine. 

ACE inhibitors (Table 8-2) decrease angiotensin II and aldosterone, attenuating many of their deleterious effects, including reducing ventricular remodeling, myocardial fibrosis, myocyte apoptosis, cardiac hypertrophy, norepinephrine release, vasoconstriction, and sodium and water retention. 

Vasopressin causes vasoconstrictive effects that, unlike adrenergic receptor agonists, are preserved during hypoxia and severe acidosis. It also causes vasodilation in the pulmonary, coronary, and selected renal vascular beds that may reduce pulmonary artery pressure and preserve cardiac and renal function. However, based on available evidence, vasopressin is not recommended as a replacement for norepinephrine or dopamine in patients with septic shock but may be considered in patients who are refractory to catecholamine vasopressors despite adequate fluid resuscitation. If used, the dose should not exceed 0.01 to 0.04 units/min. 

Propranolol lowers blood pressure in the majority of patients with essential hypertension. These effects can be caused by a number of possible mechanisms, including lowering cardiac output, inhibiting the release of renin, lowering sympathetic release from the central nervous system, inhibiting the release of norepinephrine from sympathetic postganglionic nerves, and others. 

The effects of norepinephrine on cardiac function are complex because of the dynamic interaction of the direct effects of norepinephrine on the heart and the initiation of powerful cardiac reflexes. The baroreceptor reflexes are discussed in detail in Chapter 9. 

In a normal resting subject who is receiving no drugs, there is a moderate parasympathetic tone to the heart, and sympathetic activity is relatively low. The ventricular muscle receives little, if any, parasympathetic innervation. As the blood pressure rises in response to norepinephrine, the baroreceptor reflex is activated, parasympathetic impulses (which are inhibitory) to the heart increase in frequency, and what little sympathetic outflow there is may be reduced. Heart rate is slowed so much that the direct effect of norepinephrine to increase the rate is masked and there is a net decrease in rate. Under the conditions described, however, the impact of the reflex on the ventricles is very slight because there is no parasympathetic innervation and the preexisting level of sympathetic activity is already low. A further decrease in sympathetic activity therefore would have little further effect on contractility in this subject. Thus, a decrease in heart rate and an increase in stroke volume will occur, and cardiac output will change very little. 

The reflex nature of the bradycardia induced by parenterally administered norepinephrine can readily be demonstrated by administration of atropine, a choli-noreceptor antagonist. Atropine abolishes the compensatory vagal reflexes. Under conditions of vagal blockade, the direct cardiac stimulatory effects of norepinephrine are unmasked. There is marked tachycardia, an increase in stroke volume, and as a consequence, a marked increase in cardiac output (Fig. 10.4). 

Amphetamine is an indirectly acting adrenomimetic amine that depends for its action on the release of norepinephrine from noradrenergic nerves. Its pharmacological effects are similar to those of ephedrine however, its CNS stimulant activity is somewhat greater. Both systolic and diastolic blood pressures are increased by oral dosing with amphetamine. The heart rate is frequently slowed reflexively. Cardiac output may remain unchanged in the low- and moderate-dose range. 

Hemodynamic effects Decreased peripheral vascular resistance and blood pressure Venodilation is prominent Cardiac stimulation occurs because of cardiovascular reflexes and enhanced release of norepinephrine Similar to phenoxybenzamine Decreased peripheral vascular resistance and blood pressure Veins seem to be less susceptible to antagonism than arteries thus, postural hypotension is less of a problem Cardiac stimulation is less because release of norepinephrine is not enhanced... 

Phenoxybenzamine and phentolamine, in addition to blocking postsynaptic a-receptors, also block aj-receptors on nerves and therefore can enhance the release of norepinephrine. When norepinephrine exerts a postsynaptic action by means of -adrenoceptors (e.g., cardiac stimulation, renin release), blockade of presy-naptic a2-receptors by phenoxybenzamine and phentolamine may actually potentiate the responses. Prazosin blocks responses mediated by postsynaptic aj-receptors but has no effect on the presynaptic a2-receptors. Thus,... 

The effects of nicotine on the cardiovascular system mimic those seen after activation of the sympathoadrenal system, and they are principally the result of a release of epinephrine and norepinephrine from the adrenal medulla and adrenergic nerve terminals. These effects include a positive inotropic and chronotropic effect on the myocardium as well as an increase in cardiac output. In addition, both systohc and diastolic blood pressures are increased secondary to stimulation of the sympathoadrenal system. These effects are the end result of a summation of adrenergic and chohnergic stimulation. 

Contraindications for antipsychotic therapy are few they may include Parkinson s disease, hepatic failure, hypotension, bone marrow depression, or use of CNS depressants. Overdoses of antipsychotics are rarely fatal, except for thioridazine, which is associated with major ventricular arrhythmias, cardiac conduction block, and sudden death. For other agents gastric lavage should be attempted even if several hours have elapsed since the drug was taken, because gastrointestinal motility is decreased and the tablets may still be in the stomach. Moreover, activated charcoal effectively binds most of these drugs and can be followed by a saline cathartic. The hypotension often responds to fluid replacement or pressor agents such as norepinephrine. 

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