Isoproterenol effects

Houston JB, Wilkens HJ, Levy G. Potentiation of isoproterenol effect by ascorbic acid. Res Commun Chem Pathol Pharmacol 1976 14(4) 643-650. 

Rnard, G.A., Jensen, A. and Puckett, A.M. (1983). Hydrocortisone and isoproterenol effects on trachealis cAMP and relaxation. J. Appl. Physiol Respir. Environ. Exercise Physiol. 55, 1609-1613. 

The p agonist isoproterenol effectively decreases pulmonary artery pressure when administered intravenously in acute studies. Long-term studies with sublingual isoproterenol appear to show beneficial effects, but only in a limited number of patients. Since isoproterenol is not a selective pulmonary vasodilator, however, cardiovascular side effects are common. 

Because of the widespread nature of adrenoceptors, nonselective P-agonists can produce many undesirable side effects. Therefore, before adrenergic agonists could become widely used in the treatment of asthma, some selectivity in action was needed. Whereas epinephrine and ephedrine have significant agonist activity at both a and P adrenoceptors, isoproterenol is a selective agonist at the P receptor (39). However, isoproterenol does not distinguish between the P and receptors and it is not active orally. 

Aerosol adniinistration of isoproterenol produces a prompt (2—5 minutes) intense bronchodilatation of relatively short (1 h) duration. The lack of P2-selectivity leads, in many cases, to tachycardia and blood pressure elevation. Also, use of isoproterenol, like all other known P-agonists, results in a down-regulation, or desensitization, of P-adrenergic receptors. This desensitization is only partial, and after time (depending on dose, patient, and agent), a stable, less responsive state is achieved in which P-agonists remain effective. Isoproterenol has been widely used for many years. 

Initially, it was beheved that the abiUty of xanthines phosphodiesterase (PDF) led to bronchodilation (Fig. 2). One significant flaw in this proposal is that the concentration of theophylline needed to significantly inhibit PDE in vitro is higher than the therapeutically useful semm values (72). It is possible that concentration of theophylline in airways smooth muscle occurs, but there is no support for this idea from tissue distribution studies. Furthermore, other potent PDE inhibitors such as dipyridamole [58-32-2] are not bronchodilators (73). EinaHy, although clinical studies have shown that neither po nor continuous iv theophylline has a direct effect on circulating cycHc AMP levels (74,75), one study has shown that iv theophylline significant potentiates the increase in cycHc AMP levels induced by isoproterenol (74). 

Isoproterenol. Isoproterenol hydrochloride is an nonselective P-adrenoceptor agonist that is chemically related to NE. It mimics the effects of stimulation of the sympathetic innervation to the heart which are mediated by NE. It increases heart rate by increasing automaticity of the SA and AV nodes by increasing the rate of phase 4 diastoHc depolarization. It is used in the treatment of acute heart block and supraventricular bradyarrhythmias, although use of atropine is safer for bradyarrhythmias foUowing MI (86). 

Isoproterenol is given sublingually or by iv. It is metabolized by monoamine oxidase and catechol-0-methyltransferase in brain, Hver, and other adrenergically innervated organs. The pharmacological effects of isoproterenol are transient because of rapid inactivation and elimination. About 60% is excreted unchanged. Adverse effects using isoproterenol therapy include nervousness, hypotension, weakness, dizziness, headache, and tachycardia (86). 

The use of selective P-antagonists for treatment of CHF has included the P -blocker metoprolol (Table 1) and results of clinical trials suggest long-term beneficial effects. Selective P -antagonists have also been tested, an example of which is xamoterol [81801 -12-9], C2 H25N20, which is (i)-A/-(2-hydroxy-3-(4-hydroxyphenoxy)propylamino)ethylmorphine-4-carboxamide. Xamoterol exhibits approximately 50% of the activity of isoproterenol, and serves to provide modest inotropic effects (128,129). 

FIGURE 2.18 Inotropic and lusitropic responses of guinea pig left atria to (3-adrenoceptor stimulation. Panels A to C isometric tension waveforms of cardiac contraction (ordinates are mg tension abscissae are msec), (a) Effect of 0.3 nM isoproterenol on the waveform. The wave is shortened due to an increase in the rate of diastolic relaxation, whereas no inotropic response (change in peak tension) is observed at this concentration, (b) A further shortening of waveform duration (lusitropic response) is observed with 3 nM isoproterenol. This is concomitant with positive inotropic response (increase maximal tension), (c) This trend continues with 100 nM isoproterenol, (d) Dose-response curves for ino tropy (filled circles) and lusitropy (open circles) in guinea pig atria for isoproterenol, (e) Dose-response curves for inotropy (filled circles) and lusitropy (open circles) in guinea pig atria for the P-adrenoceptor partial agonist prenalterol. Data redrawn from [6]. 

FIGURE 2.19 Potentiation and modulation of response through control of cellular processes, (a) Potentiation of inotropic response to isoproterenol in guinea pig papillary muscle by the phosphodiesterase inhibitor isobutylmethylxanthine (IBMX). Ordinates percent of maximal response to isoproterenol. Abscissa percent receptor occupancy by isoproterenol (log scale). Responses shown in absence (open circles) and presence (filled circles) of IBMX. Data redrawn from [7], (b) Effect of reduction in calcium ion concentration on carbachol contraction of guinea pig ileum. Responses in the presence of 2.5 mM (filled circles) and l.5mM (open circles) calcium ion in physiological media bathing the tissue. Data redrawn from [8],... 

FIGURE 2.21 Effects of desensitization on inotropic responses of guinea pig atria to isoproterenol (panel a) and prenalterol (panel b). Ordinates response as a percent of the maximal reaponse to isoproterenol. Abscissae logarithms of molar concentrations of agonist (log scale). Responses shown after peak response attained (within 5 minutes, filled circles) and after 90 minutes of incubation with the agonist (open triangles). Data redrawn from [6]. 

Isoproterenol (104) is an important agent for classification because of its selective p-receptor agonist activity. It is of special interest that its chronotropic (increase in heart rate) and inotropic (increase in force of contraction) effects exceed that of epinephrine it is also used in the management of mild to moderate asthma due to its bronchodilating effect, resulting in increased vital capacity of the lungs. 

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