Antihypertensive drugs sympathetic nervous system

The more usual methods which have been employed for testing guanidine derivatives as potential antihypertensive drugs depend on detecting some form of interference with the sympathetic nervous system. This.subject has also been reviewed recently in considerable detail [202], and only those methods which have been, or could be, widely applied to elucidating structure-activity relationships are described here. 

The drugs discussed in this section are primarily, but not exclusively, those that have a depressant effect somewhere in the sympathetic nervous system. The diuretics that have definite antihypertensive properties (as well as beneficial effects in CHF) are dealt with separately in this chapter. 

Hydralazine (apresoline) causes direct relaxation of arteriolar smooth muscle, possibly secondary to a fall in intracellular Ca concentrations. The drug does not dilate epicardial coronary arteries or relax venous smooth muscle. Hydralazine-induced vasodilation is associated with powerful stimulation of the sympathetic nervous system, likely due to baroreceptor-mediated reflexes, which results in increased heart rate and contractility, increased plasma renin activity, and fluid retention all of these effects counteract the antihypertensive effect of hydralazine. Although most of the sympathetic activity is due to a baroreceptor-mediated reflex, hydralazine may stimulate NE release from sympathetic nerve terminals and augment myocardial contractility directly. Most of hydralazine s effects are confined to the cardiovascular system the decrease in blood pressure after administration is associated with a selective decrease in vascular resistance in the coronary, cerebral, and renal circulations, with a smaller effect in skin and muscle. Because of preferential dilation of arterioles, postural hypotension is not common, and hydralazine lowers blood pressure equally in the supine and upright positions. 

The basis for the antihypertensive activity of the ganglionic blockers lies in their ability to block transmission through autonomic ganglia (Fig. 20.2C). This action, which results in a decrease in the number of impulses passing down the postganglionic sympathetic (and parasympathetic) nerves, decreases vascular tone, cardiac output, and blood pressure. These drugs prevent the interaction of acetylcholine (the transmitter of the preganglionic autonomic nerves) with the nicotinic receptors on postsynaptic neuronal membranes of both the sympathetic and parasympathetic nervous systems. 

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