Diuretics cardiac output effects

The principal mechanism of the hypotensive effect of diuretics (qv) is salt and fluid depletion, leading to reduction in blood volume (200,240). Acute effects lead to a decrease in cardiac output and an increase in total peripheral resistance. However, during chronic adrninistration, cardiac output and blood volume return toward normal and total peripheral resistance decreases to below pretreatment values. As a result, the blood pressure falls. The usual reduction in blood volume is about 5%. A certain degree of sustained blood volume contraction has to occur before the blood pressure decreases. The usual decrease in blood pressure achieved using a diuretic is about 20/10 mm Hg (2.7/1.3 kPa) (systoHc/diastoHc pressures. 

P-blocker therapy was ineffective in preventing coronary heart disease, cardiovascular mortality, and all-cause mortality when compared to diuretics for elderly patients (60 years of age or greater) treated for primary hypertension. Clearly, the effects of P-blockers on blood pressure are complex and difficult to ascribe to one or two mechanisms. Rather, the varied effects of negative chronotropic and inotropic properties along with reduced renin levels (Fig. 2-3) appear to result in an overall reduction in cardiac output and/or reduction in peripheral resistance. 

Patients at increased risk of NSAID-induced gastrointestinal adverse effects (e.g., dyspepsia, peptic ulcer formation, and bleeding) include the elderly, those with peptic ulcer disease, coagulopathy, and patients receiving high doses of concurrent corticosteroids. Nephrotoxicity is more common in the elderly, patients with creatinine clearance values less than 50 mL/minute, and those with volume depletion or on diuretic therapy. NSAIDs should be used with caution in patients with reduced cardiac output due to sodium retention and in patients receiving antihypertensives, warfarin, and lithium. 

It is this reduction in preload that, in some cases, is beneficial to patients experiencing heart failure or hypertension. Unlike a healthy heart, a failing heart is unable to pump all of the blood returned to it. Instead, the blood dams up and overfills the chambers of the heart. This results in congestion and increased pressures in the heart and venous system and the formation of peripheral edema. Because the failing heart is operating on the flat portion of a depressed cardiac function curve (see Figure 14.2), treatment with diuretics will relieve the congestion and edema, but have little effect on stroke volume and cardiac output. 

Acutely, diuretics lower BP by causing diuresis. The reduction in plasma volume and stroke volume associated with diuresis decreases cardiac output and, consequently, BP. The initial drop in cardiac output causes a compensatory increase in peripheral vascular resistance. With chronic diuretic therapy, the extracellular fluid volume and plasma volume return almost to pretreatment levels, and peripheral vascular resistance falls below its pretreatment baseline. The reduction in peripheral vascular resistance is responsible for the long-term hypotensive effects. Thiazides lower BP by mobilizing sodium and water from arteriolar walls, which may contribute to decreased peripheral vascular resistance. 

Hydralazine and minoxidil cause direct arteriolar smooth muscle relaxation. Compensatory activation of baroreceptor reflexes results in increased sympathetic outflow from the vasomotor center, producing an increase in heart rate, cardiac output, and renin release. Consequently, the hypotensive effectiveness of direct vasodilators diminishes over time unless the patient is also taking a sympathetic inhibitor and a diuretic. 

The molecular mechanism of diuretics acting as antihypertensive agents is not completely clear however, use of diuretics causes a significant increase in the amount of water and electrolytes excreted in urine, which leads to a reduction in the volume of extracellular fluid and plasma. This in turn leads to a reduction of cardiac output, which is the main parameter responsible for a drop in arterial blood pressure and venous blood return. Cardiac output is gradually restored, but the hypotensive effect remains, possibly because of the reduced peripheral resistance of vessels. It is also possible that diuretics somehow lower vascular activity of noradrenaline and other factors of pressure in the organism. Methods of synthesizing thiazide diuretics used for hypertension are described in the preceding chapter. Chapter 21. 

Also, as with diuretics, cardiac output is gradually restored, yet the hypotensive effect remains. Labetalol, a unique 8-adrenoblocker best suited to lower blood pressure, combines nonselective 8-adrenergic blocking action on both p - and jSj-receptors with simultaneous blockage of tti-receptors. 

Hydralazine is generally reserved for moderately hypertensive ambulatory patients whose blood pressure is not well controlled either by diuretics or by drugs that interfere with the sympathetic nervous system. It is almost always administered in combination with a diuretic (to prevent Na+ retention) and a p-blocker, such as propranolol (to attenuate the effects of reflex cardiac stimulation and hyperreninemia). The triple combination of a diuretic, -blocker, and hydralazine constitutes a unique hemodynamic approach to the treatment of hypertension, since three of the chief determinants of blood pressure are affected cardiac output (p-blocker). 

The primary indication for clonidine use is in mild and moderate hypertension that has not responded adequately to treatment with a diuretic or a p-blocker. Since clonidine causes sodium and water retention and plasma volume expansion, it generally is administered in combination with a diuretic. A vasodilator can be added to the clonidine-diuretic regimen in the treatment of resistant forms of hypertension. Such drug combinations can be quite effective, since the reflex increases in heart rate and cardiac output that result from vasodilator administration are reduced or negated by clonidine-induced decreases in heart rate and cardiac output. 

Diuretics lower blood pressure primarily by depleting body sodium stores. Initially, diuretics reduce blood pressure by reducing blood volume and cardiac output peripheral vascular resistance may increase. After 6-8 weeks, cardiac output returns toward normal while peripheral vascular resistance declines. Sodium is believed to contribute to vascular resistance by increasing vessel stiffness and neural reactivity, possibly related to altered sodium-calcium exchange with a resultant increase in intracellular calcium. These effects are... 

Increased delivery of salt to the TAL leads to activation of the macula densa and a reduction in glomerular filtration rate (GFR) by tubuloglomerular (TG) feedback. The mechanism of this feedback is secretion of adenosine by macula densa cells, which locally causes afferent arteriolar vasoconstriction. This vasoconstriction reduces GFR. Tubuloglomerular feedback-mediated reduction in GFR exacerbates the reduction that was initially caused by decreased cardiac output. Recent work with adenosine receptor antagonists (eg, rolofylline) has shown that it will soon be possible to circumvent this complication of diuretic therapy in heart failure patients. Using rolofylline with a diuretic will make it possible to produce an effective diuresis in patients with heart failure without causing renal decompensation. 

Fluid depletion may also be a serious problem during diuretic therapy. A decrease in blood volume may cause a reflex increase in cardiac output and peripheral vascular resistance because of activation of the baroreflex (see Chapter 18). This occurrence may produce an excessive demand on the myocardium, especially in patients with cardiac disease. Decreased blood volume may also activate the renin-angiotensin system, thereby causing further peripheral vasoconstriction and increased cardiac workload. Again, the effects of fluid depletion may be especially serious in patients with certain types of heart failure. 

Some diuretics have direct vasodilating effects in addition to their diuretic action. Indapamide is a nonthiazide sulfonamide diuretic with both diuretic and vasodilator activity. As a consequence of vasodilation, cardiac output remains unchanged or increases slightly. Amiloride inhibits smooth muscle responses to contractile stimuli, probably through effects on transmembrane and intracellular calcium movement that are independent of its action on sodium excretion. 

For example, because an adequate dose of hydralazine causes a significant decrease in peripheral vascular resistance, there will initially be a drop in mean arterial blood pressure, evoking a strong response in the form of compensatory tachycardia and salt and water retention (Figure 11-5). The result is an increase in cardiac output that is capable of almost completely reversing the effect of hydralazine. The addition of a B-blocker prevents the tachycardia addition of a diuretic (eg, hydrochlorothiazide) prevents the salt and water retention. In effect, all three drugs increase the sensitivity of the cardiovascular system to each other s actions. 

Prazosin, oxazosin and terazosin (see p. 73) produce a competitive block of oci adrenoceptors. They decrease peripheral vascular resistance and lower arterial blood pressure by causing the relaxation of both arterial and venous smooth muscle. These drugs cause only minimal changes in cardiac output, renal blood flow, and glomerular filtration rate. Therefore, long-term tachycardia and increased renin release do not occur. Postural hypotension may occur in some individuals. Prazosin is used to treat mild to moderate hypertension and is prescribed in combination with propranolol or a diuretic for additive effects. Reflex tachycardia and first dose syncope are almost universal adverse effects. Concomitant use of a p-blocker may be necessary to blunt the short-term effect of reflex tachycardia. 

Beta adrenergic receptor antagonists reduce cardiac output (caused by negative chronotropic and inotropic effects), decrease renin release from the kidneys, and cause smooth muscle relaxation. However, blockage may also decrease secretion of insulin from pancreatic P-cells, which limits its use in T2D. Calcium channel antagonists act on L-type voltage gated channels in the heart and blood vessels to reduce vascular resistance and arterial pressure. Diuretics are also widely used to decrease blood pressure, particularly in the elderly and hypertensive black populations. 

Increase in blood volume this occurs with any drug that reduces peripheral resistance (increases intravascular volume) or cardiac output (reduces glomerular flow) due to activation of the renin-angiotensin system. The result is that cardiac output and blood pressure rise. Adding a diuretic in combination with the other drug can prevent this compensatory effect. 

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