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Renal blood flow effective

If a marker is extracted from the blood exclusively by the kidney resulting in a renal venous concentration of 0% (i.e. the arterio-venous extraction fraction is 100%), then the calculated value of the clearance of the marker (Cx) is equal to renal plasma flow. In practice, a compound, such as para-amino hippurate (PAH) with an extraction fraction of about 87%, is used. To acknowledge the fact that there is discrepancy between the PAH clearance and renal plasma flow, the term effective renal plasma flow is used when the extraction factor is not measured. In sum, renal plasma flow = effective renal plasma flow + extraction factor and renal blood flow = effective renal plasma flow + the hematocrit. [Pg.100]

Kidney Function. Prostanoids influence a variety of kidney functions including renal blood flow, secretion of renin, glomerular filtration rate, and salt and water excretion. They do not have a critical role in modulating normal kidney function but play an important role when the kidney is under stress. Eor example, PGE2 and -I2 are renal vasodilators (70,71) and both are released as a result of various vasoconstrictor stimuli. They thus counterbalance the vasoconstrictor effects of the stimulus and prevent renal ischemia. The renal side effects of NSAIDS are primarily observed when normal kidney function is compromised. [Pg.155]

Moreover, digitahs has indirect effects on the circulation, which in normal hearts results in a small increase in arterial pressure, peripheral resistance, and cardiac output (114). The effects of digitahs on the circulation of an individual experiencing congestive heart failure are much more dramatic, however. The increased cardiac output, for example, increases renal blood flow which can reheve in part the edema of CHF associated with salt and water retention (114). [Pg.129]

Verapamil (Table 1), the first slow channel calcium blocker synthesized to selectively inhibit the transmembrane influx of calcium ions into cells, lowers blood pressure in hypertensive patients having good organ perfusion particularly with increased renal blood flow. Sustained-release verapamil for once a day dosing is available for the treatment of hypertension. Constipation is a prominent side effect. Headache, dizziness, and edema are frequent and verapamil can sometimes cause AV conduction disturbances and AV block. Verapamil should not be used in combination with -adrenoceptor blockers because of the synergistic negative effects on heart rate and contractile force. [Pg.142]

Hydralazine. Hydrala2iae causes vasodilation ia all primary vascular beds and has more pronounced effects on capacitance than on resistance blood vessels. Despite the hypotension it produces, hydrala2iae iacreases renal blood flow and cardiac output. PRA iacreases with its use. Tachycardia, headache, di22iaess, and water and sodium retention are principal side effects of hydrala2iae therapy. [Pg.143]

Methybcanthine Diuretics. The mild diuretic effect of drinking coffee, from caffeine, and tea, mainly from theophylline, has been recogni2ed for along time. But the methylxanthines (Table 5) are of very limited efficacy when used as diuretics. The excretion of sodium and chloride ions are increased, but the potassium excretion is normal. Methylxanthines do not alter the urinary pH. Even though the methylxanthines have been demonstrated to have minor direct effects in the renal tubules, it is beUeved that they exert their diuretic effects through increased renal blood flow and GER (71). [Pg.210]

In the kidney, ANG II reduces renal blood flow and constricts preferentially the efferent arteriole of the glomerulus with the result of increased glomerular filtration pressure. ANG II further enhances renal sodium and water reabsorption at the proximal tubulus. ACE inhibitors thus increase renal blood flow and decrease sodium and water retention. Furthermore, ACE inhibitors are nephroprotective, delaying the progression of glomerulosclerosis. This also appears to be a result of reduced ANG II levels and is at least partially independent from pressure reduction. On the other hand, ACE inhibitors decrease glomerular filtration pressure due to the lack of ANG II-mediated constriction of the efferent arterioles. Thus, one important undesired effect of ACE inhibitors is impaired glomerular filtration rate and impaired kidney function. [Pg.9]

As to be expected from a peptide that has been highly conserved during evolution, NPY has many effects, e.g. in the central and peripheral nervous system, in the cardiovascular, metabolic and reproductive system. Central effects include a potent stimulation of food intake and appetite control [2], anxiolytic effects, anti-seizure activity and various forms of neuroendocrine modulation. In the central and peripheral nervous system NPY receptors (mostly Y2 subtype) mediate prejunctional inhibition of neurotransmitter release. In the periphery NPY is a potent direct vasoconstrictor, and it potentiates vasoconstriction by other agents (mostly via Yi receptors) despite reductions of renal blood flow, NPY enhances diuresis and natriuresis. NPY can inhibit pancreatic insulin release and inhibit lipolysis in adipocytes. It also can regulate gut motility and gastrointestinal and renal epithelial secretion. [Pg.829]

West JR, Smith HW, Chasis H. 1948. Glomemlar filtration rate, effective renal blood flow, and maximal tubular excretory capacity in infancy. J Pediatr 32 10-18. [Pg.237]

The major cause of the diuretic effect is an increase in renal blood flow and glomerular filtration rate. [Pg.236]

A decrease in blood volume or blood pressure may result in a decrease in the blood flow to the kidney. The kidney monitors renal blood flow by way of stretch receptors in the vessel walls. A decrease in renal blood flow stimulates the release of renin. The subsequent secretion of aldosterone causes retention of sodium and water and, therefore, an increase in blood volume and blood pressure back to normal. An increase in renal blood flow tends to cause the opposite effect. [Pg.134]

A substance that fulfills these criteria is para-aminohippuric acid (PAH). All of the PAH not filtered at the glomerulus is secreted by the proximal tubule. The net effect is that all of the plasma flowing through the nephrons is completely cleared of PAH. It is important to note that about 10 to 15% of the total renal plasma flow supplies regions of the kidneys that are not involved with filtration or secretion. Consequently, this plasma cannot be cleared of PAH. Therefore, the plasma clearance of PAH provides a measurement of the effective renal plasma flow, that is, the volume of plasma that actually flows through the nephrons. The ERPF is normally about 625 ml/ min. (This value is based on a renal blood flow of about 1.1 1/min and a hematocrit of about 42.)... [Pg.328]

Renal blood flow has a direct effect on GFR, which in turn has a direct effect on urine output. As RBF increases, GFR and urine output increase. Conversely, as RBF decreases, GFR and urine output decrease. Furthermore, any change in urine output affects plasma volume and blood pressure. Therefore, the regulation of RBF and GFR are important considerations. According to Ohm s law (Q = AP/R), RBF is determined by mean arterial pressure (MAP) and the resistance of the afferent arteriole (Raffart) ... [Pg.329]

Vasopressin is a potent vasoconstrictor that increases blood pressure and systemic vascular resistance. It may have several advantages over epinephrine. First, the metabolic acidosis that frequently accompanies cardiopulmonary arrest can blunt the vasoconstrictive effect of epinephrine this does not occur with vasopressin. Second, stimulation of P receptors by epinephrine can increase myocardial oxygen demand and complicate the postresuscitative phase of CPR. Vasopressin can also have a beneficial effect on renal blood flow in the kidney, causing vasodilation and increased water reabsorption. [Pg.92]

Foop diuretics (furosemide, bumetanide, torsemide) are usually necessary to restore and maintain euvolemia in HF. In addition to acting in the thick ascending limb of the loop of Henle, they induce a prostaglandin-mediated increase in renal blood flow that contributes to their natriuretic effect. [Pg.98]

The rate of total body clearance accounted for by the kidney. Its magnitude is determined by the net effects of glomerular filtration, tubular secretion and reabsorption, renal blood flow, and protein binding. [Pg.696]

Renal function Measurement of effects on urine excretion in saline loaded rats Renal dynamics Measurement of renal blood flow, GFR and clearance... [Pg.741]

The inhibition of sympathetic tone to the venous system (capacitance vessels) results in increased pooling of blood in the venous vascular bed with consequent decreased venous return to the heart and decreased cardiac output. This phenomenon is more pronounced in upright positions because of the effect of gravity. The hemodynamic effects of ganglionic blockers include decreases in cardiac output, renal blood flow, cerebral blood flow and orthostatic hypotension(20,21). [Pg.84]

See other pages where Renal blood flow effective is mentioned: [Pg.116]    [Pg.116]    [Pg.207]    [Pg.211]    [Pg.273]    [Pg.202]    [Pg.44]    [Pg.366]    [Pg.368]    [Pg.371]    [Pg.506]    [Pg.1217]    [Pg.72]    [Pg.1179]    [Pg.42]    [Pg.348]    [Pg.757]    [Pg.84]    [Pg.87]    [Pg.87]    [Pg.415]    [Pg.133]    [Pg.143]   
See also in sourсe #XX -- [ Pg.776 ]



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