Kidney renal excretion

The organs of extraction are generally the liver (hepatic clearance - metabolism and biliary excretion CIh) and the kidney (renal excretion, CIr) and the values can be summed together to give an overall value for systemic clearance (Cls) ... 

Reactivity. Hemoglobin can exist ia either of two stmctural coaformatioas, corresponding to the oxy (R, relaxed) or deoxy (T, tense) states. The key differences between these two stmctures are that the constrained T state has a much lower oxygen affinity than the R state and the T state has a lower tendency to dissociate into subunits that can be filtered in the kidneys. Therefore, stabilization of the T conformation would be expected to solve both the oxygen affinity and renal excretion problems. 

Excretion is the process by which a substance leaves the body. The most common ways are via the kidneys and via the gut. Renal excretion is favored by water-soluble compounds that can be filtered (passively by the glomeruli) or secreted (actively by the tubuli) and that are collected into urine. Fecal excretion is followed by more lipid substances that are excreted from the liver into the bile, which is collected in the gut and passed out by the feces. Other routes of excretion are available through the skin and the lungs. 

Nitrogen compounds commonly determined are creatinine, urea, and uric acid. Creatinine is an end product of the energy process occurring within the muscles, and is thus related to muscle mass. Creatinine in urine is commonly used as an indicator and correction factor of dilution in urine. Creatinine in serum is an indicator of the filtration capacity of the kidney. Urea is the end product of the nitrogen luea cycle, starting with carbon dioxide and ammonia, and is the bulk compoimd of urine. The production of uric acid is associated with the disease gout. In some cases, it appears that the excess of uric acid is a consequence of impaired renal excretion of this substance. 

The maintenance of plasma volume and plasma osmolarity occurs through regulation of the renal excretion of sodium, chloride, and water. Each of these substances is freely filtered from the glomerulus and reabsorbed from the tubule none is secreted. Because salt and water intake in the diet may vary widely, the renal excretion of these substances is also highly variable. In other words, the kidneys must be able to produce a wide range of urine concentrations and urine volumes. The most dilute urine produced by humans is 65 to 70 mOsm/1 and the most concentrated the urine can be is 1200 mOsm/1 (recall that the plasma osmolarity is 290 mOsm/1). The volume of urine produced per day depends largely upon fluid intake. As fluid intake increases, urine output increases to excrete the excess water. Conversely, as fluid intake decreases or as an individual becomes dehydrated, urine output decreases in order to conserve water. 

An overall increase in sympathetic nerve activity includes an increase in sympathetic input to the kidneys. Consequently, resistance of the afferent arteriole increases, leading to a decrease in RBF. As discussed, this results in a decrease in PGC, GFR, and urine output. As such, the renal excretion of sodium and water is decreased. In other words, sodium and water are... 

Metabolic alkalosis is maintained by abnormal renal function that prevents the kidneys from excreting excess bicarbonate. 

Hypomagnesemia is usually associated with disorders of the intestinal tract or kidneys. Drugs (e.g., aminoglycosides, amphotericin B, cyclosporine, diuretics, digitalis, cisplatin) or conditions that interfere with intestinal absorption or increase renal excretion of magnesium can cause hypomagnesemia. 

Ammonia can diffuse freely into the urine through the tubule membrane, while the ammonium ions that are formed in the urine are charged and can no longer return to the cell. Acidic urine therefore promotes ammonia excretion, which is normally 30-50 mmol per day. In metabolic acidosis (e.g., during fasting or in diabetes mellitus), after a certain time increased induction of glutaminase occurs in the kidneys, resulting in increased NH3 excretion. This in turn promotes H"" release and thus counteracts the acidosis. By contrast, when the plasma pH value shifts towards alkaline values alkalosis), renal excretion of ammonia is reduced. 

III.a.4.3. Changes in renal blood flow. Blood flow through the kidney is partially controlled by the production of renal vasodilatory prostaglandins. If the synthesis of these prostaglandins is inhibited (e.g. by indomethacin), the renal excretion of lithium is reduced with a subsequent rise in serum levels. The mechanism underlying this interaction is not entirely clear, as serum lithium levels are unaffected by some potent prostaglandin synthetase inhibitors (e.g. aspirin). If an NSAID is prescribed for a patient taking lithium the serum levels should be closely monitored. 

Renal elimination of foreign compounds may change dramatically with increasing age by factors such as reduced renal blood flow, reduced glomerular filtration rate, reduced tubular secretory activity, and a reduction in the number of functional nephrons. It has been estimated that in humans, beginning at age 20 years, renal function declines by about 10% for each decade of life. This decline in renal excretion is particularly important for drugs such as penicillin and digoxin, which are eliminated primarily by the kidney. 

While essentially all ACE inhibitors have a similar mechanism of action and therefore exhibit similar efficacy in the treatment of hypertension and congestive heart failure, these drugs differ slightly in their pharmacokinetic profiles. Enalapril, lisinopril, and quinapril are excreted primarily by the kidney, with minimal liver metabolism, while the other prodrug compounds are metabolized by the liver and renally excreted. Thus, in patients with renal insufficiency, the half-life of renally excreted ACE inhibitors is prolonged. In addition, patients with impaired liver func-... 

A portion of the pharmaceutical can be excreted via the kidney, that is, renal excretion. Thus, renal excretion (Fg) can range between 0 and 1 with the latter representing a simation in which renal excretion is the only route of elimination. Renal excretion can be estimated from... 

Calcium and phosphate enter the body from the intestine. The average American diet provides 600-1000 mg of calcium per day, of which approximately 100-250 mg is absorbed. This figure represents net absorption, because both absorption (principally in the duodenum and upper jejunum) and secretion (principally in the ileum) occur. The amount of phosphorus in the American diet is about the same as that of calcium. However, the efficiency of absorption (principally in the jejunum) is greater, ranging from 70% to 90%, depending on intake. In the steady state, renal excretion of calcium and phosphate balances intestinal absorption. In general, over 98% of filtered calcium and 85% of filtered phosphate is reabsorbed by the kidney. The movement of calcium and phosphate across the intestinal and renal epithelia is closely regulated. Intrinsic disease of the intestine (eg, nontropical sprue) or kidney (eg, chronic renal failure) disrupts bone mineral homeostasis. 

Penicillin is rapidly excreted by the kidneys small amounts are excreted by other routes. About 10% of renal excretion is by glomerular filtration and 90% by tubular secretion. The normal half-life of penicillin G is approximately 30 minutes in renal failure, it may be as long as 10 hours. Ampicillin and the extended-spectrum penicillins are secreted more slowly than penicillin G and have half-lives of 1 hour. For penicillins that are cleared by the kidney, the dose must be adjusted according to renal function, with approximately one fourth to one third the normal dose being administered if creatinine clearance is 10 mL/min or less (Table 43-1). 

Clearance is a measure of the volume of plasma that is cleared of drug per unit time (see Chapter 3). The total clearance for most drugs is the sum of clearances via excretion by the kidneys and metabolism by the liver. In planning a detoxification strategy, it is important to know the contribution of each organ to total clearance. For example, if a drug is 95% cleared by liver metabolism and only 5% cleared by renal excretion, even a dramatic increase in urinary concentration of the drug will have little effect on overall elimination. 

Distribution of penicillin antibiotics is limited to extracellular fluids, but inflammation may enhance their distribution into tissues. Penicillins are actively transported in kidney, brain, and liver. Most penicillins undergo minimal hepatic metabolism and are cleared from the plasma primarily by renal excretion. Secretion of penicillins by the renal tubules results in high urine concentrations and rapid elimination from the body (50). 

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