Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0023890 (cirrhosis)
 42,195 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The pharmacokinetics of lansoprazole (L) after a single oral dose of 30 mg was determined in 18 healthy volunteers, 17 renal failure patients and 24 hepatic failure patients; 8 hepatitis and 16 with compensated (CC) or uncompensated (UCC) cirrhosis. In renal failure, the absorption of L was unchanged, its half-life being similar to that in healthy subjects; a small change seen in mild renal failure patients (creatinine clearance between 40 and 60 ml/min) was attributed to the age of the patients. Urinary elimination, essentially as metabolites of lansoprazole, was decreased, in relation to the degree of renal impairment. In hepatitis patients, the AUC and t1/2 of L were doubled, without any change in Cmax. In cirrhotics tmax was prolonged, the AUC was increased (P < 0.001) and there was prolongation of t1/2 (6.1 h in CC and 7.2 h in UCC compared to 1.4 h in healthy subjects). These changes resulted from a decrease in the clearance of L. There was also an increase in its sulphone metabolite (Cmax, Rm) and a decrease in the hydroxylated metabolite (Cmax, Rm) in relation to the degree of liver disease, and reflecting a decrease in hydroxylation and biliary elimination. Thus, renal failure had no effect on the pharmacokinetics of L, but severe hepatic failure caused marked changes. A repeated dosing study would be necessary to evaluate the repercussions of the possible accumulation in cirrhotic patients.
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PMID:Pharmacokinetics of lansoprazole in patients with renal or liver disease of varying severity. 829 72

As endothelin-1 (ET-1), a potent vasoconstricting peptide, may play a role in the circulatory derangement and renal impairment in cirrhosis, the aim of the present study was to investigate plasma concentrations of ET-1 in different vascular beds in relation to clinical and biochemical parameters of liver function. Median brachial venous ET-1 concentrations were substantially higher in patients with cirrhosis (3.40 pg/ml, range: 1.25-7.84, n = 24) than in controls (1.53 pg/ml, range: 0.78-2.12, n = 11) (P < 0.00005). In patients with cirrhosis ET-1 was directly correlated to serum creatinine (r = 0.70, P < 0.0001) and aspartate aminotransferase (r = 0.44, P < 0.03) and negatively correlated to serum sodium (r = -0.58, P < 0.003). In patients who underwent liver vein catheterization (n = 8), no significant differences were found in ET-1 plasma concentration between the liver, renal, or femoral veins on the one hand and the femoral artery on the other (P > 0.1), indicating no major net elimination or release in the liver, kidney or lower limb. A significant negative correlation was found between systolic and diastolic blood pressures on the one hand and circulating ET-1 on the other (r = -0.71, P < 0.05). In conclusion, circulating ET-1 is elevated in cirrhosis and related to markers of systemic circulation and renal function, thus suggesting a role for ET-1 in the circulatory derangement and nephropathy in cirrhosis. Locations of major net elimination or release of ET-1 were not identified.
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PMID:Elevated circulating plasma endothelin-1 concentrations in cirrhosis. 830 Oct 63

The purpose of this study was to determine whether duplex ultrasound (US) can allow detection of early impairment of renal function in patients with hepatic cirrhosis. The authors calculated the pulsatility index (PI) and resistive index (RI) by using duplex US in 17 patients with cirrhosis and ascites but with normal renal function (group A), in 16 patients with cirrhosis but no ascites (group B), in 20 with chronic hepatitis (group C), in six with peritoneal carcinomatosis (group D), and in 16 healthy control subjects (group E). All patients had normal renal function on the basis of blood urea nitrogen and serum creatinine values. PI and RI were higher (P < .001) in group A patients than in others. Cirrhotic patients with ascites had renal vasoconstriction even in the absence of clinically apparent renal impairment and full-blown hepatorenal syndrome. Impaired renal perfusion plays a key role in sodium and fluid accumulation in patients with liver disease. On the basis of these results, duplex US is useful in pathophysiologic and clinical studies in such patients.
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PMID:Abnormal renovascular impedance in patients with hepatic cirrhosis: detection with duplex US. 847 8

Thirty-nine patients underwent CT examination 15 to 30 min after abdominal angiography with ioxaglate. Gallbladder opacification was observed in 15 patients in the absence of clinical evidence of renal impairment. Among them, 14 patients revealed liver cirrhosis or chronic hepatitis, and one patient showed severe fatty liver on CT. The amount of contrast medium used varied from 70 ml to 310 ml (mean 180 ml). There was no significant relationship between visualization of the gallbladder and the total dose of ioxaglate or presence of liver dysfunction, which indicated that gallbladder opacification was not a rare phenomenon on CT shortly after abdominal angiography with a normal dose of ioxaglate. Gallbladder opacification on CT examination shortly after abdominal angiography shows that the hepatobiliary tract is important in the excretion of ioxaglate.
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PMID:[Hepato-biliary excretion of water-soluble iodinated contrast medium shortly after abdominal angiography]. 858 44

The single-dose pharmacokinetics of nefazodone (NEF) and its metabolites hydroxynefazodone (HO-NEF) and m-chlorophenylpiperazine (mCPP) were examined in 12 healthy younger subjects < or = 55 years of age (YNG), 12 elderly subjects > or = 65 years of age (ELD), 12 patients with biopsy proven hepatic cirrhosis (HEP) and 12 patients with moderate renal impairment (REN), ClCR 20-60 ml.min-1. The study was of parallel group design, with each of the four subject groups receiving escalating single oral doses of 50, 100 and 200 mg of nefazodone at 1 week intervals. Serial blood samples for pharmacokinetic analysis were collected for 48 h following each dose and plasma samples were assayed for NEF, HO-NEF and mCPP by a validated HPLC method. Single oral doses up to 200 mg of nefazodone were well tolerated by all subjects. Maximum plasma levels of NEF and HO-NEF were generally attained within 1 h after administration of nefazodone. HO-NEF and mCPP plasma levels were about 1/3 and < 1/10 those of NEF, respectively. There were no apparent gender-related pharmacokinetic differences in any group of subjects. NEF and HO-NEF pharmacokinetics were dose dependent in all four subject groups; a superproportional increase in AUC and an increase in t1/2 with increasing dose was obtained, indicative of nonlinear pharmacokinetics. Relative to normal subjects, elderly and cirrhotic subjects exhibited increased systemic exposure to NEF and HO-NEF, as reflected by AUC, at all doses of nefazodone; subjects with moderate renal impairment did not. Elderly and cirrhotic patients may require lower doses of NEF to achieve and maintain therapeutic effectiveness.
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PMID:Single-dose pharmacokinetics of nefazodone in healthy young and elderly subjects and in subjects with renal or hepatic impairment. 866 99

The pharmacokinetics of fluvoxamine, a selective serotonin reuptake inhibitor (SSRI) with antidepressant properties, are well established. After oral administration, the drug is almost completely absorbed from the gastrointestinal tract, and the extent of absorption is unaffected by the presence of food. Despite complete absorption, oral bioavailability in man is approximately 50% on account of first-pass hepatic metabolism. Peak plasma fluvoxamine concentrations are reached 4 to 12 hours (enteric-coated tablets) or 2 to 8 hours (capsules, film-coated tablets) after administration. Steady-state plasma concentrations are achieved within 5 to 10 days after initiation of therapy and are 30 to 50% higher than those predicted from single dose data. Fluvoxamine displays nonlinear steady-state pharmacokinetics over the therapeutic dose range, with disproportionally higher plasma concentrations with higher dosages. Plasma fluvoxamine concentrations show no clear relationship with antidepressant response or severity of adverse effects. Fluvoxamine undergoes extensive oxidative metabolism, most probably in the liver. Nine metabolites have been identified, none of which are known to be pharmacologically active. The specific cytochrome P450 (CYP) isoenzymes involved in the metabolism of fluvoxamine are unknown. CYP2D6, which is crucially involved in the metabolism of paroxetine and fluoxetine, appears to play a clinically insignificant role in the metabolism of fluvoxamine. The drug is excreted in the urine, predominantly as metabolites, with only negligible amounts ( < 4%) of the parent compound. Fluvoxamine shows a biphasic pattern of elimination with a mean terminal elimination half-life of 12 to 15 hours after a single oral dose; this is prolonged by 30 to 50% at steady-state. Plasma protein binding of fluvoxamine (77%) is low compared with that of other SSRIs. Fluvoxamine pharmacokinetics are substantially unaltered by increased age or renal impairment. However, its elimination is prolonged in patients with hepatic cirrhosis. Fluvoxamine inhibits oxidative drug metabolising enzymes (particularly CYP1A2, and less potently and much less potently CYP3A4 and CYP2D6, respectively) and has the potential for clinically significant drug interactions. Drugs whose metabolic elimination is impaired by fluvoxamine include tricyclic antidepressants (tertiary, but not secondary, amines), alprazolam, bromazepam, diazepam, theophylline, propranolol, warfarin and, possibly, carbamazepine. Fluvoxamine is a second generation antidepressant that selectively inhibits neuronal reuptake of serotonin (5-hydroxytryptamine; 5-HT). Fluvoxamine exhibits antidepressant activity similar to that of the tricyclic antidepressants, but has a somewhat improved tolerability profile, particularly with respect to a lower incidence of anticholinergic effects and reduced cardiotoxic potential. However, gastrointestinal adverse effects, especially nausea, are seen more frequently with fluvoxamine than with the tricyclic antidepressants. Fluvoxamine does not have an asymmetric carbon in its structure (fig. 1) and therefore does not exist as optical isomers. For this reason, the potentially confounding problem of stereoisomerism does not arise with fluvoxamine.
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PMID:Overview of the pharmacokinetics of fluvoxamine. 884 17

Nisoldipine, a calcium antagonist of the dihydropyridine type, is the active ingredient of the controlled release nisoldipine coat-core (CC) formulation. In humans, the absorption from nisoldipine CC occurs across the entire gastrointestinal tract with an increase in bioavailability in the colon because of the lower concentrations of metabolising enzymes in the distal gut wall. Although nisoldipine is almost completely absorbed, its absolute bioavailability from the CC tablet is only 5.5%, as a result of significant first-pass metabolism in the gut and liver. Nisoldipine is a high-clearance drug with substantial interindividual and relatively lower intraindividual variability in pharmacokinetics, dependent on liver blood flow. Nisoldipine is highly (> 99%) protein bound. Its elimination is almost exclusively via the metabolic route and renal excretion of metabolites dominates over excretion in the faeces. Although nisoldipine is administered as a racemic mixture, its plasma concentrations are almost entirely caused by the eutomer as a result of highly stereoselective intrinsic clearance. Nisoldipine CC demonstrates linear pharmacokinetics in the therapeutic dose range and its steady-state pharmacokinetics are predictable from single dose data. Steady-state is reached with the second dose when the drug is given once daily and the peak-trough fluctuations in plasma concentration is minimal. Plasma-concentrations of nisoldipine increase with age. Careful dose titration according to individual clinical response is recommended in the elderly. Nisoldipine CC should not be used in patients with liver cirrhosis, though dosage adjustments in patients with renal impairment are not necessary. Inter-ethnic differences in its pharmacokinetics are not evident. Owing to inhibition of metabolising enzymes, a small dosage adjustment decrement for nisoldipine CC may be required when it is given in combination with cimetidine. Concomitant ingestion of nisoldipine with grapefruit juice should be avoided. Inducers of cytochrome P450 (CYP) 3A4, e.g. rifampicin (rifampin) and phenytoin should not be combined with nisoldipine CC, as they may reduce its bioavailability and result in a loss of efficacy. The concomitant use of other drugs which may produce marked induction or inhibition of CYP3A4 is contraindicated. Concomitant intake of the CC tablet with high fat, high calorie foods resulted in an increase in the maximum plasma concentrations of nisoldipine. The 'food-effect' can be avoided by administration of the CC tablet up to 30 minutes before the intake of food [corrected]. Plasma concentrations of nisoldipine are related to its antihypertensive effect via a maximum effect model. Nisoldipine CC once daily produce reductions in blood pressure which are maintained over 24 hours in the absence of relevant effects on heart rate.
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PMID:Clinical pharmacokinetics of nisoldipine coat-core. 978 33

Within a 6-year period from January 1991 to December 1996, 19 patients with Salmonella choleraesuis bacteremia were enrolled for clinical and microbiological analysis. Young children, the elderly and patients with hematological malignancy (36.8%), liver cirrhosis (26.3%), systemic lupus erythematosus (10.5%), chronic renal impairment (10.5%), and peptic ulcer (10.5%) were at high risk of this infection. The ratio of male to female was 3:1. Three cases (15.8%) were nosocomially acquired. Fever (89.5%), chills (57.9%) and anorexia (52.6%) were the most common clinical manifestations. Seven patients (36.8%) presented no gastrointestinal manifestations. Normal white blood cell count was noted in seven patients (36.8%), and neutropenia caused by underlying diseases or severe infection was found in six cases (31.6%). Various types of metastatic focal infections were found, such as septic arthritis, cutaneous infection, spontaneous bacterial peritonitis, and pneumonia. The severe immunocompromised status of patients and the high virulence of this pathogen may contribute to the high case fatality rate (21%). Higher resistance rate to commonly used antimicrobial agents was noted in ampicillin (94.7%), chloramphenicol (89.5%), and TMP/SMZ (63.8%). All strains of S. choleraesuis were susceptible to third-generation cephalosporins and fluoroquinolones. Generally, S. choleraesuis bacteremia should be taken into account in the differential diagnosis of sepsis in immunocompromised patients, even without gastrointestinal manifestations. The third-generation cephalosporins and fluoroquinolones may be the first choice for treatment of this invasive infections.
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PMID:Salmonella choleraesuis bacteremia in southern Taiwan. 1033 Jul 99

High levels of nitric oxide are thought to be the cause of some of the complications associated with decompensated end-stage liver disease. To assess nitric oxide metabolism in cirrhotic patients, we measured the levels of nitric oxide metabolites (nitrosohemoglobin, methemoglobin, nitrate, and nitrite) in normal subjects, in patients with decompensated cirrhosis, in patients with renal failure (model for impaired NO metabolites excretion), and in patients with mononitrates-treated anginal syndrome (model for exogenous nitric oxide). When compared to controls, patients with decompensated cirrhosis exhibited elevated levels of nitrate only. A significant increase of nitrate was also noted in patients receiving exogenous nitrates, whereas patients with impaired excretion had significantly elevated levels of both nitrite and nitrate. In conclusion, nitric oxide metabolism in patients with decompensated cirrhosis is similar to that of patients receiving nitric oxide from an exogenous source. Renal impairment, whether alone or associated with cirrhosis, causes a change in nitric oxide metabolism. These findings may have clinical implications for nitrates treatment in patients with decompensated cirrhosis.
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PMID:Nitric oxide metabolites in decompensated liver cirrhosis. 1048 15

Ascites is the most frequent major complication of liver cirrhosis. Even if a significant decrease in renal clearances may be observed in the first stages of chronic active hepatitis, true renal impairment, often with the typical signs of hepatorenal syndrome, only occurs in patients with ascites, especially when tense and refractory. Experimental and clinical data suggest the presence of primary sodium and water retention, perhaps as a consequence of an increase in intrahepatic hydrostatic pressure. The abnormal sodium retention leads to plasma volume expansion, followed by decreased peripheral vascular resistances and increased cardiac output. This second stage concords with the peripheral arterial vasodilation theory, characterized by an increase in total blood volume, but with a decrease in effective arterial blood volume. This discrepancy leads to the activation of sympathetic nervous and renin-angiotensin-aldosterone systems. This activation, while protective against splanchnic and systemic vasodilation, provoked by the increased availability of nitric oxide and other vasodilating substances, induces renal vasoconstriction. This phenomenon can be considered as the basis of the progressive renal failure that leads to hepatorenal syndrome, favored by progressive exhaustion of the renal autacoid vasodilating substances. The first therapeutic approach to ascites is sequential and based on diuretic administration. Subsequently, paracentesis with albumin infusion is carried out, as well as transjugular intrahepatic portosystemic shunting, surgical portosystemic shunting, and liver transplantation: these procedures are essential for the treatment of hepatorenal syndrome.
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PMID:Pathogenetic factors and clinical elements in ascites and hepatorenal syndrome during liver cirrhosis. 1063 19


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