Disposition,Bioavailability, and Serum Protein Binding of Pentachlorophenol in the B6C3F1 Mouse

The toxicokinetics of pentachlorophenol (PCP) were studied in B6C3F1 mice, a strain in which PCP was previously found to be carcinogenic. In a crossover design, doses of 15 mg/kg were given intravenously (bolus) and orally (gastric intubation) to six animals. Concentrations of PCP in blood, urine, and feces were measured by capillary gas chromatography with electron-capture detection. After intravenous administration, the values of clearance and volume of distribution were 0.057 ± 0.007 L/hr/kg and 0.43 ± 0.06 L/kg, respectively. These two parameters exhibited low intermouse variability (coefficients of variation <14%). The elimination half-life was 5.2 ± 0.6 hr. After oral administration, the PCP peak plasma concentration (28 ± 7 µg/ml) occurred at 1.5 ± 0.5 hr and absorption was complete (bioavailability = 1.06 ± 0.09). The elimination half-life was 5.8 ± 0.6 hr. Only 8% of the PCP dose was excreted unchanged by the kidney. PCP was primarily recovered in urine as conjugates. A portion of the dose was recovered in urine as the mutagen, tetrachlorohydroquinone (5%) (TCHQ), and its conjugates (15%). For both PCP and TCHQ, sulfates accounted for 90% or more of the total conjugates (glucuronides and sulfates).     

Pharmacokinetic studies on the selectiveβ 1-receptor antagonist metoprolol in man

The pharmacokinetics of ³H-metoprolol, a new selective ₁-receptor antagonist, have been studied in healthy volunteers by following the plasma concentrations and the urinary excretion of the unchanged compound and its total radioactive metabolites after oral and intravenous administration. The compound was rapidly and completely absorbed after oral administration, and about 40% of the dose reached the systemic circulation. The estimated half-life of the absorption process was 10 min. Metoprolol was extensively distributed to extravascular tissues, with the half-life of the distribution phase close to 12 min. About 95% of the dose was excreted in the urine within 72 hr, mainly in metabolized form. The elimination halflife of the compound was close to 3 hr as was also the half-life of the total metabolites after oral administration. After intravenous administration, the elimination half-life of the metabolites was raised to 5 hr, indicating that the route of administra tion might influence the metabolic pathways of the parent compound.     

Pharmacokinetics and pharmacodynamics of azosemide after intravenous and oral administration to rats: Absorption from various GI segments

Azosemide, 5, 10, 20, and 30 mg/kg, was administered both intravenously and orally to determine the pharmacokinetics and pharmacodynamics of azosemide in rats (n=7–12). The absorption of azosemide from various segments of GI tract and the reasons for the appearance of multiple peaks in plasma concentrations of azosemide after oral administration were also investigated. After intravenous (iv) dose, the pharmacokinetic parameters of azosemide such ast _1/2, MRT, V_SS, CL, CL_R, and CL_NR were found to be dose-dependent in the dose ranges studied. The percentages of the iv dose excreted in 8-hr urine as azosemide, MI (a metabolite of azosemide), glucuronide of azosemide, and glucuronide of MI—expressed in terms of azosemide—were also dose-dependent in the dose ranges studied. The data above suggest saturable metabolism of azosemide in rats. The measurements taken after the iv administrations such as the 8 hr urine output, the total amount of sodium and chloride excreted in 8-hr urine per 100 g body weight, and diuretic, natriuretic, kaluretic, and chloruretic efficiencies were also shown to be dose-dependent. However, the total amount of potassium excreted in 8-hr urine per 100 g body weight was dose-independent. Similar dose-dependency was also observed following oral administration. Azosemide was absorbed from all regions of GI tract studied and approximately 93.5, 79.1, 86.1, and 71.5% of the doses (5, 10, 20, and 30 mg/kg, respectively) were absorbed between 1 and 24 hr after oral administration. The appearance of multiple peaks after oral administration is suspected to be due mainly to the gastric emptying pattern. The percentages of azosemide absorbed from the GI tract as unchanged azosemide for up to 24 hr after oral doses of 5, 10, 20, and 30 mg/kg were significantly different with doses (decreased with increasing doses), suggesting that the problem of azosemide precipitating in acidic gastric juices or dissolution may have at least partially influenced the absorption of azosemide after oral administration. This paper was supported in part by Non-Directed Research Fund, Korea Research Foundation, 01-F-0124, 1994. This paper is taken from a dissertation submitted by Sun H. Lee to the Graduate School, Seoul National University, in partial fulfillment of Doctor of Philosophy Degree requirements.     

Pharmacokinetics in man of theN-acetylated metabolite of proeainamide

The pharmacokinetics of N-acetylprocainamide (NAPA) have been studied in three normal subjects who received 500 mg of this compound by timed intravenous injection. Plasma N APA concentrations and urine excretion were measured by quadrupole mass fragmentography, and a three- compartment pharmacokinetic model was used for data analysis. NAPA elimination half-life and total distribution volume averaged 6.0 hr and 1.38 liters/kg, respectively. Renal excretion of unchanged NAPA accounted for 81% of its elimination, and the mean renal NAPA clearance was 179 ml/min. Approximately 2% of the injected NAPA was deacetylated to procainamide. The fate was not determined of 17% of the NAPA that was estimated to have been eliminated during the 16- hr study period.     

3H羟基斑蝥胺的药物代谢动力学研究

将氚标记的羟基斑蝥胺在大鼠体内研究了药物代谢动力学。所得血药浓度-时间数据依一定程序在709电子计算机上拟合曲线,并计算有关参数。结果表明,静脉注射后符合二房室开放型模型,其药代动力学参数为:t1/2α0.067hr,t1/2β2.208hr,V_d(面积)1.237l/kg,V₁0.264l/kg,K_el1.470 hr^-1,清除率0.388l/hr/kg。灌胃后可以单室开放型模型描述,其药代动力学参数为:K_α2.990hr^-1,K_el0.257hr^-1,V_d1.603l/kg,t1/22.693hr,t_max0.90hr,C_max0.745μg/ml,F94.15%。尚将本药以静脉和灌胃两种途径给药后直接观察在大鼠体内的组织分布和在尿粪胆汁中的排泄,结果表明本药分布广,主要经肾排泄,且排泄较快,与药代动力学分析结果相一致。     

Pharmacokinetic studies in man of the selective beta1-adrenoceptor agonist,prenalterol

Summary The pharmacokinetics of prenalterol, a selective ₁-adrenoceptor agonist, has been studied in healthy subjects, by following the plasma concentration and urinary excretion of the unchanged compound and its total radioactive metabolites after oral and intravenous administration. Each of six healthy subjects received a single i. v. dose (2.5 mg) and three oral doses (2.5, 5.0 and 10 mg) of prenalterol. The oral dose was administered as a solution. Three of the subjects received the intravenous and oral doses of 2.5 mg as tritiated drug. Prenalterol was rapidly and completely absorbed after oral administration. The peak plasma concentration was attained after about 0.5 h. About 25% of prenalterol reached the systemic circulation. Prenalterol was extensively distributed to extravascular tissues with a half-life of the distribution phase close to 7 min. About 90% of the dose was excreted in urine within 24 h irrespective of the route of administration, indicating complete absorption of the drug. On average 60% of the i. v. and 13% of the oral doses were excreted as unchanged drug. The elimination half-life of the compound was 1.8 h, and the decline in the plasma concentration of the metabolites indicated a slower elimination rate than for the unchanged drug. Dose-dependent kinetics were not observed after the oral doses examined.     

Pharmacokinetics of sulfisoxazole compared in humans and two monogastric animal species

The pharmacokinetic profile of sulfisoxazole was studied and compared in dogs, swine, and humans. The trial was conducted over a 72-hr period after intravenous administration and a 96-hr period after oral administration in dogs and swine. In humans, the trial was conducted over an 8-hr period after oral administration. A two-compartment model system was used to define the pharmacokinetic profile. The mean half-lives for the distribution phase were 4.08, 1.30, and 0.56 hr in dogs, swine, and humans, respectively. For the elimination phase, the mean half-lives were 33.74, 46.39, and 7.40 hr in dogs, swine, and humans, respectively. The mean volume of the central compartment was approximately the same in dogs and swine, 10.6 and 10.5 liters, respectively. Humans had a smaller volume of distribution, 7.7 liters. The steady-state volumes of distribution were 17.2, 30.3, and 16.2 liters in dogs, swine, and humans, respectively. Dogs and swine excreted 42.2 and 30.7%, respectively, of the intravenous dose and 29.4 and 18.3%, respectively, of the oral dose. The bioavailability was 69.8% in dogs and 100.0% in swine. The fraction of drug bound ranged from 30 to 50% in dogs, 40 to 60% in swine, and 25 to 40% in humans.     

Pharmacokinetics and pharmacodynamics of bumetanide after intravenous and oral administration to rats: Absorption from various GI segments

Bumetanide, 2, 8, and 20 mg/kg, was administered both intravenously and orally to determine the pharmacokinetics and pharmacodynamics of bumetanide in rats (n=10–12). The absorption of bumetanide from various segments of GI tract and the reasons for the appearance of multiple peaks in plasma concentrations of bumetanide after oral administration were also investigated. After iv dose, the pharmacokinetic parameters of bumetanide, such ast _1/2 (21.4, 53.8 vs. 127 min),CL (35.8, 19.1 vs. 13.4 ml/min per kg),CL _NR (35.2, 17.8 vs. 12.6 ml/min per kg) andV _SS (392, 250 vs. 274 ml/kg) were dose-dependent at the dose range studied. It may be due to the saturable metabolism of bumetanide in rats. After iv dose, 8-hr urine output per 100g body weight increased significantly with increasing doses and it could be due to significantly increased amounts of bumetanide exreted in 8-hr urine with increasing doses. The total amount of sodium and chloride exreted in 8-hr urine per 100g body weight also increased significantly after iv dose of 8 mg/kg, however, the corresponding values for potassium were dose-independent. After oral administration, the percentages of the dose excreted in 24-hr urine as unchanged bumetanide were dose-independent. Bumetanide was absorbed from all regions of GI tract studied and approximately 43.7, 50.0, and 38.4% of the orally administered dose were absorbed between 1 and 24 hr after oral doses of 2, 8, and 20 mg/kg, respectively. Therefore, the appearance of multiple peaks after oral administration could be mainly due to the gastric emptying patterns. The percentages of bumetanide absorbed from GI tract as unchanged bumetanide for up to 24 hr after oral doses of 2, 8, and 20 mg/kg (96.2, 95.4 vs. 98.2%) were not significantly different, suggesting that the problem of precipitation of bumetanide in acidic gastric juices or dissolution may not contribute significantly to the absorption of bumetanide after oral administration. Urine output per 100g body wt increased at oral doses of 8 and 20 mg/kg. This work was supported in part by SNU Development Foundation, 1991.     

Absorption,metabolism and elimination of strophanthus glycosides in man

Summary In 33 healthy male volunteers, given a single oral and intravenous dose of cymarin (k-strophanthin-), k-strophanthoside (k-strophanthin-) and ouabain (g-strophanthin), enteral absorption and renal excretion of these glycosides and their metabolites were investigated by radioimmunoassay and HPLC. Cymarin was absorbed at 47% of the given dose. After intravenous injection 46% and after oral administration 21% of the given dose, i.e. the total amount as detected by radioimmunoassay which consisted of the unchanged glycoside and its metabolites, were excreted by the kidneys mainly as conjugated metabolites. The half-life of elimination, calculated from the total excreted amount was 13 h (i.v.) and 23 h (p.o.), respectively. k-Strophanthoside was absorbed at 16% of the given dose. After i.v.-injection 73% of the given dose was excreted by the kidneys with a half-life of elimination of 99 h. From this total amount about 70% was excreted as the unchanged drug, the remaining 30% as various metabolites. After oral administration 11% of the given dose were excreted with a half-life of elimination of 22 h. 80% of this amount consisted mainly of conjugated k-strophanthoside and conjugated metabolites as k-strophanthin-, cymarin, k-strophanthidin, cymarol and k-strophanthidol. Only 6% was excreted as the unchanged drug. Ouabain was absorbed after oral administration to a minimum of 1.4%. Given intravenously a total renal excretion of 33% of the given dose with a half-life of elimination of 23 h was measured. Of this 80% was unchanged ouabain. The remaining 20% seemed to be conjugated metabolites which could not be exactly identified.Supported by the Deutsche Forschungsgemeinschaft, Sonderforschungsbereich Düsseldorf (SFB 30)     

Metabolism and disposition of naltrexone in man after oral and intravenous administration

The metabolism and elimination of [15, 16,-3H2]naltrexone was studied in man after oral and intravenous administration. The same metabolites, although in varying proportions, were observed in both cases; conjugated naltrexone and conjugated and unconjugated 6 beta-naltrexol were the major metabolites observed in plasma, urine, and feces. 2-Hydroxy-3-O-methyl-6 beta-naltrexol was found in minor quantities. Naltrexone was almost completely absorbed after oral administration. After oral and intravenous administration of naltrexone, about 60% of the dose was recovered in the urine in 48 and 72 hr, respectively. The route of administration did not significantly affect urinary clearance values obtained for unconjugated or conjugated naltrexone and 6 beta-naltrexol. The route of administration significantly affected terminal plasma half-life values obtained for unconjugated naltrexone (2.7 hr, iv; 8.9 hr, oral), but had little effect on comparable values obtained for total drug, conjugated naltrexone, and unconjugated and conjugated 6 beta-naltrexol. Combined gas chromatography-mass spectrometry was used to validate the presence of naltrexone, 6 beta-naltrexol, and 2-hydroxy-3-O-methyl-6 beta-naltrexol in urine.     

Comparison of metabolic pharmacokinetics of baicalin and baicalein in rats

Baicalin and baicalein, a flavone glucuronide and its aglycone, are bioactive constituents of Scutellariae Radix with various beneficial activities. We have characterized and compared the metabolic pharmacokinetics of baicalin and baicalein in rats. Baicalein was administered intravenously and orally to rats, and baicalin was orally administered. An HPLC method was used to determine the concentration of baicalein before and after hydrolysis using beta-glucuronidase/sulfatase. The pharmacokinetic parameters were calculated by using WINNONLIN. Unpaired Student's t-test was used for statistical comparison. The result showed that after intravenous administration of baicalein, 75.7% of the dose was circulating as its conjugated metabolites. After oral administration of baicalein, absorption of baicalein itself was negligible, whereas the glucuronides/sulfates of baicalein were predominant in the plasma. When compared with intravenous bolus administration with dose correction, the absolute absorption was 40%. When baicalin was administered orally, glucuronides and sulfates of baicalein were exclusively circulating in the plasma. The relative absorption for baicalin was 65% when compared with baicalein. Profound differences of serum profile and pharmacokinetics were observed between oral baicalein and baicalin. Baicalin demonstrated significantly later time to peak concentration (t(max)) and lower peak serum concentration (C(max)) of baicalein conjugated metabolites than baicalein, indicating baicalin was absorbed more slowly and to a lesser extent than baicalein.     

The influences of the route of administration on the metabolism and excretion of bitolterol, a new bronchodilator, in the rat.

1. [3H]Bitolterol, an ester prodrug to colterol (N-t-butyl-arterenol), when administered orally, was excreted mostly in the urine; approx. equal amounts of 3H were found in urine and faeces after intraperitoneal or intravenous injection. 2. Half the dose was excreted in the bile following parenteral administration, while only a small amount of radioactivity was found in bile after oral dosage. The biliary-excreted material consisted mainly of glucuronides, for all routes of administration. 3. The glucuronides of colterol and 3-O-methyl-colterol were excreted in urine after oral administration of bitolterol. In addition to the glucuronides, free colterol and 3-O-methyl-colterol were excreted in urine following parenteral administration. 4. A part of bitolterol was hydrolysed to colterol in rat stomach, and bitolterol was more rapidly hydrolysed to colteral with homogenates of intestinal mucosa than with stomach homogenates in vitro.     

Pharmacokinetics and metabolism of the antiinflammatory agents S-H 766 in man]

Blood and plasma levels as well as urinary and fecal excretion were measured in humans after oral administration of radioactively labelled 4-[j-(2'-fluorobiphenylyl)]-4-hydroxycrotonic acid (S-H 766 MO). The radioactivity in the plasma reaches maximum values of about 10 mug eq./ml 1 to 2 h after application with either form. After repeated administration good agreement is found between the plasma levels measured and those simulated according to the pharmacokinetic parameters obtained after single application. The S-H 766 metabolites were investigated in blood and urine. The substance was found to undergo considerable metabolism, only approximately 2% being excreted in the urine unchanged. The conjugates, which constitute over 60% of the radioactivity of the urine, consist mainly of glucuronides and sulfates. The structure of the aglycones shows that the metabolism occurs along two pathways, by beta-oxidation of the aliphatic side chain into aryl acetic acids and by hydroxylation of the aromatic nucleus to phenolic compounds. It must be assumed that these biotransformations take place both simultaneously and successively.     

Enantioselective Pharmacokinetics of dl-threo-Methylphenidate in Humans

A definitive enantioselective pharmacokinetic evaluation of dl-threo-methylphenidate (MPH) was carried out in 11 healthy volunteers, all of whom received, in a randomized crossover design, three oral administrations of MPH: immediate release (IR), slow release (SR), and SR chewed before swallowing (CH). In addition, all subjects received MPH intravenously (IV) on a separate occasion. Both plasma and urine samples were collected for up to 16 hr after each drug administration. Significant enantioselective differences were found in pharmacokinetic parameters such as CL, MRT, Vd_ss, AUC₀ , and t_1/2. A profound distortion of the enantiomeric ratio for MPH (d 1) was evident in all plasma samples harvested after oral administration. After IV MPH, however, there was no significant distortion in the plasma d/1 ratio until 1.5 hr after dosing, whereafter there was a divergence of the plasma levels of the enantiomers. After oral administration of dl-MPH, the absolute bioavailability (F) of d-MPH was 0.23 and that of l-MPH was 0.05. There were no significant differences in renal clearance for d- or l-MPH after oral or IV administration, although the fraction of the dose excreted unchanged in the urine was significantly greater after IV MPH. These data suggest that enantioselective differences in the pharmacokinetics of oral MPH are the result of enantioselectivity in presystemic metabolism rather than in renal excretion, such that l-MPH is preferentially converted into l-ritalinic acid. Finally, it was found that chewing the slow release formulation led to a pharmacokinetic profile very similar to that of MPH-IR, suggesting that MPH-SR should not be prescribed for children who chew tablets.     

The biotransformation of [14C]lormetazepam in dogs,rabbits, rats and rhesus monkeys

1. After oral or intravenous doses (0.25?mg/kg) of [¹⁴C]lormetazepam to rats, most of the urinary radioactivity was associated with polar components and < 1% dose was excreted as unconjugated lormetazepam. About 30% of an oral dose was excreted in rat bile as a conjugate of lormetazepam and about 50% dose as polar metabolites. Plasma also contained mainly polar metabolites, and unchanged lormetazepam represented at most 10% of total plasma radioactivity after an oral dose.

2. Almost all the radioactivity in dog, rhesus monkey and rabbit urine, after oral or intravenous doses (0.5–0.7?mg/kg) of [¹⁴C]lormetazepam, was associated with conjugated material. In the dog there were only two major components, conjugates of lormetazepam and lorazepam (N-desmethyl-lormetazepam) which accounted for about 24% and 14% respectively of the oral dose in the 0–24?h urine. The same two conjugated components were also present in dog bile. Conjugated lormetazepam was the only major component in monkey and rabbit urine and accounted for about 60% dose in the 0–24?h urine of each species, while conjugated lorazepam accounted for only about 0.5% and 4% respectively.

3. Dog and monkey plasma contained mostly conjugated material after oral and intravenous doses (0.05–0.07?mg/kg of [¹⁴C]lormetazepam. Dog plasma after an oral dose contained conjugates of both lormetazepam and lorazepam with peak concn. at 1?h of 130 and 47 ng/ml respectively. Concn. of these conjugates in plasma declined with apparent terminal half-lives of about 17 and 27?h respectively after oral doses, and 13?h in both cases after intravenous doses. Conjugated lormetazepam was the only major component in monkey plasma representing a peak concn. of 180 ng/ml at 1?h after an oral dose, and declined with an apparent terminal half-life of about 11?h after oral or intravenous doses.

4. Lormetazepam crosses the placental ‘barrier’ of rabbits: its concn. in the foetus were similar to those in maternal plasma after intravenous doses.     

Pharmacokinetics and absolute bioavailability of carteolol,a new β-adrenergic receptor blocking agent

Summary The pharmacokinetics and absolute bioavailability of a new nonselective -adrenoreceptor blocking agent, carteolol, were investigated after administration of single intravenous and oral doses to eight normal volunteers. Plasma and urine drug concentrations were measured by an HPLC method. The pharmacokinetic parameters after intravenous dosing were obtained by a two-compartment analysis: elimination or -phase t_1/2 4.7±0.3 h; Vc, 0.74±0.101/kg; Vd, 4.05±0.48 l/kg; Cl, 10.13±0.94 ml/min/kg; Cl_R, 6.56±0.58 ml/min/kg; and Cl_NR, 3.57±0.40 ml/min/kg. The absolute bioavailability obtained from plasma data was 83.7±8.0%, which was consistent with that derived from analysis of urine of 82.7±4.2%. The amounts excreted unchanged in urine up to 48 h after the intravenous and oral doses were 65.0±1.5% and 53.8±3.2% of the administered doses, respectively. The t_1/2 for removal of the drug derived from plasma and urine findings after intravenous and oral dosing were similar, which indicates that the main route of elimination of carteolol is via the kidneys. As the Cl_R of carteolol exceeded the Cl of creatinine there may be renal tubular secretion of the drug.     

Absorption and Disposition of a Selective Aldosterone Receptor Antagonist,Eplerenone, in the Dog

Purpose. The present study was conducted to characterize the pharmacokinetics of eplerenone (EP), a selective aldosterone receptor antagonist, and its open lactone ring form in the dog. Methods. Pharmacokinetic studies of EP were conducted in dogs following i.v., oral, and rectal dosing (15 mg/kg) and following intragastric, intraduodenal, intrajejunal, and intracolonic dosing (7.5 mg/kg). Results. After oral administration, the systemic availability of EP was 79.2%. Systemic availabilities following administration via other routes were similar to that following oral administration. The half-life and plasma clearance of EP were 2.21 hr and 0.329 l/kg/hr, respectively. Plasma concentrations of the open lactone ring form were lower than EP concentrations regardless of the route of administration. The C-14 AUC in red blood cells was approximately 64% and 68% of the plasma AUC for i.v. and oral doses. Percentages of the dose excreted as total radioactivity in urine and feces were 54.2% and 40.6%, respectively, after i.v. administration, and 40.7% and 52.3%, respectively, after oral administration. The percentages of the dose excreted in urine and feces as EP were 13.7% and 2.5%, respectively, after i.v. administration, and 2.1% and 4.6% after oral administration, respectively. Approximately 11% and 15% of the doses were excreted as the open form following i.v. and oral doses. Conclusions. EP was rapidly and efficiently absorbed throughout the gastrointestinal tract, resulting in a good systemic availability. The drug did not preferentially accumulate in red blood cells. EP was extensively metabolized; however, first-pass metabolism after oral and rectal administration was minimal. EP and its metabolites appear to be highly excreted in the bile.     

Pharmacokinetics of o-nitroanisole in Fischer 344 rats

The pharmacokinetics and metabolism of o-nitroanisole (ONA) were studied in male Fischer 344 rats. Three dose levels of [14C]ONA (5.0, 50, or 500 mg/kg) were administered orally to rats and daily excreta were analyzed for 14C. Since the highest dose altered the urinary excretion rate of ONA, a dose of 25 mg/kg was used for subsequent pharmacokinetic studies. Following a single 25 mg/kg iv dose of [14C]ONA, blood, tissues, and excreta were collected at times ranging from 15 min to 7 days. Urinary excretion accounted for 82% of the dose by 24 hr and 86% by 7 days. Fecal excretion was 7.5% in 24 hr and 9.0% by 7 days. Fifteen min after ONA administration, most of the 14C content was found in muscle (20%), skin (10%), adipose tissue (6.8%), and blood (6.5%). All other tissues contained less than 5% of the dose. Within 8 hr, less than 1% of the dose was present in any tissue. The initial elimination t1/2 for 14C in all tissues was 1-2 hr and the terminal t1/2 was approximately 4 days. The elimination of parent ONA from blood followed first order biphasic elimination kinetics (initial t1/2 = 30 min; terminal t1/2 = 2.2 hr). Parent ONA was rapidly eliminated from all other tissues in a monophasic manner (t1/2 = 15 min to 2 hr). Skin and fat demonstrated an uptake phase prior to the elimination of parent. Only 0.5% of the dose was excreted as ONA in the urine. Urinary metabolites of ONA were predominantly conjugated compounds (63% as sulfates; 11% as glucuronides).     

Studies on flavonoid metabolism Absorption and metabolism of (+)-catechin in man

Oral administration of (+)-catechin to man results in absorption, rapid metabolism and excretion of the compound largely within 24 hr. Eleven (+)-catechin metabolites are detected in the urine. The major phenolic acid metabolite is m-hydroxyphenylpropionic acid and the major lactone metabolites include δ-(3,4-dihydroxyphenyl)-γ-valerolactone and δ-(3-hydroxyphenyl)-γ-valerolactone. The phenolic compounds in the urine are excreted in both free and conjugated forms, including their glucuronides and to a lesser degree their ethereal sulphates. Absorption of (+)-catechin occurs in the gastrointestinal tract as early as 6 hr after the oral administration of the compound and appears in the urine together with several unidentified metabolites both in the free and conjugated forms. The amount excreted within 24 hr is about 7.5 per cent of the administered dose. The stomach gastric juice do not degrade (+)-catechin in vitro but prolonged contact with the gastric juice causes some polymerisation of the compound. Unchanged (+)-catechin amounts to about 18.6 per cent of the administered dose in the 48 hr faecal collection. In addition, m-hydroxyphenylpropionic acid and one unidentified metabolite are detected in the faeces. The rise in phenolic levels in the blood occurs as early as 6hr after the oral administration of (+)-catechin and parallel to the rise in urinary excretion of phenolic compounds.     

Pharmacokinetics of Cefixime in Children with Urinary Tract Infections after a Single Oral Dose

Abstract: The pharmacokinetics of cefixime, a third-generation broad-spectrum cephalosporin, were determined following administration of a 8 mg/kg single oral dose of cefixime suspension to six children with urinary tract infections, ages from 6 to 13 years and weights from 17 to 60 kg. Blood samples for determination of plasma cefixime concentrations were obtained for up to 12 hr and complete urine collections were obtained for urinary excretion of unchanged parent drug for up to 24 hr after administration. Plasma and urine concentrations of cefixime were determined using a reversed phase HPLC assay and pertinent pharmacokinetic parameters were estimated by model-independent standard methods. Mean peak plasma concentration was 4.04 ug/ml and was reached after 3.2 hr. The mean area under the plasma concentration-time curve was 33.07 ug.hr/ml and the mean elimination half-life was 3.91 hr. The mean apparent total clearance was 4.74 ml/min./kg and about 15% of the dose administered was recovered unchanged in urine. In conclusion, the estimated pharmacokinetic values of cefixime were comparable to those observed in healthy adult subjects based on equivalent mg/ kg doses. Plasma and urine concentrations of the drug were well above the reported minimal plasma and urinary concentrations for most common urinary tract pathogens for up to 12 and 24 hr after administration, respectively.