The pharmacokinetics of single doses of metoclopramide in renal failure

Summary The pharmacokinetics of metoclopramide have been studied after intravenous and oral dosing (10 mg) to 6 patients with chronic renal failure. The mean terminal half-life was 13.9 h after intravenous and 14.8 h after oral administration. Total body clearance after i. v. dosing was 16.7 l/h. Oral bioavailability was 71.8%. In comparison to previous studies on normal subjects these results indicate that clearance of metoclopramide in renal failure is approximately 30% of normals. This difference is not accounted for by the change in renal clearance and suggests impaired metabolism or an alteration in enterohepatic circulation of metoclopramide in renal failure.     

The pharmacokinetics of metoclopramide in man with observations in the dog.

1 The pharmacokinetics of metoclopramide have been studied in eight normal male volunteers. 2 The mean plasma beta half-life was 156.7 min after i.v. administration of 10 mg metoclopramide. 3 After oral dosing of 10 mg the mean half-life was 196.6 min and after 20 mg 317.5 min (P less than 0.05). 4 Bioavailability of a 10 mg oral dose of metoclopramide varied between 32 and 97%. 5 A major urinary metabolite was metoclopramide-N-4-sulphate and the amounts of conjugates appearing in urine to 24 h correlated significantly with the bioavailability. 6 In the dog the metabolic fate of metoclopramide is different to man with conjugation being a minor metabolic pathway. The half-life in the dog does not appear to be dose dependent. 7 The wide differences in bioavailability of metoclopramide in man may contribute to the unpredictable occurrence of side effects.     

Pharmacokinetics of ranitidine in patients with renal failure

The pharmacokinetics of ranitidine were studied in ten patients with renal failure (creatinine clearance, 6-54 mL/min) after intravenous (IV) (50 mg) and oral doses (150 mg). After oral administration, peak plasma concentrations of 378-808 ng/mL were obtained in two to six hours. Plasma concentrations declined very slowly and concentrations greater than 100 ng/mL were obtained for 16 to 20 hours after the dose. The elimination half-life following oral administration was 8.5 +/- 2.8 hours (standard deviation [SD]), and the bioavailability of ranitidine was 43.3% +/- 10.5%. After IV administration, the elimination half-life, plasma clearance, renal clearance, and volume of distribution were 7.0 +/- 1.0 hours, 170 +/- 38 mL/min, 36.0 +/- 25.0 mL/min, and 1.3 +/- 0.4 L/kg, respectively. About 20% of the IV dose and 9% of the oral dose were recovered unchanged in urine. There was a significant correlation between the renal clearance of ranitidine and creatinine clearance (r = .74, P less than .05) after IV administration. The elimination half-life in patients with renal insufficiency is about three times greater than that reported in the literature for healthy subjects. Similarly, the plasma clearance in these patients is about 20% of that reported in healthy subjects. The results indicate that ranitidine elimination is appreciably reduced in renal failure and that an adjustment of dose in patients with renal failure is warranted. A dose of 75 mg bid may be adequate in maintaining the therapeutic plasma concentrations that are required for adequate H2-blocking activity.     

High-dose morphine and methadone in cancer patients. Clinical pharmacokinetic considerations of oral treatment

Several clinical studies have shown oral morphine and methadone to be effective in the treatment of intractable pain in patients with malignant disease. Recent pharmacokinetic studies have confirmed the rationale for regular administration of oral morphine and methadone but have revealed marked interindividual differences in the kinetics and metabolism which must be considered when titrating the oral dose according to the individual patient's need. Oral absorption of morphine in patients with malignant diseases is rapid, with peak plasma concentrations occurring at 20 to 90 minutes. Predose steady-state concentrations bear a constant relationship to dose, but vary considerably between individuals. The oral bioavailability is approximately 40% with marked patient-to-patient variations as a result of differences in presystemic elimination. The reported values for the volume of distribution range from 1.0 to 4.7 L/kg. Plasma protein binding is about 30%. The elimination half-life varies between 0.7 and 7.8 hours. Plasma clearance is approximately 19 ml/min/kg (5 to 34 ml/min/kg) and mostly accounted for by metabolic clearance. Studies in a few patients with malignant diseases treated regularly with daily doses of oral morphine ranging from 20 to 750mg indicate a linear relationship between the dose and trough concentration of morphine. Long term treatment with 10- to 20-fold increase of the oral dose over a period of 6 to 8 months does not seem to change the kinetics of oral morphine. The plasma concentrations of the main metabolite, morphine-3-glucuronide (M3G), exceed those of the parent drug by approximately 10-fold after intravenous administration and by 20-fold after oral administration. The relationship between the area under the plasma concentration-time curve (AUC) of morphine and the AUC of morphine-3-glucuronide remains constant during the development of tolerance upon long term treatment with increasing doses. Renal disease causes a significant increase in the mean plasma concentrations of morphine for 15 minutes after its administration, while mean values of terminal half-life and total body clearance are within the normal range. However, the glucuronidated polar metabolite morphine-3-glucuronide rises rapidly to high concentrations which persist for several days. Chronic liver disease causes an increase in the bioavailability of oral morphine but no, or only a slight reduction in the intravenous clearance. The elimination half-life and volume of distribution are within the normal range.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pharmacokinetics of metoclopramide in patients with liver cirrhosis.

The pharmacokinetics of metoclopramide were investigated after intravenous and oral administration in eight patients with severe alcoholic cirrhosis and in eight healthy volunteers. As a consequence of a 50% lower clearance (0.16 +/- 0.07 vs 0.34 +/- 0.09 l h-1 kg-1, plasma drug concentrations and the half-life of metoclopramide were greater in patients following both routes of drug administration. Volume of distribution (3.1 +/- 0.8 vs 3.4 +/- 1.2 l kg-1) and absolute bioavailability (79 +/- 19 vs 84 +/- 15%) were similar in the two groups. The adverse effects of metoclopramide observed in patients with marked hepatic impairment are likely to result from increased accumulation of the drug as a result of impaired clearance. Consequently a reduction in dose of 50% is recommended in patients with severe liver cirrhosis.     

Pharmacokinetic characterization of the antiarrhythmic drug diprafenone in man

The pharmacokinetics of the antiarrhythmic drug diprafenone have been investigated in 6 healthy volunteers following single intravenous (50 mg) and oral doses (50 and 150 mg). Diprafenone was mainly eliminated by metabolism in the liver. Following i.v. infusion of 50 mg diprafenone, the terminal half-life of elimination was 1.50 h, the volume of distribution at steady-state was 1.23 l.kg-1, and the free fraction in plasma was 1.68%. Mean total plasma clearance was 741 ml.min-1.70 kg-1, which approaches normal liver blood flow after correction for the blood/plasma concentration ratio. Thus, diprafenone can be classified as a high extraction drug. Following oral administration, a dose-dependent increase in bioavailability from 10.9 (50 mg dose) to 32.5% (150 mg dose) was observed. The data suggest that diprafenone is subject to saturable hepatic first-pass metabolism.     

Pharmacokinetics of high-dose metoclopramide in cancer patients

The introduction of new cytotoxic drug regimens has been associated with an increase in the incidence and severity of adverse effects. This in turn has highlighted the need for more effective adjuvant therapy. The use of metoclopramide for the prophylaxis of nausea and vomiting, in high intravenous doses (50 to 1000 mg), has become established since 1981. As a lipid-soluble drug, metoclopramide has a large volume of distribution. The reported mean values after high doses range between 2.8 and 4.6 L/kg. The mean values for total body clearance and terminal half-life range from 0.31 to 0.69 L/kg/h and from 4.5 to 8.8 hours, respectively. The values of these pharmacokinetic parameters are essentially similar to those obtained after conventional doses (less than 50mg). Pharmacokinetic parameters appear unaffected by age, although no high-dose study has been conducted in children. Bodyweight is apparently correlated with clearance. An influence of renal function indices on terminal half-life and clearance has been shown, which is rather surprising since renal clearance accounts for only 20% of the total clearance. No thorough investigations exist which examine the influence of hepatic disease, cancer type and cytotoxic drug regimen on the disposition of metoclopramide. A relationship between dose (or concentration) and therapeutic or adverse effects of metoclopramide is outlined. The therapeutic benefit of high doses (up to 14 mg/kg) may be dependent on age, and on the combination of cytotoxic drugs. The advantages of high doses of metoclopramide are most apparent when the drug is used as protection against the adverse effects of high doses of cisplatin (greater than 60 mg/m2). Despite considerable pharmacokinetic variability, intravenous administration of high doses of metoclopramide is relatively safe due to its large therapeutic index.     

Pharmacokinetics, bioavailability and ECG response of verapamil in patients with liver cirrhosis.

1 The pharmacokinetics, bioavailability and ECG response of verapamil was investigated in seven patients with liver cirrhosis and compared with six normal subjects, using stable labelled techniques whereby both the intravenous and oral dose are given simultaneously. 2 After intravenous administration, plasma concentrations were much higher in the patient group such that the total plasma clearance was reduced from a mean of 1258 ml/min in normals to 616 ml/min in the patient group (P less than 0.0025). The apparent volume of distribution nearly doubled (6.76 v 12.05 l/kg, P less than 0.025) and the terminal half-life was prolonged four fold (3.7 v 14.2 h, P less than 0.001). 3 Given orally, the peak plasma concentration was higher and occurred earlier in the liver cirrhotic patients. The absolute bioavailability more than doubled (22.0% normals v 52.3% liver cirrhotics, P less than 0.001) and apparent oral clearance was reduced to only 20% of normal (6.38 v 1.30 l/min, P less than 0.001). 4 The delta P-R interval in the patient group lagged behind the plasma concentration, in contrast to normal subjects. The maximum effect was much greater in the patients (15.4 v 41.6% increase, P less than 0.005) and persisted for a longer period of time. The slope of the plasma concentration-response curve was the same as in normals after intravenous administration. Plasma protein binding remained unchanged. 5 It is recommended that in liver cirrhotic patients the intravenous dose of verapamil be halved and the oral dose decreased by a factor of five in order to prevent untoward effects. As well as a steady-state plasma concentration will not be reached until approximately 2 days after the beginning of therapy.     

Disposition of single oral doses of butylated hydroxytoluene in man and rat

The kinetics and metabolism of butylated hydroxytoluene (BHT) in man and rats have been compared. Single oral doses of 200, 63 or 20 mg BHT/kg body weight were administered to rats and a single oral dose of 0.5 mg/kg body weight was ingested by human volunteers (non-smoking males). In rats, kinetic parameters (area under the plasma concentration-time curve, plasma BHT peak levels) showed a dose-dependent increase. Plasma BHT levels after oral administration were about four times higher than those that have been reported for another synthetic food antioxidant, butylated hydroxyanisole (BHA; Verhagen et al., Fd Chem. Toxic. 27, 151–158). This may be a reflection of a smaller volume of distribution for BHT, since there were no differences in plasma elimination half-life or plasma clearance between BHT and BHA. In man, the mean plasma concentration-time profile after oral BHT intake was well below the BHT profiles observed for rats and closely followed plasma BHA kinetics in man. In rats, the simultaneous administration of BHT (200 mg/kg body weight) and BHA (200 mg/kg) significantly decreased the absorption of BHT from the gastro-intestinal tract in the first few hours after treatment; the plasma kinetics of BHA were not influenced by the simultaneous administration of BHT. In human female volunteers no alterations in plasma BHT or BHA profiles were seen after the simultaneous ingestion of BHT (0.25 mg/kg body weight) and BHA (0.25 mg/kg). Rats excrete about 10% of an oral dose of 200 mg BHT/kg as unchanged BHT in the faeces, whereas in man no BHT could be detected in the faeces. Urinary excretion of (un)conjugated 3,5-di-tert-butyl-4-hydroxybenzoic acid (BHT-COOH) accounts for only a small percentage of the administered dose in both rats and humans. It is concluded that the plasma BHT concentrations reached after the administration of a single medium to high dose of BHT to rats or a single low dose to man are very different.     

The pharmacokinetics of a new benzamide drug clebopride, in the rat and the dog

After intravenous, intramuscular and oral administration of clebopride in the rat and the dog its apparent volume of distribution is high (1.6-3.2 1 kg-1) and it has a longer biological half-life than metoclopramide in both species. High clearance values and concentrations of metabolites in plasma after oral administration indicate that the drug is subjected to an extensive first pass metabolism in the rat. Thus, clebopride administered orally gives relatively low concentrations in the systemic circulation in rats even though it is rapidly absorbed. The metabolic processes appear to become saturated at high doses which is reflected in dose-dependent kinetics. Linear kinetics were observed in the dog, although enterohepatic recycling could occur.     

The pharmacokinetics of cimetidine and its sulphoxide metabolite in patients with normal and impaired renal function.

1 The pharmacokinetics of cimetidine and its sulphoxide metabolite was studied after a single intravenous dose of 200 mg cimetidine in nine patients with normal renal function and ten patients with severe renal failure on regular haemodialysis and during continuous oral cimetidine treatment in ten patients with normal renal function and 31 patients with different degrees of renal failure. 2 In normal renal function a mean of 47.3% of the single intravenous dose was excreted as unchanged drug and 12.8% as cimetidine sulphoxide. The mean plasma elimination half-life (T1/2) of cimetidine was 2.0 h and of cimetidine sulphoxide 1.7 h. 3 In severe renal failure a mean of 2.2% of the single intravenous dose was excreted as unchanged drug and 0.5% as cimetidine sulphoxide. The mean plasma T1/2 of cimetidine was 3.9 h. The plasma concentrations of the sulphoxide metabolite increased successively with time after dosing and no elimination phase was observed still 9 h after dose. The mean non-renal clearance of cimetidine was 210 ml/min and lower than in normal renal function, suggesting decreased metabolism of cimetidine in uraemia. 4 During continuous oral cimetidine treatment in patients with normal renal function and in patients g and no elimination phase was observed still 9 h after dose. The mean non-renal clearance of cimetidine was 210 ml/min and lower than in normal renal function, suggesting decreased metabolism of cimetidine in uraemia. 4 During continuous oral cimetidine treatment in patients with normal renal function and in patients g and no elimination phase was observed still 9 h after dose. The mean non-renal clearance of cimetidine was 210 ml/min and lower than in normal renal function, suggesting decreased metabolism of cimetidine in uraemia. 4 During continuous oral cimetidine treatment in patients with normal renal function and in patients with different degrees of renal failure given reduced doses of cimetidine the plasma concentrations of the sulphoxide metabolite were higher with decreasing renal function. The mean plasma T1/2 of cimetidine was 3.1 h in mild renal dysfunction (creatinine clearance 50-75 ml/min) and 4.5 h in severe renal failure (creatinine clearance 5-15 ml/min) and of cimetidine sulphoxide 5.3 and 14.4 h respectively. 5 Toxicity studies of cimetidine sulphoxide may be needed to assess if high plasma concentrations of the sulphoxide metabolite in severe renal failure are of clinical significance.     

Absorption, distribution, metabolism, and excretion of ximelagatran, an oral direct thrombin inhibitor, in rats, dogs, and humans.

The absorption, metabolism, and excretion of the oral direct thrombin inhibitor, ximelagatran, and its active form, melagatran, were separately investigated in rats, dogs, and healthy male human subjects after administration of oral and intravenous (i.v.) single doses. Ximelagatran was rapidly absorbed and metabolized following oral administration, with melagatran as the predominant compound in plasma. Two intermediates (ethyl-melagatran and OH-melagatran) that were subsequently metabolized to melagatran were also identified in plasma and were rapidly eliminated. Melagatran given i.v. had relatively low plasma clearance, small volume of distribution, and short elimination half-life. The oral absorption of melagatran was low and highly variable. It was primarily renally cleared, and the renal clearance agreed well with the glomerular filtration rate. Ximelagatran was extensively metabolized, and only trace amounts were renally excreted. Melagatran was the major compound in urine and feces after administration of ximelagatran. Appreciable quantities of ethyl-melagatran were also recovered in rat, dog, and human feces after oral administration, suggesting reduction of the hydroxyamidine group of ximelagatran in the gastrointestinal tract, as demonstrated when ximelagatran was incubated with feces homogenate. Polar metabolites in urine and feces (all species) accounted for a relatively small fraction of the dose. The bioavailability of melagatran following oral administration of ximelagatran was 5 to 10% in rats, 10 to 50% in dogs, and about 20% in humans, with low between-subject variation. The fraction of ximelagatran absorbed was at least 40 to 70% in all species. First-pass metabolism of ximelagatran with subsequent biliary excretion of the formed metabolites account for the lower bioavailability of melagatran.     

Clinical pharmacokinetics of trospium chloride

Trospium chloride, a quaternary amine with anticholinergic properties, is used for the treatment of overactive bladder with symptoms of urge urinary incontinence, urgency and urinary frequency. The pharmacokinetics of trospium chloride have been investigated in healthy volunteers, in patients with renal and hepatic impairment, and in those with symptoms of overactive bladder, after oral, intravenous and intravesical administration.After oral administration, absorption of the hydrophilic trospium chloride is slow and incomplete. Peak plasma concentrations (Cmax) of approximately 4 ng/mL are reached 4-5 hours after administration of a 20 mg immediate-release preparation. The mean bioavailability is approximately 10% and decreases by concomitant food intake (to a mean of 26% of the fasting area under the plasma concentration-time curve [AUC]). Trospium chloride displays dose proportional increases in AUC and Cmax after a single dose within the clinically relevant dose range (20-60 mg). The mean volume of distribution is approximately 350-800 L. The drug is minimally (mean approximately 10%) metabolised to spiroalcohol by hydrolysis, is 50% plasma protein bound and does not cross the blood-brain barrier. Urinary excretion of the parent compound plays a major role in the disposition of the drug, with a mean renal clearance of 29 L/h (accounting for approximately 70% of total clearance) and a mean elimination half-life ranging from 10 to 20 hours. Elimination of the drug is slowed in patients with renal insufficiency, and population pharmacokinetic modelling has demonstrated that drug clearance is correlated with serum creatinine concentration. Thus, dose reduction is needed in patients with severe renal impairment (i.e. creatinine clearance < 30 mL/min).To date, no clinically relevant pharmacokinetic drug-drug interactions have been identified; the drug does not bind to any of the drug metabolising cytochrome P450 enzymes.The pharmacokinetics of the drug are compatible with twice-daily administration. A once-daily schedule may also be appropriate, but this regimen needs formal clinical evaluation.     

Toxicokinetics of bromodichloroacetate in B6C3F1 mice

The oral and i.v. elimination kinetics were investigated for bromodichloroacetate (BDCA), a haloacetate found in drinking water. The BDCA was administered at a dose of 5, 20 and 100 mg kg-1 to B6C3F1 mice and appears to distribute to the total body water with a mean volume of distribution of 427 +/- 79 ml kg-1. It is subject to first-pass hepatic metabolism with a range of bioavailabilities of 0.28-0.73. A mean terminal half-life of 1.37 +/- 0.21 h. was calculated from the two lower doses of both i.v. and oral administration. Non-linear behavior was exhibited at doses greater than 20 mg kg-1, with a much higher than expected area under the curve (AUC), a decrease in total body clearance (CL(b)) and an increase in the terminal half-life to 2.3 h at the highest dose. The average CL(b) was 220 ml h(-1) kg-1 for the lower two doses but decreased to 156 ml h(-1) kg-1 at the high dose. The BDCA is primarily eliminated by metabolism, with only 2.4% of the parent dose being recovered in the urine at the high dose. The unbound renal clearance, as calculated from the high dose, was 15.0 ml h(-1) kg-1. The BDCA is moderately bound to plasma proteins (f(u) = 0.28) and preferentially distributes to the plasma with a blood/plasma ratio of 0.88.     

Clinical pharmacokinetics of bretylium

Bretylium is a class III antiarrhythmic agent which is used for the management of serious and refractory ventricular tachyarrhythmias. It exhibits a complex pharmacokinetic profile which is poorly understood. The drug is poorly absorbed following oral administration, and its oral bioavailability is in the region of 18 to 23%. Peak plasma concentrations occur at 1 to 9 hours after oral ingestion, and following oral doses of 5 mg/kg average 76 ng/ml, which is 28-fold lower than those achieved after equivalent intravenous doses. Approximately 75% of a bretylium dose is absorbed within 24 hours of intramuscular administration. Peak plasma concentrations occur at 30 to 90 minutes after intramuscular administration and range from 670 to 1500 ng/ml in subjects receiving 4 mg/kg. Bretylium is negligibly bound to plasma proteins (1-6%). Although drug tissue concentrations have not been reported in humans, high values for the apparent volume of distribution suggest extensive tissue binding. In animals, bretylium is progressively taken up by the myocardium over a period of 12 hours, and at 12 hours after bolus administration, myocardial concentrations exceed plasma concentrations 6 to 12 times. It is also avidly taken up by adrenergic nerves in animals. Bretylium is almost entirely cleared by the renal route and its total body clearance is closely correlated with renal clearance. Available data suggest that bretylium exhibits a complex pharmacokinetic profile which has been described by a 3-compartment model in subjects receiving intravenous dosing. The terminal elimination half-life ranges from 7 to 11 hours following oral, intramuscular and intravenous administration, and renal clearance is about 600 ml/min after intravenous administration.(ABSTRACT TRUNCATED AT 250 WORDS)     

The pharmacokinetics of yohimbine in man

Summary The kinetic disposition of yohimbine was examined in eight young male subjects following a single oral dose of 10 mg yohimbine hydrochloride. The drug was rapidly absorbed (absorption half-time 0.17±0.11 h) and rapidly eliminated from the plasma (elimination half-life 0.60±0.26 h). This clearance of yohimbine from plasma was constant over approximately 10 elimination half-lives, suggesting that distribution into a second pharmacokinetically distinct compartment was not responsible for the rapid decline in plasma yohimbine levels. Urinary excretion and the partitioning of the drug into red blood cells (RBC) was investigated. In the 24 h following oral administration of the drug, virtually no yohimbine was eliminated in the urine (0.35±0.50% of the administered dose). Furthermore, only 20% of blood-borne yohimbine was located in RBC. These results suggest that yohimbine is eliminated primarily through metabolism since the rapid plasma clearance of yohimbine was not the result of renal elimination or sequestration by RBC.     

Pharmacokinetic profile of lesogaberan (AZD3355) in healthy subjects: a novel GABA(B)-receptor agonist reflux inhibitor

Objective: The aim of this study was to evaluate the pharmacokinetic profile of lesogaberan in healthy subjects after single oral and intravenous administration of ¹⁴C-labeled lesogaberan and non-¹⁴C-labeled lesogaberan.Study Design: This was an open-label, single-center, randomized, two-way crossover, phase I study.Participants: Ten healthy male subjects took part in the study.Intervention: Volunteers were randomized to receive a single dose of either orally dosed (100 mg) or intravenously infused (20 mg) non-¹⁴C-labeled lesogaberan, and then orally (100 mg) or intravenously (20 mg) administered ¹⁴C-labeled lesogaberan in a crossover design. Treatment periods were separated by a washout period of at least 7 days.Main Outcome Measures Analyses of the rate and route of excretion, dose recovery, area under the plasma concentration versus time curve (AUC), AUC to the last quantifiable concentration, maximal plasma concentration (C_max), time to C_max, the apparent elimination half-life, bioavailability, total clearance, renal clearance, fraction of the bioavailable dose excreted unchanged in the urine, cumulative amount of drug excreted unchanged in urine, and the apparent volume of distribution at steady state of lesogaberan.Results: Lesogaberan was rapidly and extensively absorbed from the gastrointestinal tract and C_max was achieved within 1–2 hours of oral dosing. The terminal half-life of lesogaberan was between 11 and 13 hours. Renal clearance accounted for approximately 22% of total body clearance. Based on the recovery of administered radioactivity, approximately 84% of the dose was excreted into the urine either as the parent compound or as water-soluble metabolite(s). There were no safety concerns raised during the study.Conclusion: Orally administered lesogaberan is rapidly absorbed with high bioavailability and the majority of the dose is excreted by the kidneys either as the parent compound or as metabolites. The major elimination pathway for lesogaberan in man is metabolism.     

The pharmacokinetics of a new benzamide drug,clebopride, in the rat and the dog

After intravenous, intramuscular and oral administration of clebopride in the rat and the dog its apparent volume of distribution is high (1·6–3·2 1 kg^?1) and it has a longer biological half-life than metoclopramide in both species. High clearance values and concentrations of metabolites in plasma after oral administration indicate that the drug is subjected to an extensive first pass metabolism in the rat. Thus, clebopride administered orally gives relatively low concentrations in the systemic circulation in rats even though it is rapidly absorbed. The metabolic processes appear to become saturated at high doses which is reflected in dose-dependent kinetics. Linear kinetics were observed in the dog, although enterohepatic recycling could occur.     

The effects of chronic renal insufficiency on the pharmacokinetics of doxycycline in man

The pharmacokinetics as well as erythrocyte and plasma protein binding of doxycycline were studied in fifteen patients with various renal function impairments after oral doxycycline polyphosphate single administration. Plasma half-life (t 1/2), area under the plasma concentration-time curve (AUC), urinary excretion, renal clearance, erythrocyte and plasma protein binding (%) were regressed vs creatinine clearance. No significant correlations were observed between t 1/2 or AUC and renal function nor plasma protein binding and plasma albumin concentrations. Significant correlations were obtained between urinary excretion, renal clearance, erythrocyte binding, plasma protein binding and creatinine clearance. Significant correlation was obtained between haematocrit and erythrocyte binding. Constancy of overall elimination parameters in renal failure is due to parallel increase in plasma free fraction of doxycycline.     

Ranitidine: single dose pharmacokinetics and absolute bioavailability in man

1 Ranitidine single dose pharmacokinetics and absolute bioavailability have been studied in five healthy male volunteers. Following an overnight fast, 150 mg was given intravenously as a bolus injection or orally as a tablet formulation to each subject on separate occasions. 2 Following intravenous administration, plasma levels declined biexponentially. The mean (+/- s.d.) distribution half-life (t 1/2 alpha) was 6.6 +/- 1.6 min; plasma half-life (t 1/2 beta) was 1.7 +/- 0.2 h; the volume of distribution (V) was 96 +/- 9 1; total body clearance (CL) was 647 +/- 94 ml/min and renal clearance (CLR) 520 +/- 123 ml/min. 3 Following oral administration plasma levels showed a bimodal pattern with a first peak at 1.1 +/- 0.4 h and a second peak at 3 +/- 0 h. The absolute availability was 60 +/- 17%. The plasma half-life (t 1/2) of 2.3 +/- 0.4 h was significantly longer (P less than 0.05) after oral than after i.v. administration. 4 Renal excretion of unchanged ranitidine accounted for 79 +/- 9% of the dose after i.v. administration and for 27 +/- 7% after oral administration. 5 Our results suggest a more extensive biotransformation of ranitidine and biliary excretion of metabolites after oral administration while i.v. administration ranitidine is preferentially excreted unchanged in the urine.