Evaluation of a novel method to estimate absolute bioavailability of drugs from oral data

The goal of this investigation was to evaluate the performance of a novel method allowing estimation of absolute bioavailability from oral data only. In contrast to the traditional method, which compares areas under the drug concentration time curves after oral and intravenous administration in subjects with normal renal function, the novel method uses total and renal clearance values following oral administration from subjects with varying renal functions to estimate bioavailability. The novel method can also provide estimates for nonrenal clearance.Published data on total clearance and renal clearance of drugs obtained from subjects with variable renal functions were collected, the novel method applied, estimates of bioavailability and nonrenal clearance obtained and compared with reported estimates by the traditional methods. In addition computations were performed to assess various factors that could possibly affect the reliability of the novel method. The results indicated that the novel method provides accurate estimates for bioavailability of drugs meeting the prerequisites: linear kinetics, predominant renal excretion in normals, absence of metabolic polymorphism and independence of bioavailability and nonrenal clearance from renal function. The average (standard deviation) of the prediction error and bias of the bioavailability estimates by the novel method was 7.8 (6.0) and -1.4 (9.8)%, respectively. The estimates for nonrenal clearance by the novel method were less accurate. The computations confirmed that the estimates by the novel method are sensitive to renal-function dependent changes in nonrenal clearance and bioavailability and also depend on the extent of renal excretion of a drug. In conclusion, the novel method's main use is to diagnose absence or presence of changes in bioavailability and non-renal clearance of drugs in populations with varying renal function.     

Quinolone disposition in the elderly. Practical implications.

The fluoroquinolones are antibiotics frequently used in infections that affect elderly individuals. The physiological aging process can profoundly affect the pharmacokinetics of drugs, necessitating adjustment of dosage regimens in the elderly. Changes in pharmacokinetics with age are mainly due to the progressive deterioration of renal function, with resultant lower clearance of drugs which are eliminated by the kidneys. Ofloxacin is almost totally renally excreted and elimination is slower in older age groups; a dose reduction is therefore recommended for this quinolone. Unexpected alterations in pharmacokinetics may occur, as exemplified by the increased bioavailability of oral ciprofloxacin in elderly subjects. This is a well-documented phenomenon of such significance that lower oral doses are advisable for the elderly. Renal clearance of ciprofloxacin decreases in old age, but because of substantial nonrenal elimination the total clearance is affected less. Studies of the pharmacokinetics of the other quinolones in old age are scarce. No data exist on the absolute oral bioavailability of norfloxacin, enoxacin and pefloxacin. Renal clearance seems to be reduced, but since no intravenous studies have been reported, the total and nonrenal clearances are unknown in the elderly. No safe conclusions can be drawn regarding the necessity of dose reductions from a pharmacokinetic point of view. However, reports of adverse reactions to quinolones in the elderly, especially concentration-dependent symptoms from the central nervous system, and the risk of interaction with other drugs, suggest the need for caution in determining dosages of all of these compounds in elderly subjects.     

PREDICTION OF ABSOLUTE BIOAVAILABILITY FOR DRUGS USING ORAL AND RENAL CLEARANCE FOLLOWING A SINGLE ORAL DOSE: A CRITICAL VIEW

In order to determine the absolute bioavailability, both oral and intravenous administrations of a drug are often used. Recently a new method has been proposed to determine absolute bioavailability in the absence of intravenous dose. Following a single oral dose, this method requires oral and renal clearance data from normal subjects and renal failure patients. The bioavailability is calculated from a plot of oral against renal clearance following an oral dose, where the inverse of the slope is equal to absolute bioavailability. This study examines the prediction of absolute bioavailability from the proposed method for eight drugs which have a wide range of oral and renal clearance. From this study, it appears that the proposed method may not be reliable for the prediction of absolute bioavailability and further investigation is needed to test the validity of this method. © 1997 John Wiley & Sons, Ltd.     

Absolute bioavailability and disposition of lanthanum in healthy human subjects administered lanthanum carbonate

Lanthanum carbonate [La2(CO3)3] is a noncalcium, non-aluminum phosphate binder indicated for hyperphosphatemia treatment in end-stage renal disease. A randomized, open-label, parallel-group, phase I study was conducted to determine absolute bioavailability and investigate excretory routes for systemic lanthanum in healthy subjects. Twenty-four male subjects were randomized to a single lanthanum chloride (LaCl3) intravenous infusion (120 microg elemental lanthanum over a 4-hour period), a single 1-g oral dose [chewable La2(CO3)3 tablets; 4 x 250 mg elemental lanthanum], or no treatment (control). Serial blood, urine, and fecal samples were collected for 7 days postdosing. The absolute bioavailability of lanthanum [administered as La2(CO3)3] was extremely low (0.00127% +/- 0.00080%), with individual values in the range of 0.00015% to 0.00224%. Renal clearance was negligible following oral administration (1.36 +/- 1.43 mL/min). Intravenous administration confirmed low renal clearance (0.95 +/- 0.60 mL/min), just 1.7% of total plasma clearance. Fecal lanthanum excretion was not quantifiable after intravenous administration owing to high and variable background fecal lanthanum and constraints on the size of the intravenous dose. These findings demonstrate that lanthanum absorption from the intestinal tract into the systemic circulation is extremely low and that absorbed drug is cleared predominantly by nonrenal mechanisms.     

Comparison of bioavailability and pharmacokinetics of cimetidine in subjects with normal and impaired renal function

The bioavailability and pharmacokinetics of cimetidine were studied following single oral and intravenous doses in subjects with severely impaired renal function (SIRF) and normal renal function (NRF). Eight subjects with NRF and five patients with SIRF participated. Multiple blood samples were obtained up to 1440 minutes following both doses. Urine was also collected for 24 hours after each dose. The bioavailability of cimetidine was not significantly different between the two groups (78 +/- 15% in patients with SIRF and 62 +/- 17% in the NRF subjects). In subjects with NRF, a mean of 50.4% of the i.v. dose was excreted renally as unchanged drug and the mean serum half-life (t1/2) was 2.00 hours. The mean total body and renal clearances were 710.0 and 370.7 ml/min, respectively. In the SIRF group, a mean of 1.7% of the i.v. dose was excreted renally unchanged, and the mean t1/2 was 12.71 hours. The total body and renal clearances were 147.1 and 2.5 ml/min, respectively. Nonrenal clearance was 62% lower in the subjects with SIRF than in the NRF subjects. There is no significant difference in bioavailability of cimetidine between the patients with NRF and SIRF. The significantly lower nonrenal clearance of the patients with SIRF suggests that cimetidine metabolism may be impaired in uremic patients.     

Dose adjustment in patients with liver disease.

Unfortunately, there is no endogenous marker for hepatic clearance that can be used as a guide for drug dosing. In order to predict the kinetic behaviour of drugs in cirrhotic patients, agents can be grouped according to their extent of hepatic extraction. For drugs with a high hepatic extraction (low bioavailability in healthy subjects), bioavailability increases and hepatic clearance decreases in cirrhotic patients. If such drugs are administered orally to cirrhotic patients, their initial dose has to be reduced according to hepatic extraction. Furthermore, their maintenance dose has to be adapted irrespective of the route of administration, if possible, according to kinetic studies in cirrhotic patients. For drugs with a low hepatic extraction, bioavailability is not affected by liver disease, but hepatic clearance may be affected. For such drugs, only the maintenance dose has to be reduced, according to the estimated decrease in hepatic drug metabolism. For drugs with an intermediate hepatic extraction, initial oral doses should be chosen in the low range of normal in cirrhotic patients and maintenance doses should be reduced as for high extraction drugs. In cholestatic patients, the clearance of drugs with predominant biliary elimination may be impaired. Guidelines for dose reduction in cholestasis exist for many antineoplastic drugs, but are mostly lacking for other drugs with biliary elimination. Dose adaptation of such drugs in cholestatic patients is, therefore, difficult and has to be performed according to pharmacological effect and/or toxicity. Importantly, the dose of drugs with predominant renal elimination may also have to be adapted in patients with liver disease. Cirrhotic patients often have impaired renal function, despite a normal serum creatinine level. In cirrhotic patients, creatinine clearance should, therefore, be measured or estimated to gain a guideline for the dosing of drugs with predominant renal elimination. Since the creatinine clearance tends to overestimate glomerular filtration in cirrhotic patients, the dose of a given drug may still be too high after adaptation to creatinine clearance. Therefore, the clinical monitoring of pharmacological effects and toxicity of such drugs is important. Besides the mentioned kinetic changes, the dynamics of some drugs is also altered in cirrhotic patients. Examples include opiates, benzodiazepines, NSAIDs and diuretics. Such drugs may exhibit unusual adverse effects that clinicians should be aware of for their safe use. However, it is important to realise that the recommendations for dose adaptation remain general and cannot replace accurate clinical monitoring of patients with liver disease treated with critical drugs.     

Estimation of absolute oral bioavailability without performing an intravenous clinical study

The absolute oral bioavailability (BA) of drugs are yet to be determined, and intravenous pharmacokinetic studies are currently considered indispensable for determining the BA values of oral drugs. The aim of this study was to develop and validate a novel approach to estimating BA values without intravenous pharmacokinetic data. Based on the drug inclusion criteria, such as exhibiting a urinary recovery rate of (R_u) of ≥20% in a clinical study, 13 drugs were included in the present study, and pharmacokinetic data for them were collected from the literature. The fraction excreted unchanged into urine (f_e) was calculated for healthy subjects by dividing the R_u value by the total recovery rate. The contribution of renal excretion to total clearance from the systemic circulation (R_ren) was estimated by subjecting oral clearance and creatinine clearance to regression in subjects with normal and impaired renal function. BA was estimated as f_e/R_ren and compared with the observed BA (BA_obs). The predicted BA values for 9 drugs fell within ±20% of their BA_obs. The examined approach makes it possible to estimate BA values for drugs with mean renal excretion values in healthy subjects and oral clearance in subjects with various renal function, without intravenous pharmacokinetic data.     

Fosinopril: pharmacokinetics and pharmacodynamics in Chinese subjects

This study examined thepharmacokinetics and pharmacodynamics of fosinopril (IVand oral) in Chinese subjects to determine whether they were different from a group of somewhat heavier and older Western control subjects previously published using the same methods. It was an open-label, randomized, balanced, two-way crossover study comparing oral and IV pharmacokinetics in 12 healthy Chinese subjects in a clinic in Taiwan. Each subject received 10 mg of oral fosinopril or 7.5 mg of IV fosinoprilatin a randomized sequence with sampling for fosinoprilat concentrations over 48 hours. Standard pharmacokinetics, including AUC, Cmax Tmax, T 1/2, Vss, bioavailability, total clearance, and renal and nonrenal clearance, were determined as well as pharmacodynamic effects on angiotensin-converting enzyme (ACE) activity. Following oral administration of 10 mg fosinopril, AUC0-T and AUCinf were 1,556 +/- 586 ng x hr/mL and 1,636 +/- 620 ng x hr/mL, respectively; T 1/2 was 17.4 +/- 11.4 hr; Cmax was 183.4 +/- 59.4 ng/mL; and median Tmax was 4.0 hr, with > 99% protein binding. Following IV administration of 7.5 mg fosinoprilat, AUC0-T and AUCinf were 7,727 +/- 2,638 ng x hr/mL and 7,816 +/- 2,693 ng x hr/mL, respectively; T 1/2 was 13.0 +/- 5.2 hr; and median Tmax was 4.0 hr, with 99.5% +/- 0.22% protein binding and a Vss of 5,850 +/- 2,780 mL. Bioavailability was 22.3% +/- 7.9%. Percent urinary excretion was 7.6% +/- 2.6% after oral dosing and 42.6% +/- 6.1% after IV dosing. After IV, dosing total clearance was 1,088 +/- 439 mL/hr, renal clearance was 472 +/- 213 mL/hr, and nonrenal clearance was 617 +/- 246 mL/hr. ACE inhibition was essentially complete through 12 hours and markedly reduced through 24 hours. Compared to a somewhat heavier and older previously reported control group, pharmacokinetic values were similar except for a slightly lower AUC and total clearance in Chinese and a statistically significantly lower nonrenal clearance. Pharmacodynamic effects on ACE activity were essentially identical. There is no reason to expect significant differences in fosinopril dosing or effect in a Chinese population compared to a Western population.     

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.     

Clinical pharmacokinetics of the antiviral nucleotide analogues cidofovir and adefovir

Cidofovir and adefovir are members of a new class of antiviral compounds. They are acyclic phosphonate analogues of deoxynucleoside monophosphates. Both compounds undergo intracellular activation to form diphosphates that are potent inhibitors of viral DNA polymerases. Cidofovir has broad spectrum antiviral activity against herpesviruses, papillomaviruses and poxviruses, whereas adefovir has potent activity against retroviruses and certain DNA viruses, including herpesviruses and hepadnaviruses. Intravenous cidofovir is approved for treatment of cytomegalovirus retinitis in patients with AIDS. Cidofovir and adefovir are dianionic at physiological pH and have low oral bioavailability in animals and humans. After intravenous administration to HIV-infected patients, the pharmacokinetics of both drugs are independent of dose and are consistent with preclinical data. Systemic exposure is proportional to the intravenous dose and both drugs are cleared by the kidney and excreted extensively as unchanged drug in the urine. Intracellular activation of a small fraction (< 10%) of the dose by cellular kinases leads to prolonged antiviral effects that are not easily predicted from conventional pharmacokinetic studies. The observed rate of elimination of cidofovir and adefovir from serum may not reflect the true duration of action of these drugs, since the antiviral effect is dependent on concentrations of the active phosphorylated metabolites that are present within cells. For both drugs, > 90% of an intravenous dose is recovered unchanged in the urine over 24 hours. Metabolism does not contribute significantly to the total clearance of either drug. Concomitant oral probenecid decreases both the renal clearance of cidofovir and the incidence of nephrotoxicity, presumably by blocking its active tubular secretion. This is the basis of the clinical use of concomitant probenecid as a nephroprotectant during cidofovir therapy. Subcutaneous administration produces exposure equivalent to that following intravenous administration. Drug interaction studies with cidofovir are ongoing, but there is no evidence of an interaction between zidovudine and either cidofovir or adefovir. Clearance of cidofovir in patients with renal impairment showed a linear relationship to creatinine clearance. The low oral bioavailability of adefovir has led to the development of an oral prodrug, adefovir dipivoxil, currently in development for the treatment of HIV and hepatitis B infections.     

Acecainide pharmacokinetics in normal subjects of known acetylator phenotype.

The purpose of this study was to determine the pharmacokinetics of acecainide (formerly N-acetylprocainamide) in six normal subjects of known acetylator phenotype. Three subjects were fast acetylators and three slow acetylators by sulfapyridine phenotyping criteria. Each subject received a 20-min, 3 mg kg-1 intravenous acecainide infusion. Concentrations of acecainide, procainamide, and their deethylated metabolites were measured in serum and urine samples using HPLC. Acecainide renal clearance, nonrenal clearance, steady-state volume of distribution, and other pharmacokinetic parameters were estimated using standard approaches. Acecainide renal clearance and steady-state volume of distribution were (mean +/- SD) 13.6 +/- 1.581 h-1 and 135 +/- 20.31, respectively, and were not significantly different in fast and slow acetylators. Acecainide nonrenal clearance in the six subjects was 3.0 +/- 1.01 h-1; however, nonrenal clearance in slow acetylators was 1.8 times that in fast acetylators (3.9 vs 2.21 h-1, p = 0.012) with clear separation of the subjects into two groups when the data were grouped by acetylator phenotype. The nonrenal clearance of acecainide was inversely correlated with percentage sulfapyridine acetylation. Computer simulations were conducted to explore possible explanations for the observed difference in nonrenal clearance.     

Pharmacokinetics and renal excretion of desmopressin after intravenous administration to healthy subjects and renally impaired patients

OBJECTIVE: To evaluate the influence of renal impairment on the pharmacokinetics of desmopressin. METHODS: Twenty-four subjects were enrolled in the study, 18 with varying degrees of renal impairment and six healthy volunteers. Each subject received a single intravenous dose of 2 microg desmopressin. Blood and urine samples were collected for 24 h and assayed for desmopressin by radioimmunoassay. Plasma concentrations and the amounts of desmopressin excreted in the urine were analysed simultaneously by use of mixed effects modelling. RESULTS: Only mild adverse events were observed. Both the renal and the nonrenal clearance of desmopressin were found to vary with the creatinine clearance (CrCL). A decrease of 1.67% in the CrCL (corresponding to 1 ml min(-1) from 60 ml min(-1)) was found to cause a 1.74% decrease in the renal clearance and a 0.93% decrease in the nonrenal clearance. The fall in renal clearance caused the amount of desmopressin excreted in urine to decrease from 47% in healthy subjects to 21% in the patients with severe renal impairment. The mean systemic clearance of desmopressin was 10 litres h(-1) in healthy subjects and 2.9 litres h(-1) in patients with severe renal impairment (difference -7.5 litres h(-1), 95% CI [-11; -4.3] litres h(-1)). Correspondingly, the mean terminal half-life, was 3.7 h in healthy subjects and 10 h in patients with severe renal impairment (difference 6.7 h, 95% CI [4.0; 9.4] h). CONCLUSION: Although desmopressin appears to be safe and well-tolerated by patients with impaired renal function, great caution should be exercised when titrating towards an efficient dosage regimen if patients with moderately or severely impaired renal function are to be treated with desmopressin at all.     

Steady-state intravenous pharmacokinetics of pirenzepine in patients with differing degrees of renal dysfunction

Summary The steady-state intravenous pharmacokinetics of pirenzepine has been investigated in 57 subjects whose renal function ranged from normal to chronic failure requiring regular haemodialysis.Pirenzepine renal clearance, total clearance and terminal (dominant) half-life were found to be correlated with the creatinine clearance (CL_CR), but this was not the case for the volume of distribution and the nonrenal clearance. The therapeutic regimen was well tolerated by all subjects. Haemodialysis did not significantly contribute to the elimination of pirenzepine. Dosage adjustment need only be considered in patients with CL_CR<25 ml/min in order to reduce the frequency of minor side-effects.     

Pharmacokinetics of alpha-lipoic acid in subjects with severe kidney damage and end-stage renal disease

In an open-label, parallel-group study involving 16 patients (8 with severely reduced renal function, 8 with end-stage renal disease needing hemodialysis), the effect of renal function on the pharmacokinetics, metabolism, and safety and of alpha-lipoic acid (thioctic acid) was evaluated by comparing the pharmacokinetic parameters with those of a reference group of 8 healthy subjects. Alpha-lipoic acid 600 mg was administered orally once daily for 4 days, and the pharmacokinetic parameters were measured on days 1 and 4. The mean percentage of the administered dose excreted in urine as parent compound was 0.2 and 0.05 in healthy subjects and subjects with severely reduced renal function, respectively. Assuming a bioavailability of 30%, this represents 0.67% and 0.17% of the bioavailable amount of alpha-lipoic acid, respectively. The percentage of total urinary recovered amounts of alpha-lipoic acid and 5 of its metabolites was 12.0 on both days. The respective values for patients with severe kidney damage were 5.2% (day 1) and 6.4% (day 4). The total percentage of the administered dose removed by hemodialysis was 4.0 in patients with end-stage renal disease. Renal clearance of alpha-lipoic acid and its major metabolites, 6,8-bismethylthio-octanoic acid, 4,6-bismethylthio-hexanoic acid and 2,4-bismethylthio-butanoic acid, were significantly decreased in subjects with kidney damage compared to the reference group. Apparent total clearance of alpha-lipoic acid was poorly correlated with creatinine clearance. There is strong evidence that alpha-lipoic acid is mainly excreted by nonrenal mechanism or further degraded to smaller units in the catabolic process. The significantly increased area under the curve values of 4,6-bismethylthio-hexanoic acid and half-lives of 2,4-bismethylthio-butanoic acid on both days in patients with severely reduced function and end-stage renal disease were not considered to be clinically relevant. Although trough levels of both metabolites tend to increase slightly in these subjects, no accumulation effects were detected. We conclude that the pharmacokinetics of alpha-lipoic acid are not influenced by creatinine clearance and are unaffected in subjects with severely reduced kidney function or end-stage renal disease. Hemodialysis did not significantly contribute to the clearance of alpha-lipoic acid. Hence, dose adjustment of alpha-lipoic acid is not necessary in patients with renal dysfunction.     

The bioavailability and pharmacokinetics of guanfacine after oral and intravenous administration to healthy volunteers

Guanfacine is a centrally acting alpha-2 adrenergic agonist. The absolute bioavailability, pharmacokinetics, and renal clearance of this antihypertensive drug were investigated in healthy male volunteers. Eighteen subjects received a single oral or intravenous dose of guanfacine 3 mg in a two-way cross-over study design. Blood samples were obtained before dosing and up to 72 hours after dosing for determination of drug levels in plasma. Additional blood samples were obtained for protein binding studies. Urine was collected and pooled for specific intervals up to 96 hours after dosing. The absolute bioavailability of guanfacine after a single oral dose was 81.1%. The elimination half-lives were 13.8 hours and 13.4 hours after oral and intravenous administration, respectively. The volume of distribution results were approximately 6 L/kg by both routes of administration. The mean plasma protein binding results were 71.6%, not influenced by plasma concentration or route of administration. The urinary recovery of guanfacine was 44.3% after oral dosing and 50% after intravenous dosing. Renal clearance of guanfacine was 50% of total body clearance and appeared to be due to a net renal tubular secretory process.     

The assessment of bioavailability in the presence of nonlinear elimination

The simultaneous administration of an oral dose and intravenous tracer dose, as a method to determine bioavailability, was examined by means of computer simulation for drugs exhibiting Michaelis-Menten type elimination. A physiological pharmacokinetic model parameterized for man and including first-order absorption and elimination solely from the liver was employed. This tracer method provided good estimates of the true availability, with an error of 6% or less, over a wide range of dosing and dispositional conditions. Poorer estimates were noted when large doses of drugs with very short half-lives were considered. This poor performance was improved by administering the intravenous tracer at some time after the oral dose but an a priori basis for establishing this time was not apparent. The tracer method, therefore, appears to be a robust means of assessing, in man, oral bioavailability in the presence of Michaelis-Menten type elimination for drugs characterized by the general properties of the physiological model employed and with half-lives in excess of approximately 40 min. These findings together with the statistical power and simplicity of performance of the tracer method indicate that it is a valid technique for the assessment of bioavailability under a wide range of kinetic conditions.     

Bioavailability and pharmacokinetics of phenytoin during pregnancy

Summary Five epileptic women needing to commence phenytoin therapy during pregnancy received a single intravenous and a single oral dose of phenytoin several days apart before starting regular intake of the drug. Plasma phenytoin concentration — time data were analysed by three different pharmacokinetic techniques. However assessed, the mean oral bioavailability of the drug proved to be about 90% of the intravenous bioavailability. This finding makes it unlikely that impaired bioavailability accounts for the increase in oral phenytoin dosage necessary in pregnancy to maintain plasma phenytoin concentrations at pre-pregnancy values. Phenytoin clearance in the pregnant subjects was approximately double the published values for phenytoin clearance in nonpregnant persons. This suggests that increased (metabolic) clearance accounts for the increased phenytoin dosage requirement of pregnancy.     

Bioavailability and kinetics of cibenzoline in patients with normal and impaired renal function

To test the hypothesis that renal failure alters the disposition of cibenzoline in humans, an absolute bioavailability and elimination kinetic study was performed. We used the simultaneous administration of a stable isotope variant (SASIV). Eight healthy volunteers and eight matched hemodialysis patients each received simultaneously an 80-mg intravenous infusion of 15N-2-cibenzoline and a single 80-mg cibenzoline capsule. Cibenzoline plasma concentrations were assayed by a gas chromatographic-mass spectrometric assay. A compartment-independent kinetic analysis showed a plasma clearance of 707 mL/min and an elimination half-life of 7.3 hours after the intravenous dose in healthy volunteers. In renal-failure patients, cibenzoline clearance decreased to 224 mL/min and half-life increased to 22.4 hours. Decreased plasma clearance was due to decreases in both renal and nonrenal clearance. Absolute bioavailability was 83% and 90% in healthy volunteers and renal-failure patients, respectively. Hemodialysis accounted for only 13% of drug clearance.     

Effects of amiodarone on oral and intravenous digoxin kinetics in healthy subjects

The effect of amiodarone on oral and intravenous pharmacokinetics of digoxin was studied in healthy volunteers. A single 0.5-mg dose of digoxin was administered orally to three subjects both before and after 2 weeks of oral amiodarone (200 mg daily), while three subjects received a 0.5-mg intravenous dose of the glycoside under the same experimental conditions. Two other subjects were given both oral and intravenous doses of digoxin at different times, in the absence and in the presence of amiodarone. After oral digoxin treatment, amiodarone increased peak serum concentration, total area under the serum concentration-time curve (AUC), and 5-day urinary recovery of the glycoside, without changes in peak time and absorption rate constant. During the intravenous study, no significant change occurred in AUC and urinary recovery after amiodarone administration. Absolute bioavailability, for the two subjects who received both oral and intravenous digoxin, increased by 36 and 43%, respectively, after amiodarone treatment. Bioavailability derived from the mean values of oral and intravenous AUCs was 33% greater with amiodarone treatment. Apparent volume of distribution and systemic, extrarenal, and renal clearances of oral digoxin were not modified by amiodarone, when corrected for the bioavailability factor. Amiodarone had no effect on these pharmacokinetic parameters during the intravenous study with the glycoside. Our data indicate that increased oral bioavailability is the most relevant change in digoxin pharmacokinetics during the interaction with amiodarone and this can account for the increase in the glycoside concentrations.     

Reduced clearance of ε-acetamidocaproic acid in rats with acute renal failure induced by uranyl nitrate

Objectives Anti-ulcer drugs are frequently used in patients with acute renal failure (ARF). Zinc acexamate is ionized to zinc and ε-acetamidocaproic acid and free EACA exerts a potent therapeutic effect in treating gastric or duodenal ulcers with few side effects. Thus, pharmacokinetic changes in rats with acute renal failure induced by uranyl nitrate (U-ARF rats) were investigated in this study. Methods The in-vivo pharmacokinetics and in-vitro hepatic/intestinal metabolism of EACA were assessed using control and U-ARF rats. The mechanism of urinary excretion of EACA was further investigated in rats. Key findings After intravenous and oral administration of zinc acexamate to U-ARF rats, there were significant increases in the values of the area under the curve (AUC) and decreases in the values for time-averaged renal and nonrenal clearances (Cl(r) and Cl(nr) , respectively) compared with control rats. Slower Cl(nr) was partly due to a decrease in the metabolism in liver and/or intestine. Slower Cl(r) could have been due to urine flow rate-dependent timed-interval renal clearance, decrease in organic anion transporter-mediated renal excretion (drug interaction with probenecid and decrease in the relative contribution of net secretion compared with glomerular filtration in U-ARF rats) and/or impaired kidney function. Conclusions The pharmacokinetics were significantly altered in U-ARF rats due to the changes in both the hepatic/intestinal metabolism and urinary excretion.