Bioavailability and elimination of nitrendipine in liver disease

Effect of Liver Cirrhosis on Theophylline Trough Concentrations: A Comparative Analysis of Organ Impairment Using Child-Pugh and MELD Scores

AIMS

Theophylline clearance is known to be reduced in patients with chronic liver diseases (CLDs) such as chronic hepatitis (CH) and liver cirrhosis (LC). The Child-Pugh (CP) score is generally used for pharmacokinetic evaluation, whilst a model for end-stage liver disease (MELD) has not yet been fully evaluated. This study aimed to predict theophylline clearance in patients with LC classified based on CP and MELD scores by population pharmacokinetic (PPK) analysis.

METHODS

PPK analysis included 433 steady-state trough concentrations from 192 Japanese bronchial asthma patients with and without CLDs and was performed using NONMEM. The severity of LC was assessed by CP and MELD scores.

RESULTS

The final CP and MELD models which described apparent theophylline clearance (CL/F) were obtained. The CP model showed that the mean CL/F in patients without CLDs, CH patients, and LC patients with CP class A, B, and C was 0.0473, 0.0413, 0.0330, 0.0280, and 0.0209 L/h kg-1, respectively. The MELD model predicted that CL/F in patients without CLDs, CH patients, and LC patients with MELD scores of < 10, 10-14, 15-19, 20-24, and ≥ 25 was 0.0472, 0.0413, 0.0324, 0.0268, 0.0230, 0.0197, and 0.0155 L/h kg-1, respectively.

CONCLUSIONS

CL/F in various stages of LC was evaluated, and a change in CL/F was highly dependent on the severity of CLDs in both models. The MELD model provided a more accurate and precise description of theophylline clearance in LC than the CP model, which may be due to the wider dynamic range of the MELD score.

Nitrendipine and amlodipine mimic the acute effects of enalapril on renal haemodynamics and reduce glomerular hyperfiltration in patients with chronic kidney disease

Antihypertensive drugs may have an important effect on glomerular haemodynamics. In chronic nephropathy patients, we compared the effect on glomerular haemodynamics of two second-generation dihydropyridinic agents, nitrendipine and amlodipine, with a first generation dihydropyridinic agent and an ACE-inhibitor, enalapril. In all, 32 patients (pts), divided into four groups, received the different drugs: ENA (enalapril, eight pts), NIF (nifedipine, eight pts), NIT (nitrendipine, eight pts) AML (amlodipine, eight pts). The study assessed the effect on glomerular haemodynamics of a single administration of the test drug in baseline conditions and in glomerular hyperfiltration experimentally induced by amino-acid infusion. The glomerular filtration rate (GFR, measured by inulin clearance), effective renal plasma flow (ERPF, measured by p-aminohippurate clearance), renal vascular resistances (RVR) and filtration fraction (FF) were assessed. Administration of AML and NIT test dose reduced FF, as did ENA, but not NIF, in both baseline (AML: P=0.005; NIT: P=0.02; ENA: P=0.007) and glomerular hyperfiltration conditions (AML: P=0.0003; NIT: P=0.03; ENA: P=0.00006). In baseline conditions, only ENA resulted in a significant drop in the GFR (P=0.008), while NIF, NIT and AML induced a significant increase (P=0.003, 0.03, 0.0001, respectively). However, in hyperfiltration conditions, NIT (0.08) and AML (0.00003) caused a decrease in the GFR, as did ENA (0.0003) but not NIF. In all the experimental conditions, a RVR reduction and an ERPF increase were observed. Single dose of NIT and AML were effective in attenuating the effect of amino-acid infusion on glomerular filtration, similar to ENA; this effect of NIT and AML on the glomerular filtration rate is not observed under basal conditions.

Effects of liver disease on pharmacokinetics. An update

Liver disease can modify the kinetics of drugs biotransformed by the liver. This review updates recent developments in this field, with particular emphasis on cytochrome P450 (CYP). CYP is a rapidly expanding area in clinical pharmacology. The information currently available on specific isoforms involved in drug metabolism has increased tremendously over the latest years, but knowledge remains incomplete. Studies on the effects of liver disease on specific isoenzymes of CYP have shown that some isoforms are more susceptible than others to liver disease. A detailed knowledge of the particular isoenzyme involved in the metabolism of a drug and the impact of liver disease on that enzyme can provide a rational basis for dosage adjustment in patients with hepatic impairment. The capacity of the liver to metabolise drugs depends on hepatic blood flow and liver enzyme activity, both of which can be affected by liver disease. In addition, liver failure can influence the binding of a drug to plasma proteins. These changes can occur alone or in combination; when they coexist their effect on drug kinetics is synergistic, not simply additive. The kinetics of drugs with a low hepatic extraction are sensitive to hepatic failure rather than to liver blood flow changes, but drugs having a significant first-pass effect are sensitive to alterations in hepatic blood flow. The drugs examined in this review are: cardiovascular agents (angiotensin converting enzyme inhibitors, angiotensin II receptor antagonists, calcium antagonists, ketanserin, antiarrhythmics and hypolipidaemics), diuretics (torasemide), psychoactive and anticonvulsant agents (benzodiazepines, flumazenil, antidepressants and tiagabine), antiemetics (metoclopramide and serotonin antagonists), antiulcers (acid pump inhibitors), anti-infectives and antiretroviral agents (grepafloxacin, ornidazole, pefloxacin, stavudine and zidovudine), immunosuppressants (cyclosporin and tacrolimus), naltrexone, tolcapone and toremifene. According to the available data, the kinetics of many drugs are altered by liver disease to an extent that requires dosage adjustment; the problem is to quantify the required changes. Obviously, this requires the evaluation of the degree of hepatic impairment. At present there is no satisfactory test that gives a quantitative measure of liver function and its impairment. A critical evaluation of these methods is provided. Guidelines providing a rational basis for dosage adjustment are illustrated. Finally, it is important to consider that liver disease not only affects pharmacokinetics but also pharmacodynamics. This review also examines drugs with altered pharmacodynamics.

Disposition, Elimination and Haemodynamic Effects of Gallopamil in Patients with Fatty Liver Disease

Twenty-one hypertensive patients were treated orally with 50mg gallopamil in a sustained-release formulation once daily for 1 week. 11 patients had a normal liver function (antipyrine clearance 41.2 ± 2.8 ml/min; mean ± SD), while 10 patients had fatty liver disease (antipyrine clearance 32.3 ± 1.4 ml/min). Maximum plasma concentrations of gallopamil were 15.2 (7.9 to 29.3) µg/L (geometric mean; 95% confidence interval) in patients with normal and 16.8 (8.7 to 32.5) µg/L in those with impaired hepatic function (p > 0.05). The elimination half-life was 8.8 hours in patients with normal liver function and 9.2 hours in patients with fatty liver disease (median, p > 0.05). No significant differences were found between patients with and without concomitant liver disease with regard to the effects of gallopamil on heart rate, PQ-time and blood pressure. First degree AV-block developed during treatment with gallopamil in one patient with fatty liver disease and in another with normal liver function. The AV-block in the patient with impaired hepatic function was considered to be severe (PQ-time 270ms). In conclusion, kinetic parameters of patients with fatty liver disease did not differ significantly from those of subjects with normal liver function.

Bunazosin in patients with impaired hepatic or renal function

Following a single oral dose of 6 mg bunazosin, a novel alpha 1-adrenoceptor antagonist, the pharmacokinetics and blood pressure behaviour of 37 patients were studied. 12 subjects had normal renal and hepatic function (mean creatinine clearance (GFR) 107 +/- 240 ml/min, antipyrine clearance (AP Cl) 47 +/- 10.2 ml/min; x +/- SD), 13 subjects had impaired renal function (mean GFR 38 +/- 11.5 ml/min, AP Cl 39 +/- 4.0 ml/min), and 12 patients had liver cirrhosis which was confirmed by liver biopsy (mean AP Cl 18 +/- 9.2 ml/min, GFR 92 +/- 8.1 ml/min). The groups studied were matched for age and body weight. The area under the plasma level time curve (AUC0-infinity) of bunazosin increased from 96.6 +/- 48.7 micrograms.ml-1.h in the normals to 157.0 +/- 101.0 micrograms.ml-1.h in the liver patients and to 298.2 +/- 199.4 micrograms.ml-1.h in patients with impaired renal function (P < 0.05). As there was a close correlation between plasma levels and antihypertensive activity of bunazosin in the present study, dosage adjustment of the alpha 1-receptor blocker in patients with impaired liver and kidney function appears to be mandatory.

Clinical pharmacokinetics of calcium antagonists. An update

The calcium antagonists are valuable and widely used agents in the management of essential hypertension and angina. There is an increasing number of new agents to add to the 3 prototype substances nifedipine, diltiazem and verapamil. These new agents are dihydropyridines structurally related to nifedipine. However, they tend to have longer elimination half-lives (t 1/2 beta) and may be suitable for twice-daily administration. Amlodipine is an exception with a t 1/2 beta in excess of 30h. Apart from elimination rates, however, the pharmacokinetic characteristics of the newer agents have a notable tendency to resemble those of the established agents. They are highly cleared drugs, are relatively highly protein bound. As they are subject to significant first-pass metabolism, old age and hepatic impairment will increase their plasma concentrations due to a reduced first-pass effect. Renal impairment does little to their pharmacokinetics since the fraction eliminated unchanged by the kidney is small. For most agents, plasma concentration-response relationships have been described. Interesting areas for further research include chronopharmacokinetics, stereoselective pharmacokinetics and lipid solubility. Drugs affecting hepatic blood flow and drug metabolising capacity have predictable interaction potential. Some of the newer calcium antagonists will, like verapamil, increase plasma digoxin concentrations. Verapamil and diltiazem decrease phenazone (antipyrine) metabolism and therefore tend to decrease the metabolism of other drugs.

Elevated plasma nilvadipine concentration after single and chronic oral administration to patients with chronic liver disease

Fourteen normotensive patients with liver disease (6 with cirrhosis and 8 with chronic hepatitis) and 7 healthy volunteers were given a single oral dose of nilvadipine 2 mg. In addition, nilvadipine 4 mg was administered orally twice daily for several months to 6 hypertensive patients with mild liver dysfunction and 18 hypertensives with normal liver function. A significant increase in plasma nilvadipine was found in the patients with cirrhosis as compared both to the normal and chronic hepatitis subjects; the time to peak concentration was similar among the three groups. The peak plasma nilvadipine concentration was closely correlated both with the serum albumin level and the retention of indocyanine green. Changes in blood pressure, pulse rate and various vasoactive hormones following a single oral dose of nilvadipine did not differ between the groups. Thus, an increase in plasma nilvadipine relative to the level in normal subjects was demonstrated in patients with cirrhosis following a single oral dose, as well as in patients with slight liver dysfunction following long-term oral administration.

Stereoselective pharmacokinetics of oral nitrendipine in elderly hypertensive patients with normal and impaired renal function

The pharmacokinetics of the enantiomers of nitrendipine has been studied in seven elderly patients with chronic renal failure (CRF) and in six control subjects (mean creatinine clearance 30 and 97 ml.min-1 respectively). Racemic nitrendipine 20 mg was given once daily for seven days and the pharmacokinetics of the enantiomers over the last dosage interval were determined using a stereospecific assay. In both groups nitrendipine exhibited stereoselective pharmacokinetics (AUC, Cmax), but the half-lives of the enantiomers did not differ in individual subjects. As an index of stereoselectivity, the mean S/R ratio of AUCs in control subjects (2.07) was not significantly different from the ratio in patients with CRF (2.68). The mean AUCs of (S)- and (R)-nitrendipine during the last dosage interval were increased in CRF by 132% and 85%, respectively. The observed doubling of the half-lives and the increases in Cmax did not reach significance because of the large variability in each group. Thus, the pharmacokinetics of oral nitrendipine is altered in CRF, but there was no change in the stereoselectivity of its pharmacokinetics.

Clinical pharmacokinetics of the nifedipine/co-dergocrine combination in impaired liver and renal function

Following a single oral dose of 20 mg nifedipine combined with 2 mg co-dergocrine to 24 subjects, the pharmacokinetics of this drug were studied. 8 normotensive subjects had normal renal and hepatic function, 8 patients had chronic renal insufficiency (creatinine clearance less than 30 ml.min-1) and 8 patients had liver cirrhosis which was confirmed by liver biopsy. The area under the plasma level time curve (AUC infinity) of co-dergocrine increased from 0.59 +/- 0.41 ng.ml-1. (mean +/- SD) in the normals to 1.24 +/- 0.95 ng.ml-1.h in liver cirrhosis (P less than 0.05) and to 1.81 +/- 0.9 ng.ml-1.h in renal failure (P less than 0.05 compared with the control group). Corresponding values for the nifedipine AUC infinity were 564.5 +/- 268 ng.ml-1.h, 1547.5 +/- 1134 (P less than 0.05) and 929 +/- 533 ng.ml-1.h (P less than 0.05; gas chromatographic method). The incidence of adverse effects was lower in patients with renal failure than in subjects with normal renal and liver function as well as in those with liver cirrhosis.

Use of pseudoracemic nitrendipine to elucidate the metabolic steps responsible for stereoselective disposition of nitrendipine enantiomers

1. The pharmacokinetics, protein binding, bioavailability and metabolism of (+)-R- and (-)-S-nitrendipine were studied in six healthy subjects following random oral administration of 20 mg (+)-R-, 20 mg (-)-S- and 20 mg R,S-nitrendipine (pseudoracemic mixture of 10 mg [13C4)-(+)-R- and 10 mg (-)-S-enantiomer). 2. After administration of the enantiomers pronounced differences in AUC (R: 29.9 +/- 20.1; S: 123.8 +/- 63.7 ng ml-1 h; P less than 0.05), bioavailability (R: 10.7 +/- 7.4%; S: 44.6 +/- 23.1%; P less than 0.05) and Cmax (R: 14.4 +/- 7.7; S: 72.5 +/- 40.5 ng ml-1; P less than 0.05) were observed between R- and S-nitrendipine. When racemic nitrendipine was given bioavailability and dose normalized AUC and Cmax values of the S-enantiomer were not different from the values after S-nitrendipine-administration. In contrast, bioavailability (R: 10.7% R,S: 22.1%) and dose normalized AUC (R: 15.0; R,S: 29.5 ng ml-1 h and Cmax (R: 7.2; R,S: 16.8 ng ml-1) of R-nitrendipine were doubled following R,S- as compared with R-nitrendipine administration. t1/2 (R: 9.8; S: 9.1 h) and tmax were not different between the enantiomers nor were the values different after administration of the enantiomers or racemate. The fraction unbound in serum of R-nitrendipine was 0.0098 +/- 0.0032 (s.d.) and that of S-nitrendipine was 0.0083 +/- 0.0015 (s.d.). 3. The AUC values of the major pyridine metabolite M1 were similar after administration of R- and S-nitrendipine (S: 114.7 +/- 48.5; R: 71.7 +/- 29.9 ng ml-1 h).(ABSTRACT TRUNCATED AT 250 WORDS)

Quantifying hepatic function in the presence of liver disease with phenazone (antipyrine) and its metabolites

The disposition of phenazone (antipyrine), a low extraction compound with low protein binding, is known to be altered in the presence of various types of hepatic dysfunction. As such, its pharmacokinetics may be useful in the objective characterisation of altered liver function. Understanding the known effects of various liver disease states upon the disposition of this probe may provide insight into future applications. This article provides a review of background information about normal plasma phenazone pharmacokinetics, urinary metabolite disposition and tabulations of reported total body clearances of the drug in the presence of cirrhosis, fatty liver, hepatitis and cholestasis in humans. An estimate is made of the sensitivity and specificity of phenazone testing for the verification of the presence of cirrhosis based on this compiled literature.

Pharmacokinetics after a single oral dose of bopindolol in patients with cirrhosis

The plasma concentration-time curve of the hydrolysis product of bopindolol has been investigated in 14 patients with cirrhosis and in 15 healthy volunteers given a single oral dose of 2 mg bopindolol. Cirrhosis was confirmed by history and clinical examination or liver biopsy. The time to maximum concentration, maximum concentration and AUC of hydrolyzed bopindolol were similar in the patients and controls. However, the elimination half-life was 6.0 h in controls and 9.5 h in cirrhotics. Antipyrine clearance was markedly decreased in patients with cirrhosis, but no correlation was found with the pharmacokinetic parameters of hydrolysed bopindolol. Although the AUC was not significantly altered in patients with cirrhosis, the longer half-life of hydrolysed bopindolol suggests impairment of its disposition in liver disease, which could lead to significant accumulation of drug during chronic dosing.

Pharmacokinetics of isradipine in patients with chronic liver disease

The pharmacokinetics of the dihydropyridine calcium antagonist isradipine has been examined in 8 healthy volunteers, 7 patients with non-cirrhotic chronic liver disease (CLD), and 8 patients with biopsy-proven cirrhosis (CIR). Isradipine was simultaneously given orally (12C 5 mg) and i.v. (13C 1 mg). Systemic availability was significantly increased from 17% to 16% in controls and CLD, respectively, to 37% in CIR. The corresponding systemic clearances averaged 1.1, 0.9 and 0.6 l.min-1, the reduction in cirrhotics being significant. Both aminopyrine demethylation capacity, a measure of hepatic microsomal function, and indocyanine green disappearance, a measure of hepatic perfusion, were correlated with the reduction in systemic clearance, and the reduction in oral clearance was correlated with the reciprocal of the serum bile acid concentration. The loss of first-pass extraction should be considered when this calcium antagonist is given perorally in patients with hepatic cirrhosis.

Calcium channel antagonists: Part VI: Clinical pharmacokinetics of first and second-generation agents

A survey of the pharmacokinetic properties of the three prototypical calcium antagonist agents shows that they have in common a very high rate of hepatic first-pass metabolism with, in the case of verapamil and diltiazem, the formation of an active metabolite that affects the dose during chronic therapy. Therefore, the major factor altering the pharmacokinetic properties and the dose of the drug required is the capacity of the liver to metabolize the drug, which in turn depends on the hepatic blood flow and the activity of the hepatic metabolizing systems. Hence liver disease, a low cardiac output, and coadministration of certain drugs inducing or inhibiting the hepatic enzymes, all indirectly affect the pharmacokinetic properties of the calcium antagonists. There are also other potential drug interactions of a kinetic or dynamic nature that may arise. In general, renal disease has little effect on the pharmacokinetics of calcium antagonists.

Elimination and haemodynamic effects of nitrendipine in patients with chronic renal failure

In sixteen patients with arterial hypertension and differing degrees of renal function the pharmacokinetics and haemodynamic effects of nitrendipine have been studied after treatment for 7 days. The AUC (0-24) and the elimination half-life of nitrendipine were significantly increased; the AUC (0-24) in patients with renal failure (median creatinine clearance 27.1 ml x min-1) was 196 ng x ml-1 x h compared to 97.8 ng x ml-1 x h in control subjects (median creatinine clearance 94.4 ml x min-1). The corresponding elimination half-lives were 13.5 h in renal failure and 4.4 h in the controls. The haemodynamic effects of nitrendipine were not enhanced in the patients.

Angiotensin-converting enzyme inhibitors. Relationship between pharmacodynamics and pharmacokinetics

The inter-relationship between the pharmacokinetic and pharmacodynamic behaviour of ACE inhibitors is reviewed. First, some of the methods which have been used to assess the pharmacodynamics of ACE inhibitors in humans are presented. They include humoral assays (e.g. ACE activity in plasma, renin activity, etc.), haemodynamic changes (blood pressure, total peripheral resistance, etc.) and agonist challenges (angiotensin I infusions). Subsequently a pharmacokinetic-dynamic model is described, based on biochemical processes obtained after ACE inhibition, which seems to be useful for the interpretation of the complex processes. The various correlations between plasma drug concentration on the one hand and plasma ACE activity, angiotensin II concentration in plasma or blood pressure on the other, are discussed on the basis of this model. From the model obtained it becomes obvious that under many circumstances the release of the inhibitor from ACE binding is the step which in fact determines the pharmacodynamically relevant elimination rate of the drug at low concentrations, whereas at high concentrations the elimination of the drug is mainly dependent on kidney (and/or liver) elimination rate. The dynamic-kinetic correlations are then presented for some ACE inhibitors in various disease states: arterial hypertension, heart failure, old age, renal failure, liver disease. In a final section the kinetic and dynamic relevance of interactions of ACE inhibitors with food and other drugs is described (e.g. prostaglandin inhibitors, diuretics, digoxin and cimetidine). Despite the great body of literature which deals with the kinetic and/or dynamic properties of ACE inhibitors, precise knowledge of the relationship between their kinetic and dynamic behaviour is rather limited and there is a clear need for further studies to elucidate this complex topic, thereby improving therapeutic possibilities with these useful new compounds.