Disposition of amiodarone and its proximate metabolite, desethylamiodarone, in the dog for oral administration of single-dose and short-term drug regimens

A comparative study of the plasma disposition and tissue distribution of amiodarone and its proximate metabolite, desethylamiodarone, for a single oral dose and short-term oral dosage regimens was conducted in the dog. Four groups of male mongrel dogs (six per group) received one of the following oral dosage regimens: single dose of 40 mg amiodarone/kg; 40 mg amiodarone/kg/day for 10 days and then 30 mg/kg/day for 4 days; 40 mg amiodarone/kg/day for 10 days, 30 mg/kg/day for 4 days, and then no treatment for 14 days; and 40 mg amiodarone/kg/day for 10 days, 30 mg/kg/day for 4 days, and then 20 mg/kg/day for 5 days/week for 2 weeks. The plasma and tissue amiodarone and desethylamiodarone concentrations were determined by HPLC. The plasma concentration of amiodarone was greater than that of desethylamiodarone for the four dosage regimens. The apparent plasma elimination half-life of amiodarone was prolonged following repeated drug administration (3.2 days) compared with a single drug dose (7.5 hr). There was extensive extravascular distribution of amiodarone and desethylamiodarone resulting in progressive tissue accumulation of drug and metabolite for the short-term regimens. For most of the dosage regimens, the concentration of amiodarone was greater than that of desethylamiodarone in left and right ventricles, thyroid gland, adipose tissue, and kidney, whereas the parent drug and metabolite concentrations were similar in lung, liver, and brain. There was predominant accumulation of amiodarone in adipose tissue and desethylamiodarone in lung. After cessation of amiodarone administration, there was rapid elimination of parent drug and metabolite from all tissues, except for amiodarone from adipose tissue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics and body distribution of amiodarone and desethylamiodarone in rats after oral administration

The pharmacokinetics and body distribution of amiodarone and desethylamiodarone were studied in rats after single oral administration of 100 mg/kg and 200 mg/kg of amiodarone. The time-course of the concentrations of the drug and its main metabolite was determined by high performance liquid chromatography in serum and tissues up to 24 h. The mean absorption half-life of amiodarone was 1.83 h for both dosages and the mean elimination half-life was 15 h after the 100 mg/kg dosage and 105 h after the 200 mg/kg dosage. The mean bioavailability of oral amiodarone ranged from 17% to 60% with an average of 39%. Desethylamiodarone, the major metabolite of amiodarone, was present over the 24 h period of observation in relatively low levels of 30 to 60 ng/ml after the 100 mg/kg dose and 50 to 110 ng/ml after the 200 mg/kg dose respectively, which is circa 4% and 7% of the corresponding parent drug level. Amiodarone is preferentially distributed in decreasing order in lung, liver, thyroid gland, kidney, heart, adipose tissue, muscle tissue and brain. The metabolite desethylamiodarone exhibited a distribution pattern comparable to the parent drug. However, its maximum concentrations in serum and tissues were consistently lower than the corresponding amiodarone concentrations and varied from 18 to 55% (mean 27%), depending on the acute oral dose applied and on the kind of tissue. The amiodarone tissue/serum concentration ratios were high in lung tissue (60-100) and moderate to high in the other tissues except brain (3-60), and indicate an extensive distribution of the drug with the lung as an organ with specific binding sites or uptake mechanisms and adipose tissue as a reservoir with a large storage capacity. The metabolite tissue/serum concentration ratios were very high in lung tissue (500-800), high in renal, thyroid, liver and adipose tissue (80-200) and moderate in the other tissues except for brain (20-60); they indicate a very extensive distribution of desethylamiodarone with, primarily, lung and to some lesser extent kidney, liver and thyroid gland as organs with sites of metabolism and/or specific binding sites or uptake mechanisms and fat as a reservoir for the drug. A marked increase in the accumulation of amiodarone and desethylamiodarone was observed in adipose tissue after chronic oral administration, whereas the rise in kidney and brain was less pronounced and in the remaining tissues it was insignificant. Our data suggest that the rat is a good model for describing the single oral dose pharmacokinetics and body distribution of amiodarone and desethylamiodarone in man.     

Myocardial amiodarone concentrations after short- and long-term treatment in patients with end-stage heart failure

Background: Pharmacokinetics and tissue concentrations of amiodarone may vary considerably in end-stage heart failure, but may be crucial for treatment efficiency and antiarrhythmic drug therapy. Objective: This study was undertaken to determine plasma amiodarone and desethylamiodarone concentrations and to determine whether they correlate with myocardial concentrations in explanted hearts from patients with end-stage heart failure. Patients and methods: Eight patients with idiopathic dilated cardiomyopathy and normal coronary arteries were included in the present study. Myocardial tissue samples (seven sites) and epicardial fat were taken from each explanted heart, and drug concentrations of amiodarone and desethylamiodarone were determined. In addition, plasma drug levels were measured and compared with the myocardial amiodarone/desethylamiodarone concentrations. Results: The mean cumulative amiodarone dose was 91 g and the mean plasma concentrations of amiodarone and desethylamiodarone were 0.68 and 0.84 μg · ml⁻¹, respectively. The tissue concentrations of amiodarone amounted to 13.2 and 28.3 μg · g⁻¹, respectively, in the atria and to 13.0 and 40.8 μg · g⁻¹, respectively, in the ventricles. The distribution of the drug and its metabolite were similar in the right and left ventricles. There was a good correlation between myocardial concentration of amiodarone and desethylamiodarone and the cumulative ingested dose of amiodarone. Tissue drug concentrations correlated only poorly with plasma amiodarone or desethylamiodarone levels. The highest drug levels were measured in the epicardial fat tissue, where the ratio of amiodarone 105 μg · g⁻¹ to desethylamiodarone 32 μg · g⁻¹ was reversed (3.3 compared with 0.29 in the ventricles). Thus, amiodarone concentrations in epicardial fat were approximately 10 times higher than myocardial and 150 times higher than plasma levels. Conclusions: Our data confirm the slow equilibrium of amiodarone and desethylamiodarone concentrations between plasma and myocardium. Myocardial tissue concentrations of desethylamiodarone and, to a lesser degree, amiodarone correlate with the cumulative ingested dose of amiodarone. Monitoring of the total cumulative dose may be more relevant clinically than monitoring plasma levels. These results support the clinical practice of reducing the maintenance dose of amiodarone in patients who are on long-term treatment. Received: 12 July 1997 / Accepted in revised form: 25 September 1997     

Individual variability of amiodarone distribution in plasma and erythrocytes: implications for therapeutic monitoring

The complexity of amiodarone disposition in blood and tissues gives rise to difficulty in determination of optimal therapeutic monitoring strategies. We have defined the within-patient variability of plasma and erythrocyte amiodarone and desethylamiodarone concentrations and electrocardiogram intervals [PR and corrected QT (QTc)] in 27 patients each sampled on three to four occasions during long-term stable amiodarone therapy. All individual repeated measurements were included in the concentration-effect analysis. The mean within-patient coefficients of variation for amiodarone and desethylamiodarone were significantly greater in erythrocytes, 46.0 and 24.5%, respectively, compared with plasma, 12.7 and 12.3%. Amiodarone and desethylamiodarone were significantly greater in erythrocytes, 46.0 and 24.5%, respectively, compared with plasma, 12.7 and 12.3%. Amiodarone and desethylamiodarone were strongly correlated (r = 0.29 p less than 0.004). There was a 10-fold variability in erythrocyte amiodarone for a given plasma level. These data emphasize the highly variable cellular distribution of amiodarone and desethylamiodarone in the same patient on stable dosage over time. Plasma amiodarone was significantly correlated with dosage (r = 0.98), and percent change in QTc, (r = 0.56, p less than 0.0001), but there was a fourfold variation in plasma amiodarone for a given QTc. Side-effect frequency was not related to plasma or erythrocyte amiodarone or desethylamiodarone concentrations. A clinically useful relationship between plasma concentration and effect could not be consistently demonstrated for amiodarone in the same individual during stable dosage.     

Digoxin-desethylamiodarone interaction in the rat: comparison with the effects of amiodarone

We have shown that there is a pharmacokinetic interaction between amiodarone and digoxin that results in an increase in steady-state serum and tissue concentrations of digoxin in rats. There is a linear correlation between serum levels of amiodarone, as well as desethylamiodarone, and steady-state serum digoxin levels in rats treated with amiodarone. Since desethylamiodarone is formed in amounts equal to that of the parent compound during chronic amiodarone therapy, we investigated the possibility of desethylamiodarone directly interacting with digoxin in rats. Rats that received digoxin alone showed a serum level of 0.32 +/- 0.08 ng/ml, whereas those that received combination therapies showed a serum level of 3.25 +/- 1.06 ng/ml (p less than 0.001) with desethylamiodarone administration, and 3.00 +/- 0.87 ng/ml with amiodarone administration. Concomitant administration of desethylamiodarone and digoxin increased digoxin concentration in the myocardium by 110% (p less than 0.001), in the skeletal muscle by 208% (p less than 0.001) and in the brain by 110% (p less than 0.001). The corresponding figures for amiodarone-digoxin administration were 94% (p less than 0.001), 172% (p less than 0.001) and 80% (p less than 0.001). The tissue/serum ratios of digoxin concentrations in the myocardium, skeletal muscle, and brain were decreased in the rats that received combination therapies, indicating reduced tissue binding of digoxin. The data indicate that desethylamiodarone interacts with digoxin in a manner similar to that of the parent compound.     

Tissue uptake and metabolism of amiodarone after chronic administration in rabbits

This study was designed to determine serum and tissue concentrations of amiodarone and its metabolite desethylamiodarone after chronic amiodarone administration in rabbits. Rabbits were administered 20 mg/kg amiodarone for 6 weeks. Serum, liver, kidney, heart, lung, spleen, bile, adipose tissue, and muscle were collected upon sacrifice. Amiodarone and desethylamiodarone concentrations were determined in serum and tissues by an HPLC procedure standardized in our laboratory. Amiodarone concentrations were the highest in fat tissue followed by lung, liver, and muscle, with the lowest concentration in serum and only traces in the brain. Desethylamiodarone concentrations in liver, lung, and kidney approached those of the parent drug while the metabolite was present in negligible amounts in fat tissue and in brain. Bile from amiodarone-treated rabbits showed the presence of two more new metabolites which have not been characterized. Desethylamiodarone/amiodarone ratios in serum and tissues after chronic administration in rabbits were lower than in man. Nevertheless, differential accumulation of amiodarone and desethylamiodarone may be relevant to efficacy and toxicity studies.     

Amiodarone pharmacokinetics in coronary patients: differences between acute and one-month chronic dosing

The pharmacokinetics of amiodarone (A) and its desethylamiodarone metabolite (DEA) were compared in the same coronary patients after a first 1000 mg dose and one-month chronic oral dosing. Terminal half-life (t1/2 el) of amiodarone increased from a mean (SD) 24.1 +/- 19.5 h after the first dose to 20.4 +/- 4.8 days after the last dose. Desethylamiodarone slowly appeared in the plasma after the first oral dose and its apparent t el was 61.6 +/- 26.6 h. After one-month dosing apparent t1/2 el of desethylamiodarone increased to 29.5 +/- 9.7 days. Mean maximal plasma amiodarone/desethylamiodarone concentration ratio decreased from 9.2 +/- 5.0 to 2.0 +/- 0.6 after chronic dosing. This change was mainly related to an increase in the plasma concentration of desethylamiodarone. These data suggest that after long-term treatment with amiodarone, the complete elimination of the drug and its metabolite may need 3-4 months in some patients. The results of this study were presented in part at the meeting of the Societe Francaise de Therapeutique et de Pharmacologie Clinique, Paris, December 1985.     

Pharmacokinetics and body distribution of amiodarone and desethylamiodarone in rats after intravenous administration

The pharmacokinetics and body distribution of amiodarone and desethylamiodarone were investigated in rats following a single intravenous dose of 100 mg/kg and 150 mg/kg of amiodarone. The decline in serum and tissue concentrations of amiodarone and desethylamiodarone are described by biexponential functions. All aspects of the typical kinetic profile of the drug and its major metabolite, desethylamiodarone, are discussed. Amiodarone is preferentially distributed in decreasing order in thyroid gland, lung, kidney, liver, heart, adipose tissue, skeletal muscle and brain. The metabolite desethylamiodarone showed a distribution pattern which is similar to that observed for the parent drug. Our study indicates an extensive distribution of amiodarone, with the thyroid gland and lung as organs with specific binding sites or uptake mechanisms and adipose tissue as a depot with a large storage capacity. We also found a very extensive distribution of the metabolite desethylamiodarone with mainly lung and thyroid gland and to some lesser extent kidney, liver and heart as organs with sites of metabolism and/or specific binding sites or uptake mechanisms and fat as a reservoir for the drug. Our data demonstrate the advantages of intravenous loading dosages of amiodarone over oral doses, since considerably higher and longer lasting effective serum and tissue concentrations of amiodarone are reached while lower quantities of the less cardio-active metabolite are formed.     

Effect of blood sample tubes on amiodarone and desethylamiodarone concentrations

We have investigated the change in amiodarone and desethylamiodarone concentrations in blood sampled from three different Vacutainer tubes: (a) sodium heparin, (b) gel separator (SST), and (c) no additive (plain tube). Amiodarone and desethylamiodarone concentrations were determined by a reverse-phase high pressure liquid chromatography technique in samples from 12 subjects on chronic amiodarone therapy. Amiodarone concentrations were significantly lower in plasma compared with serum from either gel separator (11.5%, p = 0.05) or no additive (13.5%, p = 0.01) tubes. Desethylamiodarone concentrations were significantly lower in plasma compared with serum from gel separator tubes (8.5%, p = 0.04) and were slightly lower compared with no additive tubes (4.4%, p = 0.41). Serum amiodarone and desethylamiodarone concentrations from either no additive or gel separator tubes yielded similar results. We conclude that significant amiodarone and desethylamiodarone concentration differences occur between serum and plasma, and that no binding of amiodarone and desethylamiodarone to the separator gel occurs.     

Amiodarone and desethylamiodarone concentrations in plasma and tissues of surgically treated patients on long-term oral amiodarone treatment

The tissue disposition of amiodarone and its metabolite desethylamiodarone was studied in 12 surgical patients with various types of arrhythmias after chronic oral treatment with amiodarone. Amiodarone and desethylamiodarone concentrations in plasma and tissues were determined using a simple and sensitive high performance liquid chromatographic method. The mean plasma level of amiodarone and desethylamiodarone was found to increase from 0.55 microgram/ml to 1.40 microgram/ml and 0.68 microgram/ml to 1.80 microgram/ml for the respective components following the increase of the daily oral dose from 200 mg to 600 mg of amiodarone and indicates a linear relationship between plasma concentrations and dose. The mean levels of both drugs in different parts of the heart varied for amiodarone from 15 to 48 micrograms/g and for desethylamiodarone from 48 to 71 micrograms/g, with the highest values present in the epicardially resected ventricular myocardium. The mean cardiac tissue/plasma ratios ranged for amiodarone from 12 to 35 and for desethylamiodarone from 35 to 61 and show an extensive tissue uptake in the different parts of the heart for both drugs, with the metabolite accumulation 2 to 5 times higher than the parent compound. Relatively low levels, ranging for amiodarone from 2 to 15 micrograms/g and for desethylamiodarone from 5 to 25 micrograms/g, were observed in skeletal muscle, epidermis, skin and femoral artery. By far the largest content of the drugs was found in adipose tissue with mean concentrations of 207 +/- 98 micrograms/g and 82 +/- 43 g/g respectively for the parent compound and its metabolite, which suggests that fat constitutes the main depot of the drugs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tissue distribution of amiodarone and desethylamiodarone in rats after multiple intraperitoneal administration of various amiodarone dosages

Tissue distribution of amiodarone (Cordarone) and desethylamiodarone in the rat was studied after repeated intraperitoneal administration of the drug. Tissue and serum concentrations of amiodarone and desethylamiodarone were determined by high-performance liquid chromatography. The levels of amiodarone and desethylamiodarone in serum and tissues obtained after repeated intraperitoneal application of doses varying from 25 mg to 200 mg/kg show that the accumulation of amiodarone and desethylamiodarone in the rat is dose-dependent and both drugs are preferentially distributed in decreasing order in adipose tissue, lung, liver, kidney and thyroid gland. The penetration of the drug and its metabolite into brain was poor and with all the applied dosages brain levels were considerably lower than the corresponding serum levels. Desethylamiodarone serum and tissue concentrations were substantially lower than the corresponding amiodarone concentrations and varied from 1 to 48% (mean 15%) depending on the dosage used and the kind of tissue. The amiodarone tissue/serum concentration ratios were exceptionally high in adipose tissue (1,000-4,000) and moderate to high in the other tissues except brain (5-90), and indicate an extensive distribution of the drug with fat as a reservoir with a large storage capacity. The levels of amiodarone and desethylamiodarone, obtained with 50 mg/kg and 100 mg/kg dosages, showed in function of time clearly an increase in serum and tissues. The observed amiodarone tissue/serum ratios in function of time revealed no further significant increase (p less than or equal to 0.05) after 3 injections over a 6-day period, indicating the attainment of "steady-state".(ABSTRACT TRUNCATED AT 250 WORDS)     

Lack of interaction between amiodarone and mexiletine in cardiac arrhythmia patients

Amiodarone has pharmacokinetic interactions with various therapeutic agents, including phenytoin, flecainide, and cyclosporine. Mexiletine is metabolized by CYP2D6 and CYP1A2. The objective of this study is to evaluate the effect of amiodarone on the pharmacokinetics of mexiletine through its inhibition of various cytochrome P450 (CYP) subtypes. In a series of 181 inpatients with supraventricular tachyarrhythmias, 26 inpatients received mexiletine and amiodarone therapy (MEX + AMD group), and the others received mexiletine therapy (MEX group). In 10 inpatients of the MEX + AMD group, the mexiletine clearance (CL(MEX)/F) before and after coadministration of amiodarone was compared. CL(MEX)/F was also compared in the MEX and MEX + AMD groups after the start of amiodarone therapy. Serum mexiletine, amiodarone, and desethylamiodarone concentrations were measured by an HPLC method. The CL(MEX)/F was estimated by the Bayesian method using population pharmacokinetic analysis. There was no significant difference in CL(MEX)/F before and after 1-month coadministration of amiodarone in 10 inpatients of the MEX + AMD group. Although serum amiodarone and desethylamiodarone concentrations gradually increased with time after the start of amiodarone therapy in these patients, CL(MEX)/F showed no change at 3 and 5 months after the start of amiodarone therapy. There was no significant difference in CL(MEX)/F of the MEX group and the MEX + AMD group. The results suggest that the pharmacokinetics of mexiletine is not affected by amiodarone in patients with cardiac arrhythmias.     

Impact of rifampin on serum amiodarone concentrations in a patient with congenital heart disease

A 33-year-old woman with congenital heart disease and atrial and ventricular arrhythmias, managed over the long term with an implantable cardioverter defibrillator, epicardial pacing system, and amiodarone, experienced an increase in palpitations and a shock from her defibrillator. Evaluation revealed decreases in amiodarone and desethylamiodarone serum concentrations from previous levels. Rifampin had been added to her therapy 5 weeks earlier. Increases in amiodarone and desethylamiodarone concentrations were observed after an increase in the amiodarone dosage and discontinuation of rifampin. The time course suggested that the addition of rifampin led to reductions in serum concentrations of both the drug and metabolite.     

Simultaneous determination of amiodarone and desethylamiodarone in human plasma by high performance liquid chromatography.

A rapid, sensitive and specific reversed phase HPLC method for the simultaneous assay of amiodarone and its major metabolite desethylamiodarone in human serum has been developed. This method is suitable for pharmacokinetic studies and for monitoring of the drug and metabolite concentrations in serum of patients on both short and long-term therapy with amiodarone.     

Tissue Drug Accumulation and Ultrastructural Changes during Amiodarone Administration in Rats

Pulmonary and hepatotoxicity arc the two major side effectsof chronic amiodarone therapy. We studied the accumulation ofamiodarone and its principal metabolite, desethylamiodarone,in lung and liver of rats treated ip for 21 to 23 days witheither 40 or 80 mg/kg/day amiodarone. The ultrastructural changesin liver, lung, and alveolar macro-phages in saline controlsand in rats on the two amiodarone dosage regimens were investigated.There was a dose-dependent increase in amiodarone and desethylamiodaronelevels in serum and in tissues. The desethylamiodarone/amiodaroneratios in liver and lung, but not in serum, increased significantlywith increasing dose. Serum also contained another metabolite,mono-deiodinated desethylamiodarone. Increase in vacuolizationand presence of whorled lamellar inclusion bodies in alveolarmacrophages occurred with an increase in dose and higher lungamiodarone and desethylamiodarone levels. Electron microscopyof the liver of amiodarone-treated rats revealed the presenceof large inclusion bodies partially filled with amorphous materialin the cytoplasm. The quantitative relationship of the abovechanges to organ toxicity and to phospholipidosis that accompaniesamiodarone administration remains to be established.     

Pharmacokinetics of amiodarone,desethylamiodarone and other iodine-containing amiodarone metabolites

Summary In 23 patients treated with the iodine-containing antiarrhythmic drug amiodarone, the plasma concentrations of amiodarone, desethylamiodarone and iodine have been studied. Besides amiodarone and desethylamiodarone, a pool of iodine-containing substances, NANDAI (non-amiodarone-, non-desethylamiodarone-iodine), was present. At steady state the iodine content of NANDAI amounted to 64% and the iodine content of amiodarone plus desethylamiodarone to 36% of total serum iodine. At steady state 26% of the NANDAI fraction was made up of inorganic iodide, the average plasma concentration of which was at least 40 times above the upper limit of the normal range. The serum elimination half-life of NANDAI of 57–160 days exceeded that of amiodarone (35–68 days) and of desethylamiodarone (31–110 days).At steady state the serum concentration of desethylamiodarone appears to be related to the concentration of amiodarone by a Michaelis-Menten type function, yielding a Km of amiodarone of 2.45 µmol/l and a maximal desethylamiodarone concentration of 3.61 µmol/l.     

Amiodarone pharmacokinetics. I. Acute dose-dependent disposition studies in rats

Single intravenous bolus doses of amiodarone hydrochloride of 30, 60, 90 and 120 mg/kg were administered to male Sprague-Dawley rats to determine the effects of dose on amiodarone pharmacokinetics. Serial blood samples and total urine were collected over 48 hr and assayed for amiodarone and desethylamiodarone by HPLC. The blood amiodarone concentration-time curves for the four doses were best described by a triexponential equation with terminal half-lives (t1/2 gamma) ranging from 17 to 20 hr. Over the dose range studied, no changes in gamma, t1/2 gamma, or central compartment volume (Vc = 1.2-1.4 L/kg) were observed. On the other hand, reductions in amiodarone clearance (CL) and steady-state volume of distribution (Vss) of 44% (17.7 to 10.0 ml/min per kg) and 50% (16.4 to 8.2 L/kg), respectively, were noted as the dose of amiodarone increased. The conversion of amiodarone to desethylamiodarone (fm) was dose-independent and amounted to approximately 10% of each amiodarone dose. No amiodarone or desethylamiodarone was detected in the urine of any of the treated animals. The blood-to-plasma concentration ratio of amiodarone was concentration-independent and therefore did not account for the dose-dependent changes in Vss and CL observed. The data suggested that the dose-dependent changes noted were due to an alteration in the volume (s) of the peripheral tissue compartment(s).     

Cytotoxic effects of amiodarone and desethylamiodarone on human thyrocytes

Since recent in vivo evidence suggests that the benzofuran antiarrhythmic drug amiodarone has a direct toxic effect on the human thyroid gland, we have investigated the effects of both amiodarone and its metabolite desethylamiodarone on a novel immortalized functional human thyrocyte line (SGHTL-34 cells). Desethylamiodarone markedly reduced cell number as assessed from both DNA and protein content. Few cells were left after 24 hr exposure to 12.5 micrograms/ml; the concentration producing death of 50% of cells (EC50) was 6.8 +/- 1.1 micrograms/ml (mean +/- SE, N = 15). Amiodarone was much less potent, producing a maximum decrease in cell number of approximately 25% at concentrations up to 50 micrograms/ml. The effect of desethylamiodarone was seen within 24 hr of culture. T3 in concentrations up to 0.75 micrograms/ml had no effect on the action of amiodarone or desethylamiodarone on SGHTL-34 cells. Light microscopy demonstrated vacuolation of SGHTL-34 cells after 4-day culture with either the drug or its metabolite. Studies using primary cultures of human retroorbital fibroblasts demonstrated that the greater cytotoxicity of desethylamiodarone was not confined to thyrocytes. When SGHTL-34 cells were incubated with 2.5 micrograms/ml desethylamiodarone for 4 days, 71.7 +/- 0.9% was taken up by the cells; there was no detectable conversion to amiodarone. Incubation of thyrocytes with 50 micrograms/ml amiodarone for 4 days resulted in the uptake of 80.1 +/- 2.1% by the cells. In addition, 5.0 +/- 0.1% of the amiodarone was converted to material with the same retention time as desethylamiodarone standard; of this material, 72.9 +/- 2.8% was taken up by the cells. We conclude that desethylamiodarone, at concentrations near those found in the plasma of patients on long-term amiodarone therapy, exerts a direct cytotoxic effect on human thyroid cells in short-term culture. This effect may play a role in the aetiology of clinical thyroid disease during amiodarone therapy. We suggest that, since the effect is not restricted to thyrocytes, desethylamiodarone may play a role in the aetiology of amiodarone toxicity which occurs clinically in many tissues.     

Peripheral neutrophil inclusions in amiodarone treated patients.

In 14 patients receiving chronic amiodarone therapy the appearance of multilamellar inclusion bodies in peripheral blood neutrophils was related to both plasma concentrations of amiodarone and its desethyl metabolite and unwanted effects of the drug. Seven of the patients had well defined inclusion bodies. In this group mean amiodarone and desethylamiodarone concentrations were significantly higher than in the remaining seven patients and all but one had unwanted effects of the drug. Of the seven patients without inclusion bodies only one, with high plasma amiodarone and desethylamiodarone concentrations, had unwanted effects of the drug. It is concluded that the appearance of multilamellar bodies in the blood neutrophils of amiodarone-treated patients may help to distinguish those patients at risk of long-term amiodarone toxicity.     

Basic and clinical pharmacology of amiodarone: relationship of antiarrhythmic effects, dose and drug concentrations to intracellular inclusion bodies

Amiodarone is a unique class III antiarrhythmic drug with several unusual pharmacokinetic, pharmacodynamic, and toxicological actions which are quite distinct from those of the standard antiarrhythmic drugs. Extensive animal and clinical studies have demonstrated that amiodarone and its major metabolite, desethylamiodarone, both produce a marked increase in the duration of transmembrane action potential, which may be related to their antiarrhythmic as well as clinical electrophysiological activity. Unlike most other cardiovascular drugs, it has been recognized for more than 20 years that optimal antiarrhythmic effects may take several days to weeks after onset of oral therapy. Amiodarone is highly lipid soluble and exhibits at least three separate compartments of drug distribution, with a long elimination half-life of 14-120 days after chronic therapy. The pharmacokinetic profile of desethylamiodarone is qualitatively similar to that of amiodarone, but its elimination half-life is even longer and its tissue distribution may be slightly different. Although there may not be any correlation between serum drug levels and clinical toxicity of amiodarone during long-term therapy, recent animal as well as clinical data suggest that multilamellar intracellular inclusions can be dissociated from cell death or clinical toxicity. Thus, it is possible that amiodarone toxicity can be minimized with low doses or low serum drug concentrations. The metabolite(s) of amiodarone may play a major role in its pharmacological and toxicological actions.