Clinical pharmacokinetics of disopyramide

Contribution of the α1-Acid Glycoprotein in Drug Pharmacokinetics: The Usefulness of α1-Acid Glycoprotein-Knockout Mice

α1-Acid glycoprotein (AGP) is a primary binding protein for many basic drugs in plasma. The number of drugs that bind to AGP, such as molecular target anticancer drugs, has been continuously increasing. Since the plasma level of AGP fluctuates under various pathological conditions such as inflammation, it is important to evaluate the contribution of AGP to drug pharmacokinetics. Here, we generated conventional AGP-knockout (AGP-KO) mice and used them to evaluate the contribution of AGP. The pharmacokinetics of drugs that bind to two AGP variants (F1*S or A variants) or albumin were evaluated. Imatinib (a F1*S-binding drug) and disopyramide (an A-binding drug) or ibuprofen (an albumin-binding drug) were administered to wild-type (WT) and AGP-KO. The plasma level of imatinib and disopyramide decreased rapidly in AGP-KO as compared to WT. In AGP-KO, AUC and t1/2 were decreased, then CLtot was increased. Compared with disopyramide, imatinib pharmacokinetics showed more marked changes in AGP-KO as compared to WT. The results seemed to be due to the difference in plasma level of each AGP variant (F1*S:A = 2-3:1). No differences were observed in ibuprofen pharmacokinetics between the WT and AGP-KO mice. In vitro experiments using plasma from WT and AGP-KO showed that unbound fractions of imatinib and disopyramide were higher in AGP-KO. These results suggest that the rapid elimination of imatinib and disopyramide in AGP-KO could be due to decreased protein binding to AGP. Taken together, the AGP-KO mouse could be a potential animal model for evaluating the contribution of AGP to the pharmacokinetics of various drugs.

Phosphate moiety in FDA-approved pharmaceutical salts and prodrugs

The salification and prodrug approaches modulate the physicochemical properties and absorption, distribution, metabolism, excretion, and toxicity parameters of drugs and lead candidates. The "phosphate" is one of the key counterions/promoiety used in the salt formation and prodrug synthesis. Salification with phosphoric acid enhances the aqueous solubility and thereby facilitates the administration of a drug by the parenteral route. Phosphate moiety in prodrug synthesis mainly improves permeability by lipophilic substitution. Histamine phosphate is the first phosphate salt, and hydrocortisone phosphate was the first prodrug approved by FDA in 1939 and 1952, respectively. The orange book enlists 12 phosphate salts and 17 phosphate prodrugs. Phosphate prodrugs, namely combretastatin A-4 diphosphate, combretastatin A-4 phosphate, lufotrelvir, TP-1287, pyridoxal phosphate, riboflavin phosphate, and psilocybin are clinical candidates. This review focuses on the FDA-approved phosphate salts and prodrugs from 1939 to 2021. The biopharmaceutical advantage of phosphate salts and prodrugs over the parent molecule is also deliberated.

A rapid and sensitive liquid chromatography/tandem mass spectrometry assay for simultaneous quantitation of disopyramide and its major metabolite, mono-isopropyl-disopyramide, in rat plasma and its application to a pharmacokinetic study

Disopyramide as an antiarrhythmic agent has been used for treating ventricular tachycardia and metabolized into its major metabolite, mono-isopropyl-disopyramide, by CYP3A4. We developed a novel, selective, highly sensitive, accurate, rapid method using liquid chromatography-tandem mass spectrometry (LC-MS/MS) for the simultaneous determination of disopyramide and mono-isopropyl-disopyramide in rat plasma. This study is the first report for the assay validation using LC-MS/MS in biological fluids after simple protein-precipitation method. The most sensitive signals by multiple reaction monitoring (MRM) showed at m/z 340.2 → 239.2 and 298.2 → 239.2 with same fragment ion for disopyramide and mono-isopropyl-disopyramide, respectively. The lower limit of quantification (LLOQ) was determined at 2 ng/mL for both analytes and the linear concentration ranges were found to be 2-2000 ng/mL for disopyramide and 2-1000 ng/mL for mono-isopropyl-disopyramide. Finally, this assay was successfully applied to pharmacokinetic analysis of disopyramide and mono-isopropyl-disopyramide after oral and intravenous administration of disopyramide.

Therapeutic drug monitoring: antiarrhythmic drugs

Antiarrhythmic agents are traditionally classified according to Vaughan Williams into four classes of action. Class I antiarrhythmic agents include most of the drugs traditionally thought of as antiarrhythmics, and have as a common action, blockade of the fast-inward sodium channel on myocardium. These agents have a very significant toxicity, and while they are being used less, therapeutic drug monitoring (TDM) does significantly increase the safety with which they can be administered. Class II agents are antisympathetic drugs, particularly the beta-adrenoceptor blockers. These are generally safe agents which do not normally require TDM. Class III antiarrhythmic agents include sotalol and amiodarone. TDM can be useful in the case of amiodarone to monitor compliance and toxicity but is generally of little value for sotalol. Class IV antiarrhythmic drugs are the calcium channel blockers verapamil and diltiazem. These are normally monitored by haemodynamic effects, rather than using TDM. Other agents which do not fall neatly into the Vaughan Williams classification include digoxin and perhexiline. TDM is very useful for monitoring the administration (and particularly the safety) of both of these agents.

Bioavailability of total and unbound disopyramide: implications for clinical use of the immediate and controlled-release dosage forms

This study further characterized the impact of concentration-dependent protein binding on the bioavailability and clinical use of the immediate-release (IR) and controlled-release (CR) dosage forms of disopyramide after single doses and during steady-state conditions in ten healthy volunteers. Consistent with the clinical use of these products, steady state has incorporated an IR to CR conversion step. Side effects and electrocardiographic actions were quantitated using a visual analog scale and serial Holter monitor recordings, respectively. Significant decreases resulted in area under the curve for total disopyramide between single dose and steady state: IR, 47.8 +/- 13.6 versus 33.0 +/- 6.4 mg/Lxh (P < .05); and CR, 46.9 +/- 9.5 versus 31.7 +/- 5.9 mg/Lxh (P < .05). In contrast, there were no differences in area under the curve for unbound disopyramide between phases or products. During conversion, the mean IR peak significantly decreased (P < .05) to the nadir before the first CR dose for total (37%) and unbound (60%) concentrations. There were no major differences in change in QT interval or side effects detected between products or phases. These findings indicate that, because of concentration-dependent protein binding, unbound, not total, concentrations should be used to estimate the bioavailability of disopyramide. Also, although the previously recommended conversion method (first CR dose 6 hours after the last IR dose) should provide an adequate transition in most, an alternative method (combined first CR with last IR dose) is indicated in select patients.

Importance of pharmacokinetic and physicochemical data in the discovery and development of novel anti-arrhythmic drugs

1. The importance of pharmacokinetics and physicochemical data in the discovery and development of a new mono-cationic antiarrhythmic agent, bidisomide (pKa 9.3), structurally related to the di-cationic anti-arrhythmic disobutamide (pKa of 8.6 and 10.2) and a mono-cationic drug disopyramide (pKa 10.4), is described. 2. In man, the di-cationic disobutamide was slowly eliminated with a mean terminal phase half-life of 54 +/- 18 h, a value > 7 times longer than disopyramide. The long terminal phase half-life of disobutamide is attributed to high accumulation of the drug in the tissues, a phenomenon attributed to the di-cationic nature. 3. Structural modification of disobutamide resulted in the mono-cationic agent bidisomide, designed to minimize drug accumulation in the tissues. Human studies with bidisomide confirmed that the terminal phase elimination of this drug was much faster than that of disobutamide, with a half-life of about 11h. The absolute bioavailability of bidisomide was 45-62% which is lower than that of disopyramide (60-90%). 4. Unlike disopyramide, absorption of bidisomide was complex, characterized by a lag period (0.75-1.5 h) before absorption, followed by occurrence of two peaks in the plasma concentration-time curves. 5. The characteristic double peaks found with bidisomide was attributed to two rapid absorption sites of the drug in the gastrointestinal tract.

Practical optimisation of antiarrhythmic drug therapy using pharmacokinetic principles

The optimisation of antiarrhythmic drug therapy is dependent on the definitions and methods of short term efficacy testing and the characteristics of those drugs used for rhythm disturbances. The choice of an initial antiarrhythmic drug dosage is highly empirical, and will remain so until the measurement of free concentrations, enantiomeric fractions and genetic phenotyping becomes routine. However, the clinician can devise an efficient initial dosage for efficacy testing procedures based on pharmacokinetic principles and disposition variables in the literature. In this regard, a nomogram for commonly used agents and dosages was constructed and is offered as a guide to accomplish this goal. Verification of the accuracy and usefulness of this nomogram in a prospective manner in patients with symptomatic tachyarrhythmias is still required. On a long term basis, dosage regimens can be modified by the use of pharmacokinetic principles and patient-specific target concentrations, in accordance with the methods used to monitor arrhythmia recurrence and drug-related side effects.

A comparison of the anticholinergic effects of two formulations of disopyramide in healthy volunteers

Eight healthy male volunteers took a single oral dose of one of the following: Rythmodan (conventionally formulated disopyramide) 150 mg; Rythmodan 250 mg; Rythmodan Retard (controlled-release disopyramide) 250 mg; placebo. The subjects were allocated double-blind to sessions and treatments according to a Latin square design. In each session pupil diameter, heart rate, salivation, and QT interval were measured immediately before and at 1, 2, 3, 4, 6, 8, and 24 h after the drug. QT interval was corrected for heart rate (QT60). Plasma concentrations of total and unbound disopyramide were also determined at each time point. Both formulations of disopyramide reduced salivary output and increased QT60 interval, but there was not significant difference between the effects of the three active treatments. Neither formulation had any effect on pupil diameter or heart rate. The peak plasma concentration of unbound disopyramide was reached 2 h after Rythmodan and 4 h after Rythmodan Retard. The peak plasma concentration of disopyramide was significantly lower after Rythmodan Retard 250 mg than after Rythmodan 250 mg. The plasma concentration of unbound disopyramide was positively correlated with the reduction in salivation and prolongation of the QT60 interval. The reduction in salivation is likely to reflect blockade of muscarinic receptors by disopyramide, whereas the increase in QT60 interval is likely to be related to a direct effect of the drug on the heart. The results of this single-dose study do not indicate that disopyramide in the controlled-release formulation would be better tolerated by patients than conventionally formulated disopyramide.

Study on transport of disopyramide into the intestinal lumen aimed at gastrointestinal dialysis by activated charcoal in rats

The characteristics of exsorption and/or excretion of disopyramide into the gastrointestinal lumen have been investigated after intravenous administration of the drug at doses of 10 and 30 mg kg-1 to rats by the in-situ single pass perfusion technique. Disopyramide was appreciably excreted into the bile where its levels were approximately ten-fold higher than those in the serum. The exsorption rate of disopyramide and mono-N-dealkyldisopyramide (MND) into the perfusate was increased with an increase in the serum level following an increase from 10 to 30 mg kg-1 in the dose of disopyramide. The average amounts of disopyramide exsorbed into the perfusate were 17.0 and 18.4% at the dose of 10 and 30 mg kg-1, respectively, whereas those of MND were less than 1% at both doses of disopyramide. Oral administration of activated charcoal reduced the serum disopyramide levels after intravenous administration of the drug (20 mg kg-1) compared with the control treatment. By oral administration of activated charcoal, t 1/2 and AUC were decreased to 89 and 82%, respectively, and Cltot was increased to 122% compared with the corresponding control treatment. Vd was not different between the treated rats and control rats. These results suggest that the oral administration of activated charcoal can enhance the clearance of disopyramide and MND from the blood.

Disposition kinetics of disopyramide in human healthy volunteers described by an open three compartment model

Disposition kinetics of disopyramide was examined in an open randomised cross-over study in 8 healthy volunteers. Disopyramide was randomly administered as a single bolus injection (150 mg) over a period of 5 min. and as an infusion (28.2) mg/h to steady state. Disposition kinetics of disopyramide were most precisely described by an open three compartment model according to Akaike's information criteria. Significant positive correlations (0.909 +/- 0.04, P less than 0.05 (injection study); 0.787 +/- 0.11, P less than 0.05 (infusion study] were observed between total serum concentrations of disopyramide and renal clearance while no significant correlation could be demonstrated between free serum concentrations and renal clearance. This implies a constant value of unbound renal clearance. The results are consistent with non linear kinetics (mainly caused by the variable free fraction of the drug), when based on total serum concentrations. The disposition of unbound disopyramide, however seems to be linear (i.e. the kinetic parameters are independent of dose) in the bolus injection study. Total elimination clearance (free and total), volume of distribution and elimination half-life were significantly higher in the steady state experiment than in the bolus injection study.

Does alpha 1-acid glycoprotein reduce the unbound metabolic clearance of disopyramide in patients with renal impairment?

The pharmacokinetics of disopyramide was studied in 15 patients with renal dysfunction (4 with pyelonephritis, 7 with glomerular nephritis and 4 with interstitial nephritis). The elimination rate constant of unbound disopyramide was 0.094 h-1 and CLu/f (unbound clearance divided by bioavailability) was 245 ml/min. Both the unbound renal clearance (CLR) and CLu/f were highly correlated with the creatinine clearance (CLCR). The apparent unbound metabolic clearance in the patients was approximately two-fold lower than that previously reported in normal subjects. The estimated unbound metabolic clearance in the renal dysfunction patients showed a significant negative correlation with the alpha 1-acid glycoprotein (AAG) concentration and only a weak, non-significant correlation with CLCR. As AAG in the renal dysfunction subjects was increased in comparison with normal values, it is possible that AAG is a factor in the decrease in the apparent unbound metabolic clearance.

Bioavailability of disopyramide in normal volunteers using unbound concentration

The pharmacokinetics of disopyramide were determined in 10 healthy volunteers after a 300 mg oral dose and again after a 2 mg/kg i.v. dose. The unbound clearance was 599 ml/min and the unbound renal clearance 310 ml/min. The terminal elimination rate constant of unbound drug was 0.180 h-1 after the i.v. dose and 0.203 h-1 after the oral dose. The absorption rate constant was 0.53(-1) and the maximum peak concentration occurred after 3.2 h. The bioavailability was 0.809 using the area under the unbound plasma concentration time curve. Although a saturable plasma protein binding was found in all subjects the bioavailability using the total concentration, in contrast to theoretical expectations, showed the same value (0.813) as the unbound concentrations.

Free drug concentration monitoring in clinical practice. Rationale and current status

Recent advances in techniques to determine free drug concentrations have lead to a substantial increase in the monitoring of this parameter in clinical practice. The majority of drug binding to macromolecules in serum can be accounted for by association with albumin and alpha 1-acid glycoprotein. Albumin is the primary binding protein for acidic drugs, while binding to alpha 1-acid glycoprotein is more commonly observed with basic lipophilic agents. Alterations in the concentrations of either of these macromolecules can result in significant changes in free fraction. Diseases such as cirrhosis, nephrotic syndrome and malnourishment can result in hypoalbuminaemia. Burn injury, cancer, chronic pain syndrome, myocardial infarction, inflammatory diseases and trauma are all associated with elevations in the concentration of alpha 1-acid glycoprotein. Treatment with a number of drugs has also been shown to increase alpha 1-acid glycoprotein serum concentrations. A wide variety of biological fluids have been examined for their ability to provide an estimation of free drug concentration at receptor sites. The most useful fluid for estimating free drug concentrations appears to be plasma or serum, with subsequent treatment of the sample to separate free and bound drug by an appropriate technique. The two most widely used methods are equilibrium dialysis and ultrafiltration. Of these two, ultrafiltration has the greatest utility clinically because it is rapid and relatively simple. The major difficulty associated with this method involves the binding of drug to the ultrafilters, but significant progress has been made in solving this problem. Several authors have endorsed the routine use of free drug concentration monitoring. Data examining the clinical usefulness of free drug concentration monitoring for phenytoin, carbamazepine, valproic acid, disopyramide and lignocaine (lidocaine) are reviewed. While available evidence suggests that free concentrations may correlate with clinical effects better than total drug concentrations, there are insufficient data to justify the recommendation of the routine use of free drug concentration monitoring for any of these agents at present.

Pharmacologically active conformation of disopyramide: evidence from apparent pKa measurements

We have found evidence that an intramolecular hydrogen bond exists between the amido and pyridine groups of disopyramide in aqueous solutions. This conclusion was reached by a comparison of the pKa values for the basic nitrogen atoms of certain analogues of disopyramide. By comparing the pharmacological actions of disopyramide with those of pheniramine, which lacks an amido group, we have concluded that the constraint on the rotation of the pyridine ring which is imposed by the hydrogen bond is a major determinant of the antiarrhythmic activity. That constraint is, at the same time, a suppressor of the anticholinergic activity. We then concluded that a covalent link would hold the pyridine ring, and the amido group, in the desirable conformation permanently, which would lead to better antiarrhythmic activity and a lower degree of anticholinergic activity. Pharmacological studies on such new molecules are in general agreement with these concepts.

Kinetics of disopyramide after intravenous infusion to patients with myocardial infarction and heart failure

Total body clearance, half-life and volume of distribution of disopyramide (Norpace, Searle G.D.) was measured during a six to eight hour infusion to steady state in twenty four patients with either congestive heart failure or acute myocardial infarction and compared to eleven patients without these diseases. All patients were given a bolus injection of 150 mg disopyramide followed by a continuous infusion of 18-24 mg per hour. Serum concentration of disopyramide and its main dealkylated metabolite were determined by HPLC. The clearance in patients without myocardial infarction or congestive heart failure was 1.71 +/- 0.60 ml/min./kg (mean +/- S.D.), not significantly different from those who had either myocardial infarction, congestive heart failure or both. Half-life was 798 min. in patients without heart failure, not significantly different from the values in the other groups. The ratio between disopyramide and its metabolite varied between 3 to 10. Twenty-six % of the steady state serum concentrations of disopyramide were outside the recommended therapeutic range (2-5 micrograms/ml), but no adverse haemodynamic effects were observed in any of the patients. The suggested dosage regimen of disopyramide seems to result in a satisfactory response.

Atenolol inhibits the elimination of disopyramide

The effect of atenolol on the total elimination of disopyramide and its main dealkylated metabolite was studied in 6 patients and 3 volunteers. During administration of 50 mg atenolol b.i.d. the clearance of disopyramide decreased significantly (p less than 0.02) from 1.90 +/- 0.71 (mean +/- SD) to 1.59 +/- 0.68 ml/kg/min, while its half-life, concentration of the metabolite, and the volume of distribution remained unchanged. The reduction in the clearance of disopyramide by atenolol might contribute to the alleged pharmacodynamic interaction between disopyramide and beta-blocking drugs.

Prediction of the volumes of distribution of basic drugs in humans based on data from animals

The apparent volume of distribution-after distribution equilibrium and the ratio of distributive tissue volume to the unbound fraction in the tissue (VT/fuT) of 10 weak basic drugs, i.e., chlorpromazine, imipramine, propranolol, disopyramide, lidocaine, quinidine, meperidine, pentazocine, chlorpheniramine, and methacyclin were compared in animal species and humans. In these two parameters, a statistically significant correlation between animals and humans was obtained, when the parameters were plotted on a log-log scale. The correlation coefficient between VT/fuT was significantly higher than that between the apparent volumes of distribution (p less than 0.05). In general, there was little difference between VT/fuT of various basic drugs in animals and that in humans. Prediction of the apparent volume of distribution in humans using animal data of VT/fuT, plasma unbound fraction, blood volume, and blood-to-plasma concentration ratio in humans was successful for most of drugs studied.

Pharmacokinetic-pharmacodynamic analysis of unbound disopyramide directly measured in serial plasma samples in man

The pharmacokinetics and pharmacodynamics of the antiarrhythmic drug, disopyramide, were investigated in 12 volunteers who took 300 mg doses of 3 different capsule preparations and an aqueous oral solution of the drug at 1-week intervals. Concentrations of drug unbound to plasma proteins were measured by a sensitive immunoenzyme assay after ultrafiltration of plasma samples taken serially after dosing. QT interval was measured on serial ECG recordings with correction for changes in heart rate. Unbound concentrations of disopyramide were modelled by an open one-compartment pharmacokinetic model with a zero-order absorption rate and a lag time. There was no significant difference in parameter estimates between the four preparations, except for the lag time, which was significantly shorter for the solution preparation. The saturable protein binding of disopyramide was described by a hyperbolic model including a specific binding site and additional nonspecific binding. The pharmacodynamic relationship between unbound drug concentration and QT prolongation was fit by a simple linear model. This fit was better using unbound concentration of the drug than using total concentrations.

Simultaneous quantitation of disopyramide and its mono-dealkylated metabolite in human plasma by fused-silica capillary gas chromatography using nitrogen-phosphorus specific detection

A nitrogen-specific detector gas-liquid chromatographic assay method is reported which provides improved selectivity and sensitivity for disopyramide and its mono-N-dealkylated metabolite using a crosslinked fused-silica capillary column. The quantitation of disopyramide and mono-N-dealkylated disopyramide was accomplished by injecting trifluoroacetic anhydride-treated samples containing derivatized internal standard p- chlorodisopyramide , into a gas chromatograph equipped with a nitrogen--phosphorus detector and an automatic liquid sampler. A 25 m X 0.31 mm crosslinked, 5% phenylmethyl silicone-coated fused-silica column was utilized and samples were injected using the splitless injection mode. Linearity was observed in the range 0.05-5.00 micrograms/ml for disopyramide and 0.02-3.00 micrograms/ml for the mono-N-dealkylated metabolite. The coefficient of variation was found to be within 10% for both compounds in the concentration range studied.

Circadian phase dependent pharmacokinetics of disopyramide in mice

The focus of the reported work is investigation of disopyramide chronopharmacokinetics in the mouse. Different groups of male NMRI mice maintained under controlled environmental conditions (LD: 0600-1800) received a single intraperitoneal injection of disopyramide (30 mg per kg of body weight) at one of four different fixed time points of a 24-h period, i.e. 1000, 1600, 2200 or 0400. Blood samples were taken 0.5, 1, 2, 3, 4 and 6 hr after drug administration and total and free plasma levels of disopyramide were measured by an immunoenzymatic method. Our data showed statistically significant circadian rhythms in the following pharmacokinetic parameters: highest volume of distribution = 3.91 +/- 0.21 l kg-1 at 2200 (circadian amplitude, half the peak-to-trough difference relative to the 24-hr mean multiplied by 100, is 34%); highest area under concentration curves = 16.06 +/- 1.03 micrograms ml-1 hr-1 at 0400 (circadian amplitude = 43%) and highest clearance = 3.04 +/- 0.19 l hr-1 kg-1 at 2200 (circadian amplitude = 21%). Protein binding of the drug was shown to be circadian time dependent. Alpha and beta phase elimination half-lives were not found to be significantly circadian phase-dependent. Thus circadian changes in disopyramide clearance may represent circadian changes in the drug's volume of distribution.