Evaluation of selective competitive binding of basic drugs to alpha1-acid glycoprotein variants.

We examined the binding of various basic drugs to the F(1)S and A genetic variants of alpha(1)-acid glycoprotein (AGP), which were isolated from native human commercial AGP (total AGP) by chromatography on an immobilized copper(II) affinity adsorbent. The values of the dissociation constant (K(d)) of some basic drugs with the F(1)S variant in equilibrium dialysis differed characteristically from those with the A variant. The selective binding to these variants was evaluated by measuring the displacement ratio of dicumarol bound to the F(1)S variant or that of acridine orange bound to the A variant, using circular dichroism spectroscopy. There was reasonably good agreement between the K(d) values and displacement ratios. There was a characteristic difference between the values of inhibition constant (K(i)) of basic drugs towards dipyridamole binding to F(1)S and towards disopyramide binding to A in total AGP. We found that the K(i) values for dipyridamole binding were well correlated with the K(d) values for the F(1)S variant, whereas those for disopyramide binding were well correlated with the K(d) values for the A variant. In conclusion, the higher the affinity of basic drugs for AGP, the more they inhibit the binding of other basic drugs, and further, the inhibitory potency depends on the selectivity of binding to the AGP variants.

1H NMR and UPLC-MS(E) statistical heterospectroscopy: characterization of drug metabolites (xenometabolome) in epidemiological studies.

Statistical HeterospectroscopY (SHY) is a statistical strategy for the coanalysis of multiple spectroscopic data sets acquired in parallel on the same samples. This method operates through the analysis of the intrinsic covariance between signal intensities in the same and related molecular fingerprints measured by multiple spectroscopic techniques across cohorts of samples. Here, the method is applied to 600-MHz (1)H NMR and UPLC-TOF-MS (E) data obtained from human urine samples ( n = 86) from a subset of an epidemiological population unselected for any relevant phenotype or disease factor. We show that direct cross-correlation of spectral parameters, viz. chemical shifts from NMR and m/ z data from MS, together with fragment analysis from MS (E) scans, leads not only to the detection of numerous endogenous urinary metabolites but also the identification of drug metabolites that are part of the latent use of drugs by the population. We show previously unreported positive mode ions of ibuprofen metabolites with their NMR correlates and suggest the detection of new metabolites of disopyramide in the population samples. This approach is of great potential value in the description of population xenometabolomes and in population pharmacology studies, and indeed for drug metabolism studies in general.

Lipophilicity Influences Drug Binding to α1-Acid Glycoprotein F1/S Variants But Not to the A Variant.

OBJECTIVE: Human α1-acid glycoprotein has genetic variants, the F1, S, and A variants, which can be separated isoelectrophoretically. These variants show differences in their affinity of binding to several drugs. In this study, we investigated the factors determining drug binding to these α1-acid glycoprotein genetic variants using disopyramide, warfarin, and tamsulosin as marker compounds. METHODS: Binding of the marker drugs to human α1-acid glycoprotein was determined by ultra-filtration in the presence or absence of various other drugs. For screening of the α1-acid glycoprotein variants to which the marker drugs became bound, the effects of various other drugs on their binding were studied. The binding data were analyzed using a competitive inhibition model and the relationship between the estimated dissociation constants and physicochemical properties, such as log P, was also analyzed. RESULTS: The binding of tamsulosin was significantly decreased by aprindine, carvedilol, erythromycin, thioridazine, and warfarin, but not by disopyramide. The dissociation constants of drugs bound to F1/S variants were significantly correlated with their lipophilicity, but those for the A variant were not. CONCLUSIONS: We were able to develop a simple screening method for determining individual α1-acid glycoprotein variants to which drugs would bind. The binding of drugs to F1/S variants may be determined mainly by drug lipophilicity.

Studies of drug interactions with alpha1-acid glycoprotein by using on-line immunoextraction and high-performance affinity chromatography.

A method that combined on-line immunoextraction with high-performance affinity chromatography was developed to examine the binding of drugs with α1-acid glycoprotein (AGP). Affinity microcolumns containing immobilized polyclonal anti-AGP antibodies were developed that had a capture efficiency of up to 98.4% for AGP and a binding capacity of 0.72nmol AGP when using a 20mm×2.1mm i.d. microcolumn. These microcolumns were employed in various formats to examine the binding of drugs to normal AGP and AGP that had been adsorbed from serum samples for patients with systemic lupus erythematosus (SLE). Drugs that were screened in zonal elution experiments for their overall binding to these types of AGP included chlorpromazine, disopyramide, imipramine, propranolol, and warfarin. Most of these drugs showed an increase in their binding to the AGP from SLE serum when compared to normal AGP (i.e., an increase of 13-76%); however, disopyramide gave a 21-25% decrease in retention when the same AGP samples were compared. Frontal analysis was used to further evaluate the binding of disopyramide and imipramine to these forms of AGP. Both drugs gave a good fit to a model that involved a combination of saturable and non-saturable interactions with AGP. Changes in the non-saturable interactions accounted for most of variations seen in the binding of disopyramide and imipramine with the AGP samples. The methods used in this study could be adapted for use in personalized medicine and the study of other proteins or drugs using aqueous mixtures or clinical samples.

Binding of disopyramide, methadone, dipyridamole, chlorpromazine, lignocaine and progesterone to the two main genetic variants of human alpha 1-acid glycoprotein: evidence for drug-binding differences between the variants and for the presence of two separate drug-binding sites on alpha 1-acid glycoprotein.

Human alpha 1-acid glycoprotein (AAG), a plasma drug transport protein, has three main genetic variants, the A variant and the F1 and S variants, which are encoded by two different genes. The binding of disopyramide, methadone, dipyridamole, chlorpromazine, lignocaine and progesterone to the two main gene products of AAG-the A variant and a mixture of the F1 and S variants (60% F1 and 40% S)-separated by chromatography from native commercial AAG, a mixture of almost equal proportions of the F1, S and A variants, was studied by equilibrium dialysis. A selective binding of disopyramide and methadone to the A variant and a preferential binding of dipyridamole to the F1S variant mixture were found. Lignocaine and chlorpromazine had a slight preference for binding to the A variant and to the F1S mixture, respectively, but progesterone showed no selectivity with regard to any of the variants of AAG. The differences in drug-binding demonstrated between the A variant and the F1S mixture confirmed those of a previous study, in which a selective binding of imipramine to the A variant and of warfarin and mifepristone to the F1S mixture have been found. These results indicate specific drug transport roles for each AAG variant, according to its separate genetic origin. The results of control binding experiments performed with (unfractionated) commercial AAG and the series of tested ligands concurred with that for the separate AAG variants, with respect to the proportion of the A variant (27%) and that of the F1 and S variants (73%) in the commercial protein. In addition, disopyramide, methadone, dipyridamole, chlorpromazine, lignocaine and progesterone were used in equilibrium dialysis displacement experiments to study interactions on binding sites labelled with imipramine for the A variant and with warfarin for the F1S variant mixture. The four latter ligands were found to competitively inhibit the binding of warfarin to the F1S variant mixture and all of them that of imipramine to the A variant. The ligands association constants to each AAG variant obtained from such inhibitory experiments were comparable to those determined in the direct binding studies. As the stochlometry of the interactions of the A variant and the F1S variants, respectively, with their specific ligands was approximately one (1), it was concluded that these ligands bind to each of these variants via a single common binding site. These results indicate that the AAG molecule would have for its ligands at least two separate binding sites, showing different specificity and localization, and not one site, as it is generally assumed. The possible pharmacological and clinical consequences of the binding results with the separate AAG variants are discussed.

Disopyramide hemodialysis and kinetics in patients requiring long-term hemodialysis.

Disopyramide hemodialysis and kinetics after 200 mg orally in six patients receiving long-term hemodialysis were examined. Mean volume of distribution (area) was 66.5 +/- 13 l. Mean times of the peak serum concentration and mean peak serum concentration were 2.3 +/- 0.9 hr and 3.1 +/- 0.9 microgram/ml. Mean absorption half-life (t 1/2) was 21.6 +/- 12.5 min. Mean disopyramide elimination t 1/2 during dialysis was 16.8 +/- 11.9 hr, not significantly different from mean elimination t 1/2 without dialysis of 16.1 +/- 5.2 hr. End-dialysis bath concentrations of disopyramide showed that not more than 2.4% of the dose was dialyzed during a 2-hr dialysis period. Our data indicate that at therapeutic concentrations disopyramide was not appreciably dialyzed.

Protein binding of disopyramide in liver cirrhosis and in nephrotic syndrome.

The plasma protein binding of disopyramide (D) was determined in seven patients with cirrhosis, six with nephrotic syndrome, and seven healthy subjects. Plasma samples containing concentrations of 0.2 to 12.0 micrograms/ml were ultrafiltered and the free fractions were measured with fluorescence polarization immunoassay. The mean free fractions at D concentrations ranging from 1 to 6 micrograms/ml were significantly (P less than 0.01) greater in patients with cirrhosis than in healthy subjects. No difference was observed between patients with nephrotic syndrome and healthy subjects. The free fraction at D 3 micrograms/ml correlated better with alpha 1-acid glycoprotein (r = -0.77) than with albumin (r = -0.46). Patients with cirrhosis had significantly (P less than 0.01) lower capacity constants as compared with the other two study groups. There was a significant (P less than 0.01) correlation between capacity constant and alpha 1-acid glycoprotein (r = 0.71). Our results suggest that the D therapeutic range measured as the total plasma concentration in cirrhosis, but not in nephrosis, should be approximately 50% lower than previously believed.

Disopyramide kinetics in patients with acute myocardial infarction.

The kinetic behavior of disopyramide was studied in 20 patients with suspected myocardial infarction: in 13 of these, the diagnosis was subsequently confirmed. All received a 400-mg oral loading dose of disopyramide base followed by an oral maintenance regimen of either 100 or 200 mg 4 times daily. The elimination half-life (t1/2beta) was longer (p less than 0.05) in patients with confirmed infarction than in patients with unconfirmed infarction [38.0 +/- 3.7 hr (mean +/- SEM) compared to 24.3 +/- 0.8 hr, and 21.2 +/- 2.1 hr compared to 7.2 +/- 2.4 hr for the 100- and 200-mg maintenance dose regimens, respectively]. The t1/2beta was dose dependent for infarct and noninfarct patients. Two of the patients with confirmed infarction failed to reach trough plasma levels equal to or exceeding the lower end of the manufacturer's recommended therapeutic range (3.3 mug/ml) during the study. For the remaining 11 patients the time taken to achieve trough plasma levels of 3.3 mug/ml varied from 18 to 170 hr; hence plasma disopyramide concentration in these patients was suboptimal at a time when the risk of arrhythmias is high. Modification of existing oral loading dose regimens is therefore required for optimization of oral disopyramide therapy.

Serum disopyramide concentrations and suppression of ventricular premature contractions.

Serum disopyramide determinations and 24-hour Holter monitoring were performed in 20 cardiac subjects with ventricular premature contractions (VPCs) after the first, seventeenth, and thirty-seventh doses of disopyramide, 100 mg (10 subjects; low-dose group) or 200 mg (10 subjects; high-dose group) every 6 hr for 10 days to assess the ability of single- or first-dose data to predict serum disopyramide concentrations at steady state and the relationship between steady-state serum disopyramide concentrations and VPC suppression. Control Holter recordings were made for 48 hr in each subject. There were strong correlations in both groups between data for the AUC over 0 to 6 hr for the first dose (AUC60) and average (C ss) and trough (C min) steady-rate serum disopyramide concentrations after the seventeenth and thirty-seventh doses and the two combined. C ss and C min were related to AUC60 by the following expressions for both dosage groups: C ss = 0.22 AUC60 + 0.90 and C min = 0.20 AUC60 + 0.70. There were good correlations between 6-hr serum disopyramide concentration after the first dose and C ss and C min. There was strong correlation between overall average steady-state serum disopyramide concentration and suppression of VPC frequency. The relationship between VPC suppression and overall average trough serum disopyramide concentration at steady state, on the other hand, was weak.

Disopyramide kinetics in renal impairment: determinants of interindividual variability.

Disopyramide kinetics were studied in 30 patients with normal to severely impaired renal function (endogenous creatinine clearance 7.6 to 116.9 ml/min/1.73 m2) after intravenous bolus injection. Serum concentration-time curves were fitted to an open two-compartment model. There was close correlation between renal disopyramide clearance and creatinine clearance (r = 0.922). Disopyramide body clearance or elimination rate constant (kel beta) and creatinine clearance did not correlate as closely (r = 0.756 and 0.644). Volume of distribution at steady state and extrarenal clearance of disopyramide both correlated slightly positively with renal function. Disopyramide body clearance and volume of distribution, but not kel beta, were found to be dose dependent. Disopyramide kinetics in renal impairment were not sufficiently predictable from clinical data of the patient because of great interindividual variation in drug disposition and renal and extrarenal elimination. Dosage regimen must therefore be based on individual response and controlled by the clinical effect and estimates of disopyramide serum concentration.

Kinetics and dynamics of disopyramide and its dealkylated metabolite in healthy subjects.

The kinetics and dynamics of total and free (unbound) disopyramide (D) after dosing with D, 1.5 and 2 mg/kg iv, were compared with those of the dealkylated metabolite (MND) after dosing with MND, 0.5 and 1.5 mg/kg iv, in six healthy subjects. Dynamic parameters included ECG with measurement of the QT interval corrected for heart rate (QTc), systolic time intervals, vitamin C-stimulated saliva secretion, pupil size, and maximum accommodation capacity. Mean values of total clearance, apparent volume of distribution, and elimination t1/2 of MND were 5.9, 2.3, and 0.4 times those of total D, respectively. D significantly prolonged the QTc and systolic time intervals and induced transient inhibition of stimulated saliva secretion. In contrast, MND induced no substantial change in either the QTc or systolic time intervals, but did induce more persistent inhibition of salivary secretion. If anticholinergic potency is determined as the degree of inhibition of stimulated saliva flow per plasma concentration unit, MND was three times as potent as its parent when measured at maximum inhibition. There were no consistent drug effects on the ocular parameters. The effect of D on QTc correlated with both total and free plasma concentrations. Furthermore, its transient salivary inhibitory effect paralleled its initial rapid decline in plasma concentration. There was no relationship between the MND plasma concentration and its salivary inhibitory effect. We conclude that disopyramide significantly affected the QTc and systolic time intervals in healthy subjects, while MND in a similar dose had no such effects. MND more strongly inhibited stimulated saliva flow, indicating a more potent anticholinergic effect than D.

Synthesis and anticholinergic properties of the enantiomers of 4-(isopropylamino)-2-(2-pyridyl)-2-phenylbutyramide, the mono-N-dealkylated metabolite of disopyramide.

The 2R and 2S enantiomers of 4-isopropyl-2-(2-pyridyl)-2-phenylbutyramide [(2R)-2 and (2S)-2] were prepared from the respective 2R and 2S enantiomers of disopyramide [(2R)-1 and (2S)-1] by oxidation with peracid, Cope elimination, and subsequent zinc/HCl reduction of the resulting hydroxylamines (2R)-3 and (2S)-3. The enantiomers were tested as antagonists to the contraction of guinea pig ileum longitudinal muscle produced in response to electrically stimulated release of acetylcholine. The enantiomers showed IC50 values of 5.0 X 10(-6) and 14 X 10(-6) M for (2S)-2 and (2R)-2 respectively, about a 3-fold difference between enantiomers. Data are presented showing direct antagonism of acetylcholine in the guinea pig ileum assay. In a comparison of the anticholinergic effects of 2 and 1, the metabolite (2) was slightly less potent than disopyramide (1).

The effects of urine pH and plasma protein binding on the renal clearance of disopyramide.

To ascertain whether the renal clearance of disopyramide (pKa = 8.36) is affected by urine pH, the disposition kinetics of disopyramide were compared during excretion of acidic and alkaline urine following both single dose intravenous (2mg/kg) and oral (5 mg/kg) administration to 4 healthy male volunteers. No significant difference was observed in the plasma concentration-time curve of disopyramide. The mean 72 hour recovery of disopyramide and its N-deisopropyl metabolite (MND) in urine was 55.1 and 20.3% of the dose respectively, with no apparent difference between the two routes of administration or pH of urine. Renal clearance of disopyramide was found to vary with time, which is partly the result of a concentration dependent change in plasma protein binding. The unbound fraction of drug in plasma varied from 0.32 to 0.72 between 0.4 to 4microgram/ml concentration. However, time-dependent change in renal clearance of disopyramide persists even after correction for plasma protein binding.

Clinical pharmacokinetics of disopyramide.

Disopyramide is an antiarrhythmic agent with proven efficacy in the management of atrial and ventricular arrhythmias. The drug is well absorbed and undergoes virtually no first-pass metabolism. Peak concentrations are achieved approximately 0.5 to 3.0 hours after a dose. Absorption is reduced and slightly slowed in patients with acute myocardial infarction. Disopyramide is excreted as unchanged drug (two-thirds) or as the metabolite mono-N-desisopropyldisopyramide, with elimination via both renal and biliary routes. Elimination half-life is approximately 7 hours in normal subjects and patients, but is prolonged in patients with renal insufficiency (creatinine clearance less than 60 ml/min). Disopyramide exhibits complex protein binding. It is bound to alpha 1-acid glycoprotein (AAG), an acute phase reactant, and binds in a concentration-dependent (saturable) manner. The unbound fraction is reduced in the presence of elevated concentrations of AAG, as are found in acute myocardial infarction and in some chronic haemodialysis patients and renal transplant recipients. Free disopyramide concentrations are low relative to total concentration in these patients. Because the pharmacological effects of disopyramide are determined by unbound drug, changes in the unbound fraction could make total disopyramide concentrations misleading as a guide to therapy. Changes in protein binding do not, however, alter free disopyramide or metabolite concentrations, both of which are dependent only on dosage and intrinsic clearance. Free drug concentration measurement could potentially improve therapeutic monitoring, but is as yet of unproven clinical value. Disopyramide is cleared more rapidly in children than in adults, and therefore children require higher dosages to attain therapeutic concentrations.

Effect of concentration-dependent binding to plasma proteins on the pharmacokinetics and pharmacodynamics of disopyramide.

Disopyramide exhibits concentration-dependent binding to plasma proteins at therapeutic plasma concentrations. This paper reviews the effect of this type of binding on both the pharmacokinetic and pharmacodynamic properties of the drug. For a drug with capacity-limited, binding-sensitive elimination like disopyramide, concentration-dependent binding to plasma proteins produces a non-linear relationship between dosing rate and total plasma concentrations of the drug. However, when dosing rate is related to unbound concentrations of drug, the relationship is linear. Renal clearance of total disopyramide has been found to depend on the unbound fraction whereas renal clearance of unbound drug may be dependent upon time after drug administration as well as route of drug administration. However, due to some potential methodological problems, these data need verification. The concentration-dependent binding of disopyramide to plasma proteins, with its resultant effects on clearance and distribution, produces a concave curvature in the log unbound concentration versus time curves and a log-linear decline in total plasma concentration versus time after intravenous administration of the drug. Several pharmacological studies suggest that the unbound drug is active in terms of producing both desirable and undesirable effects. Hence, monitoring unbound concentrations of disopyramide seems more rational for clinical purposes. The few studies that have been carried out examining the optical isomers of disopyramide have suggested that both the pharmacokinetic and pharmacodynamic properties of the drug are stereoselective. Recent data reveal stereoselective binding to plasma proteins in humans.(ABSTRACT TRUNCATED AT 250 WORDS)

Potential applications of free drug level monitoring in cardiovascular therapy.

Cardiovascular drugs, as a class, have low therapeutic indices, but also have great therapeutic potential. Plasma concentration information is therefore often of value when using these drugs. Unfortunately, the total plasma concentration may not reflect the concentration of pharmacologically active free drug, since a number of factors including disease states, heparin anticoagulation, non-linear binding characteristics, and in vitro artefacts can affect the protein binding of these agents. This may also explain their poor dose-response relationships and great interindividual variability in plasma concentration data. Careful studies relating bound and free drug concentration to pharmacological response may provide the clinician with a better guide to therapy, and enhance the usefulness of these drugs.

Effects of congestive heart failure on the pharmacokinetics and pharmacodynamics of antiarrhythmic agents.

Changes in the pharmacokinetics of antiarrhythmic agents should be expected in patients with congestive heart failure (CHF). The direction of the changes, however, is not always predictable. The volume of distribution is often decreased by as much as 40%, and loading doses should, therefore, be appropriately reduced. Drug clearance may also be diminished due to decreased blood flow to the liver and kidneys, as well as decreased hepatic drug-metabolizing activity. Infusion rates should similarly be lowered to avoid toxicity. However, decreases in both volume of distribution and clearance may result in little, if any, change in elimination half-life, despite higher plasma concentrations. On the other hand, the elimination half-life of antiarrhythmic agents that have a large volume of distribution and are highly cleared by the liver may be twice as long in patients with CHF compared with normal subjects. Thus, the total daily dose of drug should also be lower in these patients. In addition, the time necessary to reach steady state is longer, so that premature dose escalation may lead to excessive drug accumulation. In terms of their pharmacodynamic effects, all antiarrhythmic agents have the potential to manifest a degree of negative inotropy, which must be anticipated as a possible side effect in patients with CHF. Some of the newer agents, such as tocainide and encainide, appear to cause only minimal myocardial depression. Other potential complications of all antiarrhythmic therapy include proarrhythmia and possible drug interactions with digitalis and diuretics.

Disopyramide. A reappraisal of its pharmacodynamic and pharmacokinetic properties, and therapeutic use in cardiac arrhythmias.

Disopyramide is a widely used class IA antiarrhythmic drug with a pharmacological profile of action similar to that of quinidine and procainamide. Over the past 10 years disopyramide has demonstrated its efficacy in ventricular and atrial arrhythmias. In therapeutic trials, usually involving small numbers of patients, the efficacy of disopyramide was comparable with that of mexiletine, perhexiline, tocainide, propafenone or prajmalium. Recent comparisons with quinidine have confirmed the similar efficacy and better tolerability of disopyramide. The suggestion from initial studies that disopyramide may be less effective than amiodarone or flecainide requires further investigation. In addition, studies have failed to demonstrate that the early administration of disopyramide after acute myocardial infarction decreases important arrhythmias or early mortality. Thus, disopyramide is now well established as an effective antiarrhythmic drug in ventricular and supraventricular arrhythmias although its role in therapy relative to that of recently introduced antiarrhythmic agents is not clear.

Disopyramide: a review of its pharmacological properties and therapeutic use in treating cardiac arrhythmias.

Disopyramide is a new antiarrhythmic drug with a pharmacological profile of action similar to that of quinidine and procainamide. In a few controlled therapeutic trails and a large number of uncontrolled studies in patients with arrhythmias, often following a myocardial infarction, disopyramide has been relatively effective (more so in ventricular than in atrial arrhythmias) and usually well tolerated. In treating premature atrial and ventricular contractions, the best-studied area of its therapeutic use, disopyramide was superior to a placebo and of similar efficacy to but better tolerated than quinidine; the drop-out rate due to adverse effects of the disopyramide group (10%) being less than one-third that of the quinidine group (36%). In an open ward setting, disopyramide used prophylactically after myocardial infarction appeared to reduce both the incidence of reinfarction and the mortality rate, while in patients treated in coronary care units although the incidence of reinfarction was lower with disopyramide than with a placebo, the mortality rate was not significantly different. Further well-designed trials with adequate numbers of patients are needed before the routine use of disopyramide in infarct patients treated in either setting can be justified. Comparative studies are also required to determine if disopyramide has advantages over other antiarrhythmic agents in this area of use. Side-effects with disopyramide are usually a result of its anticholinergic activity, a dry mouth and difficulty in urination being the most common. Like other antiarrhythmic agents, disopyramide exerts a negative inotropic action on cardiac muscle, and development of acute heart failure has been reported. Development of worsening of heart block and hypotension have also occurred. Disopyramide is largely excreted unchanged and dosage should be reduced in patients with impaired renal function, in accordance with creatinine clearance values.

Series on pharmacology in practice. 2. Antiarrhythmic drug therapy.

The selection of appropriate antiarrhythmic drug therapy depends on a knowledge of the drugs available, their spectrum of action, their pharmacokinetics, and their major side effects. It is important to know how the pharmacokinetics of a drug vary with different disease states so that appropriate adjustments to dosage can be made. Drugs with similar actions can be assigned into groups, and five different groups can be identified. The commonly used antiarrhythmic drugs are reviewed, and some of the newer drugs are discussed.