Intravenous quinidine: pharmacokinetic properties and effects on left ventricular performance in humans

Continuous intravenous quinidine infusion for the treatment of atrial fibrillation or flutter: a case series

BACKGROUND

The purpose of the study was to evaluate a continuous intravenous quinidine infusion (CIQI) for the treatment of cardiac arrhythmias in critically ill patients.

METHODS AND RESULTS

A 2-year retrospective review was conducted in adult patients receiving a CIQI for cardiac arrhythmias. Patient demographics, baseline laboratory values, indication for quinidine, dose, duration of therapy, efficacy, adverse events, and serum concentration were among the collected data. All patients were critically ill and receiving quinidine for the treatment of atrial arrhythmias. Quinidine was effective in 14 (61%) of the 23 enrolled patients. Ninety-one percent of the patients received the CIQI after surgery. A total of 8 (35%) patients died. Four (17%) patients had hypotension possibly attributed to the quinidine.

CONCLUSIONS

A continuous intravenous infusion of quinidine gluconate may be effective in patients in whom other agents are contraindicated or have failed. However, as with all antiarrhythmic agents, risks of therapy must be carefully considered.

Haemodynamic effects of intravenous quinacainol with and without autonomic nervous system blockade

Normal subjects are able to compensate negative inotropic drug effects by adrenergic stimulation. This may limit the relevance of hemodynamic investigations with new drugs. Therefore, the haemodynamic effects of a new class 1 antiarrhythmic drug, quinacainol, were evaluated in 16 patients with normal left ventricular function 5 and 25 minutes after intravenous administration in 2 settings: 12 patients were untreated, and 4 patients were pretreated with beta-blockers and atropine to block a reflex adrenergic discharge and vagolytic reaction. Cardiac contractility decreased in all patients: in the untreated group, the heart rate increased from 74 +/- 10 beats per minute to 80 +/- 9 and Vmax decreased from 1.56 +/- 0.56 circ/sec to 1.36 +/- 0.45 at 5 minutes and 1.36 +/- 0.61 at 25 minutes; in the pretreated group, the heart rate did not change. Vmax decreased from 1.61 +/- 0.19 circ/sec to 1.33 +/- 0.08 at 5 minutes and to 1.09 +/- 0.13 at 25 minutes. Autonomic nervous system blockade unmasked a significant persistent negative inotropic effect of the drug in this series of patients with normal left ventricular function. This method may be useful for evaluating the haemodynamic effects of antiarrhythmic drugs in preliminary studies before administration to patients with impaired left ventricular function.

Pharmacodynamic comparison of L-bunolol with propranolol, metoprolol, and placebo

Twelve healthy volunteers received single oral doses of propranolol (80 mg), metoprolol (100 mg), L-bunolol (2 mg), and placebo in a four-way crossover study. Blood pressure, ventricular rate, and echocardiographically determined ejection fraction, ejection time, and mean rate of circumferential fiber shortening (mVcf) were measured before dosing and at multiple time points during 10 hours after each dose, with subjects maintained in the supine position. Reductions in systolic and diastolic blood pressure following administration of each of the beta blockers were greater than those observed with placebo, but differences among the four treatments were not significant. Heart rate reductions with the beta blockers differed significantly from placebo (P less than .001), but differences among the three beta blockers were not significant. Differences among the four treatments in mVcf decrement did not attain significance at the 5% level (.05 less than P less than .1), and there were no significant differences in ejection-time prolongation or ejection-fraction reduction. Thus, reduced blood pressure, heart rate slowing, and reduced cardiac contractility may be associated with placebo treatment and may indicate the need for placebo controls in studies of the cardiovascular effects of beta blockers. Despite differing secondary pharmacologic properties, the three beta blockers reduced heart rate to a similar extent. Other effects of the beta blockers on blood pressure and cardiac contractility could not be consistently distinguished from those associated with placebo.

Pharmacokinetics and dynamics of penbutolol in humans: evidence for pathway-specific stereoselective clearance

The pharmacokinetics and dynamics of the D- and L-isomers of the beta-adrenergic blocking agent penbutolol were investigated in healthy human volunteers. In Study One, subjects received a single 40-mg oral dose of L-penbutolol (the pharmacologically active stereoisomer), and matching placebo on two occasions. A mean peak serum penbutolol concentration of 268 ng/ml was reached at 0.9 h after dosing. Elimination half-life averaged 1.6 h, and total clearance 16.6 ml/min per kg body weight. Changes in blood pressure, ventricular rate, and rate of circumferential fiber shortening (Vcf) did not differ between L-penbutolol and placebo. In Study Two, subjects received 40 mg D-penbutolol, L-penbutolol, and placebo on three occasions. Total clearance of D-penbutolol was higher than for the L-isomer (43.7 vs 15.9 ml/min/kg; P less than 0.01); this was reflected in correspondingly increased area under the serum concentration curve for conjugates of the oxidized metabolite 4-hydroxy penbutolol (2.25 vs 0.66 micrograms/ml X h; P less than 0.005). In contrast, direct conjugates of L-penbutolol achieved higher serum concentrations than conjugates of D-penbutolol. Alterations in blood pressure, ventricular rate, and Vcf for D-penbutolol, L-penbutolol, and placebo were quantitatively small. Thus the clearance of penbutolol after oral administration in humans is stereoselective, but the oxidative pathway is more stereosensitive than the parallel conjugative pathway. Penbutolol causes minimal alterations in parameters of cardiac function after single 40-mg doses in healthy humans.

Hypoglycaemia and antimalarial drugs: quinidine and release of insulin

Life threatening hypoglycaemia has been closely associated with the use of quinine, but the effect of quinidine and the synthetic antimalarials on the homoeostasis of glucose has not been investigated. In volunteers given a fixed dose of 500 mg base and patients with malaria given a quinidine loading dose (15 mg base/kg) mean (SEM) plasma insulin concentrations rose from 6.1 (1.5) mU/l to 10.9 (4.4) mU/l (p less than 0.02) and 10.4 (2.0) mU/l to 18.5 (5.3) mU/l (p less than 0.04), respectively. Plasma glucose concentrations fell from 4.5 (1.1) mmol/l (81 (20) mg/100 ml) to 4.0 (0.3) mmol/l (72 (5) mg/100 ml) in volunteers (p less than 0.04) and from 5.7 (1.3) mmol/l (102 (23) mg/100 ml) to 4.8 (1.6) mmol/l (86 (29) mg/100 ml) in patients (p less than 0.05). One of two patients with cerebral malaria and acute renal failure became profoundly hypoglycaemic (plasma glucose concentration 1.4 mmol/l (25 mg/100 ml), plasma insulin concentration 3.1 mU/l). Hypoglycaemia may occur in any severely ill fasting patient given parenteral quinidine. The other antimalarials tested, chloroquine, amodiaquine, mefloquine, and halofantrine, did not stimulate the release of insulin, an important advantage that should be taken into account when treatment is chosen for Plasmodium falciparum malaria.

Analysis of nonlinear tissue distribution of quinidine in rats by physiologically based pharmacokinetics

The nonlinear tissue distribution of quinidine in rats was investigated by a physiologically based pharmacokinetic model. Serum protein binding of quinidine showed a nonlinearity over the in vivo plasma concentration range. The blood-to-plasma concentration ratio (Cb/Cp) of quinidine also showed a concentration dependence. The steady-state volume of distribution (Vss) determined over the plasma concentration range from 0.5 to 10 micrograms/ml was 6.0 +/- 0.45 L/kg. The tissue-to-plasma partition coefficient (Kp) of muscle, skin, liver, lung, and gastrointestinal tract (GI) showed a nonlinearity over the in vivo plasma concentration range of quinidine, suggesting saturable tissue binding. The concentration of quinidine in several tissues and plasma was predicted by a physiologically based pharmacokinetic model using in vitro plasma protein binding and the Cb/Cp of quinidine. The tissue binding parameters were estimated from in vivo Kp values. The predicted concentration curves of quinidine in each tissue and in plasma showed good agreement with the observed values.

Intravenous quinidine by intermittent bolus for electrophysiologic studies in patients with ventricular tachycardia

The safety and efficacy of intravenous quinidine gluconate, using intermittent boluses of 80 mg/cc every 5 minutes to a total dose of 800 mg, was evaluated in 61 patients referred for electrophysiologic studies (EPS). Patients were referred because of out-of-hospital cardiac arrest (12), symptomatic ventricular tachycardia (VT) (24), asymptomatic VT (18), syncope of unknown origin (6), and supraventricular arrhythmias (1). Clinical heart failure was present in 74% of patients, with a mean ejection fraction of 45 +/- 3 for all patients. Quinidine prevented VT induction in 78% of patients at a mean dose of 9.6 mg/kg and facilitated VT induction in 7% of patients. Quinidine failed to decrease mean arterial pressure in 14 patients, and in the remaining 47 patients arterial pressure decreased by 16%. Six patients had hemodynamically significant hypotension. Two patients had hypotension severe enough to require saline administration, while four had hypotension not needing fluid replacement. Sixteen percent of patients experienced other side effects. Quinidine can be administered safely by intermittent infusion and is effective in preventing programmed stimulation induction of VT. Carefully monitored, intravenous intermittent bolus administration of quinidine should be utilized more frequently in EPS, since significant adverse side effects are infrequent.

Nifedipine: kinetics and dynamics after single oral doses

Serum nifedipine concentrations and hemodynamic changes were evaluated in ten healthy volunteers after a single 40-mg oral dose of nifedipine. Peak serum concentrations averaged 45 micrograms/l, attained 2.7 h after dosage. The mean elimination half-life was 5.9 h (range: 3-12 h). Blood pressure, ventricular rate, and echocardiographically-determined rate of circumferential fiber shortening did not differ between placebo and nifedipine trials. Five additional subjects ingested nifedipine once in the control state and on a second occasion with a standard breakfast. Coingestion of food delayed the peak serum nifedipine concentration but did not alter the area under the serum concentration curve. Thus the pharmacokinetic profile of nifedipine indicates that a three- or four-times-daily dose is, in general, appropriate in clinical practice. Completeness of absorption is not altered by coadministration with food. Adverse hemodynamic effects of single oral doses in healthy persons are not evident.

Determination of quinidine in serum by spectrofluorometry, liquid chromatography and fluorescence scanning thin-layer chromatography

Quinidine is determined in serum by direct and extraction spectrofluorometry, by reflectance fluorescence scanning thin-layer chromatography (TLC), and by high-performance liquid chromatography (HPLC). Least-squares analyses of patients' sera (n = 62) analyzed first by direct fluorometry (x) and then HPLC (y) gave a slope of 0.52, an y-intercept of -0.40, a standard error of estimate of 0.65, and a correlation coefficient of 0.83. Comparison of patients' sera (n = 59) determined by extraction fluorometry (x) and then HPLC (y) gave a slope of 0.998, an y-intercept of -0.175, a standard error of estimate of 0.30, and a correlation coefficient of 0.96. Comparison of patients' sera (n = 36) by HPLC (x) and then reflectance fluorescence scanning TLC (y) gave a slope of 0.837, an y-intercept of 0.152, and a correlation coefficient of 0.94. Methaqualone and oxazepam interfere with HPLC. Within-run precision is 1.6, 1.0, 5.2 and 3.0% by direct fluorometry, extraction fluorometry, TLC and HPLC while between-run precision is 5, 3.5, 9 and 6.0%, respectively.

Electrophysiological effects of quinidine alone and of the combination quinidine-verapamil on AV conduction in humans

The influence of 320 mg quinidine administered intravenously (i.v.), as well as subsequent administration of 5 mg verapamil i.v. on atrioventricular conduction was studied in 8 patients during sinus rhythm and atrial stimulation with the aid of His bundle electrography. Among the electrophysiologic parameters of the atrium the sinus rate increased significantly after quinidine and again increased slightly after subsequent administration of verapamil. During sinus rhythm the PA interval was not influenced by either substance. Conversely, during atrial stimulation the STA interval increased significantly under the effect of quinidine, while verapamil had no further influence. As an indicator of conduction time in the AV node, the AH interval was decreased significantly by quinidine during sinus rhythm and atrial stimulation. This effect was significantly counteracted by the additional administration of verapamil. The HV interval as a measure of the His-Purkinje conduction was not significantly affected. The QRS duration was increased significantly by quinidine and was not further influenced by verapamil. The QTc and QT intervals increased significantly after administration of quinidine and were again slightly, but significantly shortened by verapamil. Our investigations show that the combination of quinidine and verapamil, which has clinically been found to have a higher conversion rate than quinidine alone, is well justified from an electrophysiologic point of view and that undesirable quinidine-related effects, such as rapid AV conduction in cases of atrial fibrillation and flutter, can be avoided by the subsequent administration of verapamil.

Safety and efficacy of intravenous quinidine

The safety and efficacy of intravenous quinidine were evaluated in a patient population with a high prevalence of left ventricular dysfunction and intraventricular conduction delays. Quinidine gluconate (mean dose 9.1 +/- 1.6 mg/kg) was administered during electrophysiologic study to 100 patients with ventricular or supraventricular tachyarrhythmias. Clinical heart failure was present in 68 percent of the patients. Left ventricular end-diastolic pressure, cardiac index, and left ventricular ejection fraction were abnormal in 62, 48, and 70 percent, respectively. Major intraventricular conduction delays (QRS of 120 msec or more) were present in 27 percent, and the H-V interval was prolonged (over 55 msec) in 28 percent. Despite the prevalence of these abnormalities, quinidine was discontinued because of hypotension in only 10 patients. Saline solution was infused to maintain preload in 37 percent, and hypotension responded promptly to saline solution infusion or discontinuation of quinidine infusion in all subjects. Hypotension was not more common in patients with more severe left ventricular dysfunction. QRS duration, H-V interval, QTc, and right ventricular effective refractory period increased significantly (p less than 0.001) after quinidine administration. Heart block or QRS widening of 50 percent or more did not occur. Quinidine prevented arrhythmia induction in 26 percent of patients who received full doses. Ventricular tachycardia cycle length increased in all 41 patients in whom identical forms were induced before and after quinidine (287 +/- 71 msec versus 361 +/- 93 msec, p less than 0.001). Intravenous quinidine may be administered safely to patients with intraventricular conduction delays and moderate heart failure. When antiarrhythmic efficacy is assessed by electrophysiologic study, quinidine compares favorably with other antiarrhythmic agents.

Kinetics and cardiac effects of propranolol in humans

Six healthy volunteers received single 20-mg intravenous (IV) and 80-mg oral doses of propranolol on two occasions in random sequence. Serum propranolol concentrations were determined by gas chromatography in multiple samples drawn during 24 h after each dose. Mean (+/- SE) kinetic variables for IV propranolol were: elimination half-life (t 1/2 beta), 5.3 (+/- 0.6) h; volume of distribution, 2.3 (+/- 0.3) l/kg; total clearance, 4.9 (+/- 0.3) ml/min/kg; predicted extraction ratio, 0.23 (+/- 0.02). After single oral doses, t 1/2 beta (3.8 +/- 0.2 h) tended to be smaller than after the IV dose, and actual systemic availability (0.60 +/- 0.07) was less than that based on the predicted extraction ratio. During multiple oral dosage (80 mg every 12 h), observed steady state serum levels (47 +/- 5 ng/ml) tended to be less than those predicted based on the single oral dose (61 +/- 5 ng/ml), thus providing no evidence for reduced propranolol clearance at steady-state. Echocardiographic measurements of left ventricular performance (posterior wall velocity, diastolic dimensions) made during the single-dose oral study indicated significant impairment of function; impairment was maximal at 3 h post-dosage, and corresponded to the time of the peak serum propranolol concentration (341 ng/ml).

Assessment of quinidine gluconate for nonlinear kinetics following chronic dosing

Two different chronic dosing regimens of quinidine gluconate were administered to each of four healthy volunteers in a pilot study to evaluate quinidine for nonlinear pharmacokinetics. Analysis of plasma quinidine levels following the last dose indicates that disproportionate increases in steady-state plasma concentrations can occur in some subjects as the daily dose increases. Measurement of 2'-oxoquinidinone (2'-OXO) and 3-hydroxyquinidine (3-OH) metabolites revealed that the formation of 2'-OXO is proportional to the availability of quinidine base. Hydroxylation was a more variable process. Rate-limited hydroxylation was documented in one subject, and an apparent increase in hepatic microsomal enzyme-mediated hydroxylation was shown in a second subject who ingested large amounts of caffeine daily. By using a highly selective high-performance liquid chromatography assay technique, the total body clearance of quinidine was found to be greater than previously published data. Our results suggest that some individuals may exhibit dose-dependent elimination of quinidine and that the variability in quinidine's pharmacokinetics is related in part to its hydroxylation. Future studies must use highly specific quinidine assays and control for variables that may influence this route of metabolism.

Intravenous quinidine in congestive cardiomyopathy

Eight male patients with compensated congestive cardiomyopathy received single 300-mg doses of intravenous quinidine by 15-min infusion. Left ventricular (LV) performance was evaluated by echocardiography at multiple points in time during the next 24 h. Quinidine kinetics and protein binding were determined from multiple serum samples drawn for up to 36 h after dosage. LV function was not impaired. Instead, quinidine transiently increased ejection fraction (mean: +39%) and rate of circumferential shortening (mean: +46%). Endsystolic and end-diastolic LV internal diameter likewise were decreased (means: -13% and -7%). Blood pressure and ventricular rate were not significantly altered. Compared to 8 healthy controls matched for age, sex, and weight, quinidine volume of distribution among patients was smaller (means: 2.27 vs 1.90 l/kg), as was total quinidine clearance (3.49 vs 2.84 ml/min/kg); however, differences were not statistically significant. Well-controlled, slow intravenous infusion of quinidine does not impair LV performance and is safe for patients with compensated congestive cardiomyopathy. However, such patients may have reduced quinidine clearance and hence require lower doses than expected based on age and weight.

Clinical pharmacokinetics of quinidine

The elimination of quinidine is accomplished by a combination of renal excretion of the intact drug (15 to 40% of total clearance) and hepatic biotransformation to a variety of metabolites (60 to 85% of total clearance). Many of the metabolites appear to be pharmacologically active. Typical ranges for kinetic properites of quinidine in healthy persons are: apparent volume of distribution 2.0 to 3.5 litres/kg; elimination half-life 5 to 12 hours; clearance, 2.5 to 5.0 ml/min/kg. Quinidine clearance is reduced in the elderly, in patients with cirrhosis, and in those with congestive heart failure. Oral quinidine is available either as relatively rapidly absorbed conventional tablets (usually quinidine sulphate) or as a variety of slowly absorbed sustained release preparations. Absolute systemic availability generally is 70% or greater. Quinidine is 70 to 95% bound to plasma protein, primarily to albumin but also to a number of other plasma constituents. Binding is reduced in patients with cirrhosis, partly because of hypoalbuminaemia, but is not influenced by renal insufficiency. Clinical interpretation of total serum or plasma quinidine concentrations must be altered in patients with reduced or increased binding, since it is the unbound fraction which is pharmacologically active.