The pharmacokinetics and pharmacodynamics of lignocaine and MEGX in healthy subjects

Lignocaine clearance declines during continuous intravenous infusion in man and in vitro studies suggest that this may partly be due to inhibition by MEGX, a metabolite of lignocaine. MEGX is pharmacologically active in animals, but this is not yet proven in man. This study examined the pharmacokinetics and pharmacodynamics of lignocaine and MEGX in eight healthy male volunteers given lignocaine HCl 120 mg, MEGX HCl 120 mg, lignocaine HCl 120 mg + MEGX HCl 120 mg, and placebo, administered according to a randomized double-blind protocol. One-, two-, or three-compartment models were fitted to drug and metabolite blood concentration-time profiles and clearance, volume (Vss), and half-life values were calculated and compared by paired t-test. Systolic time intervals and QT interval were recorded and compared by repeated measures ANOVA. When administered in combination with MEGX, lignocaine clearance was significantly reduced from 58 +/- 18 to 48 +/- 13 L hr-1 (p less than 0.02). The Vss was unchanged and there was a trend toward an increase in terminal half-life. Lignocaine, MEGX, and the combination significantly reduced QT interval up to 30 min after injection and this was maintained to 2 hr with the lignocaine and the combination. Transient side effects were experienced with all active treatments, but were most pronounced with the combination. Thus, lignocaine clearance was inhibited by MEGX, which was pharmacologically active in man.     

Effect of the CYP3A4 inhibitor erythromycin on the pharmacokinetics of lignocaine and its pharmacologically active metabolites in subjects with normal and impaired liver function

AIMS: The objectives of this study were: (i) to evaluate the effect of a cytochrome P450 (CYP) 3A4 inhibitor, erythromycin, on the pharmacokinetics of intravenous lignocaine and its two pharmacologically active metabolites, monoethylglycinexylidide (MEGX) and glycinexylidide (GX); (ii) to assess whether the effects of the erythromycin inhibitory action on lignocaine clearance and the results of the MEGX liver function test depend on liver functional status; and (iii) to determine the effects of both moderate and severe liver dysfunction on the disposition kinetics of lignocaine. METHODS: The study was carried out on 10 healthy volunteers, and 10 Child's class A and 10 class C cirrhotic patients, according to a double-blind, randomized, two-way crossover design. On day 1 of the investigation, all subjects received three oral doses of erythromycin (600 mg of the ethylsuccinate ester) or placebo, and two further doses on day 2. One hour after the fourth dose, subjects were given 1 mg kg-1 lignocaine intravenously. Timed plasma samples were then obtained until 12 h for determination of the concentrations of lignocaine, MEGX and GX. RESULTS: Erythromycin caused statistically significant, although limited, modifications of lignocaine and MEGX pharmacokinetic parameters. In healthy volunteers, lignocaine clearance was decreased from 9.93 to 8.15 ml kg-1 min-1[mean percentage ratio (95% CI), 82 (65-98)] and the half-life was prolonged from 2.23 to 02.80 h [mean percentage ratio (95% CI), 130 (109-151)]; MEGX area under the concentration-time curve from 0 h to 12 h was increased from 665 to 886 ng ml-1 h [mean percentage ratio (95% CI), 129 (102-156)]. Quantitatively similar modifications were observed in the two cirrhotic groups. GX concentrations were lowered in all study groups, although not to statistically significant extents. Erythromycin coadministration caused no appreciable interference with the results of the MEGX test. Only in patients with Child's grade C liver cirrhosis were lignocaine kinetic parameters significantly altered with respect to healthy volunteers. Thus, clearance was approximately halved, steady-state volume of distribution was increased, and terminal half-life was more than doubled. CONCLUSIONS: Although erythromycin only modestly decreases lignocaine clearance, it causes a concomitant elevation of the concentrations of its pharmacologically active metabolite MEGX. A pharmacodynamic study following lignocaine infusion to steady state appears necessary to assess the actual clinical relevance of these combined effects. The degree of liver dysfunction has no influence on the extent of the erythromycin-lignocaine interaction, whereas it markedly influences the extent of the changes in lignocaine pharmacokinetics. These findings indicate that no dose adjustment is needed in patients with moderate liver cirrhosis, whereas the lignocaine dose should be halved in patients with severe cirrhosis.     

Effect of erythromycin and itraconazole on the pharmacokinetics of intravenous lignocaine

Objective: We have studied the possible interaction of erythromycin and itraconazole, both inhibitors of cytochrome P450 3A4 isoenzyme (CYP3A4), with intravenous lignocaine in nine healthy volunteers using a randomized cross-over study design. Methods: The subjects were given oral placebo, erythromycin (500 mg three times a day) or itraconazole (200 mg once a day) for 4 days. Intravenous lignocaine 1.5 mg · kg⁻¹ was given with an infusion for 60 min on the fourth day of pretreatment with placebo, erythromycin or itraconazole. Timed plasma samples were collected until 11 h. The concentrations of lignocaine and its metabolite monoethylglycinexylidide (MEGX) were measured by gas chromatography. Results: The area under the lignocaine concentration-time curve was similar during all three phases but erythromycin significantly increased the elimination half-life of lignocaine from 2.5 to 2.9 (0.7) h compared with placebo. Following itraconazole administration, t_1/2 was 2.6 h. The values for plasma clearance and volume of distribution at steady state were similar during all the phases. Compared with placebo and itraconazole, erythromycin significantly increased MEGX peak concentrations by approximately 40% and AUC_(0–11 h) by 45–60%. Conclusion: The plasma decay of lignocaine administered intravenously is virtually unaffected by the concomitant administration of erythromycin and itraconazole. However, erythromycin increases the concentrations of MEGX, which indicates that erythromycin either increases the relative amount of lignocaine metabolized via N-de-ethylation or decreases the further metabolism of MEGX. Further studies are necessary to elucidate the clinical significance of the erythromycin-induced elevated concentrations of MEGX during prolonged intravenous infusions of lignocaine. Received: 8 January 1998 / Accepted in revised form: 8 June 1998     

The effect of ranitidine on the disposition of lignocaine.

The effect of pretreatment with ranitidine (150 mg twice daily for 5 days) on the disposition of lignocaine was examined in 10 healthy volunteers (five male, five female). Each subject received separate oral (250 mg) and intravenous (1.5 mg/kg) doses of lignocaine hydrochloride before and after ranitidine. Lignocaine systemic clearance was reduced by 9% (1.11 to 0.99 1 h-1 kg-1; P less than 0.01) following ranitidine pretreatment. The volume of distribution at steady-state was reduced by 15% (3.34 to 2.85 1 kg-1; P less than 0.005). Lignocaine oral clearance, elimination half-life and oral bioavailability were unchanged after ranitidine pretreatment. There was no sex difference in the effects of ranitidine pretreatment on lignocaine disposition. These results are consistent with small reductions in blood flow to the splanchnic and other vascular beds due to ranitidine.     

Changes in lignocaine disposition during long-term infusion in patients with acute ventricular arrhythmias

Lignocaine disposition was studied in 30 patients with acute ventricular arrhythmias. Serum concentrations of lignocaine, its metabolites Monoethylglycine xylidide (MEGX) and glycine xylidide (GX), and alpha 1-acid glycoprotein (AAG) were analyzed during and after a 48-h lignocaine infusion. AAG concentrations tended to rise in patients with acute myocardial infarction (AMI), leading to binding of the drug in plasma. Lignocaine clearance was estimated at various times during the infusion using a Bayesian parameter estimation program and was found to decline over the course of the infusion. There was a significant reduction in clearance based on estimates obtained at the end of the infusion compared with estimates obtained during the first 0-5 h. Clearance was reduced both in patients who had an AMI and those who did not. Multiple linear regression analysis of the clearance data revealed that these changes could be described by a linear function of time and AAG concentration. These findings suggest that other factors in addition to protein binding changes may influence lignocaine disposition during long-term infusion.     

Influence of Malnutrition on the Disposition of Metronidazole in Rats

The influence of dietary protein deficiency on the disposition of metronidazole and its two major metabolites was examined in male Sprague–Dawley rats fed for 4 weeks on a 23% (control-) or a 5% (low-) protein diet ad libitum. Following an intravenous bolus dose of 10 mg/kg metronidazole hydrochloride, blood samples were obtained serially for a period of 24 hr after drug administration. Serum concentration–time data were analyzed by nonlinear least-squares regression, as well as noncompartmental techniques. The average mean residence time (MRT) was significantly prolonged by 48%, while the systemic clearance (Cl) was decreased by 42% in the protein-deficient rats. Since there was no alteration in the apparent steady-state volume of distribution (V _ss), the mean harmonic half-life was increased from 2.9 to 5.0 hr in the protein-deficient rats. Although the percentage of metronidazole recovered as total drug in the urine over 24 hr was not significantly different between the two groups of animals, rats on a low-protein diet excreted a significantly smaller percentage of the administered dose as unchanged metronidazole (mean ± SD, 24.6 ± 3.8 vs 36.5 ± 12%) and a larger percentage (16.7 ± 2.6 vs 8.3 ± 1.8%) as the hydroxylated metabolite. No significant difference in the partial metabolic clearance of the hydroxylated metabolite of metronidazole was seen between the two groups of animals; however, there was a significant decrease in the renal clearance of metronidazole (1.45 ± 0.68 vs 0.55 ± 0.06 ml/min/kg) in the rats fed a low-protein diet. We conclude that the decreased clearance of metronidazole in protein deficiency is a result primarily of the decreased glomerular filtration rate, decreased biliary excretion, and/or increased net tubular reabsorption of metronidazole.     

Lignocaine kinetics in cardiac patients and aged subjects.

1 The pharmacokinetics following long term intravenous infusion of lignocaine to cardiac patients have been examined. 2 Plasma levels and half-lives of lignocaine and monoethylglycinexylidide (MEGX) showed wide inter-patient variability. 3 Toxicity reactions to therapy were associated with elevated lignocaine and/or MEGX plasma levels. 4 In a separate study the effect of age on the pharmacokinetics of lignocaine was examined using bolus doses (50 mg) of the drug to young and aged subjects. 5 Elderly subjects had significantly longer half-lives for lignocaine compared to younger individuals although no change in plasma clearance occurred. 6 The drug appeared to distribute differently in the aged as reflected by significantly increased apparent volumes of distribution. 7 The 24 h urinary recovery of the major metabolite (total 4-hydroxyxylidine) showed a significant reduction in the elderly when compared to the young. 8 The clinical significance of these studies with respect to lignocaine therapy has been discussed.     

Pharmacokinetics of lidocaine and its deethylated metabolite: Dose and time dependency studies in man

The concentrations of lidocaine and of its deethylated metabolite, MEGX, were measured in blood following the intravenous administration of 50 and 100 mg lidocaine hydrochloride, the oral administration of 100, 300, and 500 mg lidocaine hydrochloride monohydrate, and the oral administration of 300 mg lidocaine hydrochloride monohydrate every 8 h for seven doses, to three healthy volunteers. The range of values for the parameters defining the disposition kinetics of lidocaine were: terminal half-life, 50–231 min; total clearance, 13–17 ml/min/kg; initial dilution space, 0.13–2.5 liters/kg; and volume of distribution at steady state, 0.6–4.5 liters/kg. Lidocaine absorption from solution was rapid, but due to presystemic hepatic metabolism, the availability was low, the range of average values lying between 0.19 and 0.38. No dose or time dependency in lidocaine and monoethylglycinexylidide pharmacokinetics following the single dose studies of lidocaine were noted. Effective hepatic blood flow, based on total clearance and availability measurements, was estimated to be 18–27 ml/min/kg. The concentrations of MEGX were approximately one-third of those of lidocaine following intravenous lidocaine and were comparable following oral lidocaine, but as predicted, the dose normalized area under the MEGX concentration-time curve was constant and independent of the route of administration of lidocaine. In two subjects, the blood concentrations of lidocaine and MEGX following multiple doses of oral lidocaine were those predicted from the single dose studies. In the third subject, the degree of accumulation of lidocaine was greater than predicted. The reasons and mechanism for this difference between subjects on multiple dosing remains unclear.Glossary ₁, ₂ exponential coefficients associated with the first and second phase of the biexponential equation describing lidocaine disposition; min^–1 - ANOVA analysis of variance - AUC total area under the blood drug concentration-time curve; (mg/liter) × min - CL total (blood) clearance of lidocaine; ml/min/kg - EHBF effective hepatic blood flow; ml/min/kg - F oral availability of lidocaine - f _m fraction of lidocaine converted to MEGX which appears in the general circulation. MEGX monoethylglycinexylidide - t _1/2,1 t _1/2,2 half-life associated with the first and second phase, respectively, of lidocaine disposition; min - t _1/2,abs absorption half-life of lidocaine; min - t _1/2,MEGX elimination half-life of MEGX; min - tlag time between administration and estimated start of lidocaine absorption; min - V ₁ initial dilution space of lidocaine; liters/kg - V volume of distribution of lidocaine during the terminal phase; liters/kg - V _ss volume of distribution of lidocaine at steady state; liters/kg - V _MEGX volume of distribution of MEGX; liters/kg     

The uptake and elution of lignocaine and procainamide in the hindquarters of the sheep described using mass balance principles

Mass balance principles were used to describe the uptake and elution of lignocaine (lidocaine) and procainamide in the hindquarters of the sheep. Each of four sheep received a right atrial infusion of either lignocaine · HCl (2.7 mg/min) or procainamide · HCl (5.5mg/min) for 180 min. Paired arterial and inferior vena cava (draining the hindquarters) blood samples were taken at 20-min intervals during the infusion and for 180 min after the infusion. Lignocaine and procainamide mean total body clearances were 2.9 L/min (SD 1.1) and 1.3 L/min (SD 0.2), respectively. An index of the uptake and elution of these drugs in the hindquarters was estimated from the net drug mass per unit hindquarter blood flow;indirect evidence suggested that hindquarter blood flow was constant. All the net mass/flow of procainamide that was taken into the hindquarters during the infusion also eluted after the infusion, demonstrating reversible distribution into the tissues. However, uptake of procainamide was still occurring when blood concentrations were constant, indicating that the concentrations of procainamide in the hindquarters were not in equilibrium with the inferior vena cava concentrations. Lignocaine did not reach constant blood concentrations during the infusion and showed no tendency to reach arteriovenous equilibration; an arteriovenous difference of 22%(SD5%) across the hindquarters was measured during the last 60 min of the infusion. By 180 min after the lignocaine infusions, 79% (SD 8%) of the lignocaine net mass/flow had not eluted from the hindquarters when arterial and venous lignocaine concentrations were not significantly different. This drug could remain uneluted due to metabolism and/or avid tissue binding, and presents difficulties in the interpretation of pharmacokinetic data whether based on arterial or venous blood sampling.This work was funded by a grant from National Health and Medical Research Council of Australia. RNU was funded by a National Health and Medical Research Council Biomedical Postgraduate Scholarship.     

Extrahepatic production of the lignocaine metabolite monoethylglycinexylidide (MEGX).

The extrahepatic production of monoethylglycinexylidide (MEGX) from lignocaine was measured in a 20-year-old female rendered anhepatic while awaiting liver transplantation 4 days after a paracetamol overdose. Following hepatectomy and during continuous arteriovenous dialysis, cardiac stability and control over rising intracranial pressure was restored. Lignocaine (1 mg kg body weight-1 intravenously over 2 min) reached a subtherapeutic peak serum concentration of 0.89 mg l-1 and was rapidly and exponentially cleared, reaching the lower limit of detection after 5 h (cf. around 2 h in normal subjects). There was significant production of MEGX at extrahepatic sites with serum concentrations rising from undetectable levels to 15 micrograms l-1 at 15 min and to a peak of 30 micrograms l-1 at 2 h and falling thereafter. MEGX concentrations were similar in arterial, venous, and pulmonary arterial blood, suggesting minimal MEGX production in the heart, lungs or skeletal muscle. Extrahepatic production of MEGX may contribute to total MEGX formation and should be considered when interpreting test results.     

Pharmacokinetics of isosorbide dinitrate and its mononitrate metabolites after intravenous infusion

Plasma concentrations of isosorbide dinitrate (ISDN) and its two active metabolites 2-isosorbide mononitrate (2-ISMN) and 5-isosorbide mononitrate (5-ISMN) have been measured during and for 6 hr after intravenous infusion at a rate of 2.5mg/hr during 1.75 hr in six cardiac patients, by a capillary gas chromatographic method. Data were analyzed by simultaneous modeling of the observed kinetics of the three compounds. Two or three phases were detected on the postinfusion ISDN concentration-time curves. ISDN concentrations declined with a mean terminal half-life of 2.81 hr±0.7 SD. The mean systemic clearance of ISDN (2.9 L/min ±0.7 SD) and its mean total volume of distribution (259 L +- 48 SD) were relatively high. Plasma 5-ISMN concentrations were 5- to 6-fold greater than those of 2-ISMN during the whole observation period. Maximum levels of 2-ISMN (6.7 ng/ml ± 0.9 SD) and of 5-ISMN (27 ng/ml ± 6 SD) occurred within a few minutes after the end of infusion. The mean half-lives of 2-ISMN (1.59 hr± 0.19 SD) and of 5-ISMN (3.78 hr± 0.79 SD) estimated by the model were smaller than those calculated by a model-independent method (2.95 hr± 0.41 SD and 5.98 hr± 2.22, respectively), but were in good agreement with those reported in the literature following separate administration of both metabolites to man. This study shows how such modeling can distinguish between metabolite formation and elimination processes and allow the determination of metabolite half-lives after administration of the precursor drug.     

Effect of Amiodarone and Desethylamiodarone on the Pharmacokinetics of Antipyrine in the Rat

The effect of amiodarone on hepatic drug metabolism in vivo was examined in the rat using antipyrine as a model substrate. Pretreatment with oral amiodarone hydrochloride, 100 mg/kg/day, for 5 days resulted in a 19% reduction in antipyrine clearance and a 22% increase in half-life. The administration of single oral doses of amiodarone hydrochloride, 100 mg/kg, 1 or 5 hr prior to antipyrine administration had no significant effect on antipyrine pharmacokinetics. The administration of a single intravenous dose of amiodarone hydrochloride, 50 mg/kg, reduced antipyrine clearance by 32% and increased the half-life by 46%. The desethyl metabolite of amiodarone was also found to reduce antipyrine clearance (21%) after a single oral dose of 100 mg/kg.     

Pharmacokinetics of a Single Intravenous and Oral Dose of Pafenolol—a Beta1Adrenoceptor Antagonist with Atypical Absorption and Disposition Properties—in Man

The pharmacokinetics of pafenolol were studied in eight young healthy individuals. The doses were 10 mg iv and 40 mg orally. Each dose was labeled with 100 µCi [³H]pafenolol. The plasma concentration–time curve of the oral dose exhibited dual maxima. The second peak was about four times higher than the first one. Maximum concentrations were attained after 0.9 ± 0.2 and 3.7 ± 0.6 hr. The mean bioavailability (F) of the oral dose was 27.5 ± 15.5%. The reduction in F was due mainly to incomplete gastrointestinal absorption. The drug was rapidly distributed to extravascular sites; t _1/2l was 6.6 ± 1.8 min. The volumes of distribution were V _c = 0.22 ± 0.08 liter/kg, V _ss = 0.94 ± 0.17 liter/kg, and V _z = 1.1 ± 0.16 liters/kg. The iv dose of pafenolol was excreted in unchanged form in the urine to 55.6 ± 5.1% of the given dose and in the feces to 23.8 ± 5.7% within 72 hr. The corresponding recoveries of the oral dose were 15.8 ± 5.9 and 67.0 ± 10.2%, respectively. About 10% of both doses was recovered as metabolites in the excreta. Approximately 6% of the oral dose was metabolized to nonabsorbable compounds in the intestine. The mean total plasma clearance was 294 ± 57 ml/min, of which renal clearance, metabolic clearance, and gastrointestinal and/or biliary clearance were responsible for 165 ± 31, 31 ± 15, and 95 ± 32 ml/min, respectively. The half-life of the terminal phase determined from plasma levels up to 24 hr after dosing was 3.1 ± 0.3 hr for the iv dose and 6.7 ± 0.7 hr for the oral dose.     

Pharmacokinetics and bioavailability of diacetolol,the main metabolite of acebutolol

Summary The pharmacokinetics and bioavailability of diacetolol, the principal metabolite of acebutolol, were studied in 6 healthy subjects. Plasma concentrations were determined following a single intravenous injection of diacetolol 100 mg and three oral doses of diacetolol 100, 400 and 800 mg, in random order. The average oral bioavailability of diacetolol was F: 0.302±0.052 (100 mg), 0.363±0.052 (400 mg) and 0.426±0.068 (800 mg); the differences are not significant. The mean plasma half-life of the terminal phase, 7.94±0.26 h after intravenous administration, was significantly higher than after oral administration 12.27±1.00 h (100 mg), 12.82±1.59 h (400 mg) and 13.05±1.22 h (800 mg) (p<0.02 to 0.05); the mean urine half-lives of the terminal phase were not significantly different. Renal clearance of diacetolol 10.2±0.81·h^–1 represented about two-thirds of total body clearance 15.9±1.21·h^–1. The results suggest either a first-pass effect or incomplete absorption of diacetolol after oral administration.     

Lignocaine and indocyanine green kinetics in patients following myocardial infarction.

1. Blood clearances of lignocaine and indocyanine green together with indocyanine green half-lives were measured in 17 post-myocardial infarct patients (one patient was studied twice) between 8 h and 36 h after starting intravenous lignocaine infusions for the treatment of cardiac arrhythmias. 2. Mean +/- s.d. values of lignocaine clearance (ml min-1 kg-1) were higher in patients without heart failure (11.8 +/- 2.6, n = 9) than in those with heart failure (7.2 +/- 1.9, n = 9) (P < 0002). 3. Clearances of lignocaine and indocyanine green were not correlated but lignocaine clearance was directly related to the reciprocal of indocyanine green half-life (rs = 0.67, P < 0.01). 4. In eight patients who received both lignocaine and indocyanine green and in a further five patients received only lignocaine and whose lignocaine infusions lasted 24h or more, a 25% rise in lignocaine concentrations was observed between 8-12h and 24-28h. 5. The mean +/- s.d. post-infusion terminal half-life of lignocaine in four patients whose lignocaine infusions lasted 30h or longer was 7.2 +/- 2.1 h. 6. Heart failure was associated with greater changes in lignocaine kinetics than in indocyanine green kinetics. 72% of the variance between observed and predicted lignocaine clearances could be accounted for by multiple linear regression analysis incorporating indocyanine green half-life and the presence or absence of heart failure. Indocyanine green half-life contributed only 17% of the variance indicating that by itself it is of limited value in predicting lignocaine requirements. 7. Lignocaine kinetics during and after prolonged intravenous infusion were not predicted by data obtained after intravenous bolus injection. 8. A lowering of lignocaine dosage may be clinically desirable in the presence of heart failure and if an infusion lasts longer than 24 h.     

Comparative trial of mexiletine and lignocaine in the treatment of early ventricular tachyarrhythmias after acute myocardial infarction

The antiarrhythmic effects of intravenously administered lignocaine and mexiletine were compared over a period of 48 hr in a randomized trial on 24 patients who developed ventricular tachyarrhythmias within 48 hr of the onset of acute myocardial infarction. Mexiletine was given as an initial bolus of 200 mg, followed by an infusion of 1 mg/min reduced to 0.5 mg/min after 1 hr. Lignocaine was given as a bolus of 100 mg, followed by an infusion of 3 mg/min reduced to 2 mg/min after 1 hr. Plasma levels of mexiletine, lignocaine, and monoethylglycinexylidide were monitored. The frequency of "complex" ventricular tachyarrhythmias was significantly lower in the mexiletine-treated group. This group of patients also had significantly fewer ventricular extrasystoles than those receiving lignocaine, the difference being most marked during the second 24 hr of treatment. Too few episodes of ventricular fibrillation occurred for statistical comment. The greater efficacy of mexiletine was not associated with increased drug toxicity.     

Correlation between midazolam and lignocaine pharmacokinetics and MEGX formation in healthy volunteers

AIMS: The objectives of the present investigation were: (a) to determine the correlation between lignocaine and midazolam pharmacokinetics following intravenous administration in healthy volunteers, (b) to determine the effects of treatment with an inhibitor of CYP3A4 (erythromycin) on this correlation and (c) to assess the precision of the MEGX-test as a sole predictor of lignocaine and midazolam pharmacokinetics. METHODS: The study was conducted in four male and four female healthy volunteers, aged between 21 and 26 years, who received 1 mg kg-1 lignocaine HCl i.v. on days 1, 3, 5, 9 and 10 of the investigation. On days 5 and 10 they also received midazolam, 0.075 mg kg-1 i.v. and from days 6-10 they took erythromycin 500 mg orally, four times daily. Following administration of lignocaine and midazolam, frequent venous blood samples were obtained for determination of the concentrations of lignocaine, MEGX and midazolam. RESULTS: In the absence of erythromycin a statistically significant linear correlation was observed between the clearance of lignocaine and midazolam (CL(midazolam)= 0.41 x CL(lignocaine)+ 1.2; r(2) = 0.857; P < 0.001). Erythromycin cotreatment resulted in a loss of the correlation between the two clearances (r(2) = 0.39; P = 0.1). Erythromycin caused a statistically significant reduction in midazolam clearance from the original value of 3.8 to 2.5 (95% CI for the difference -2.27, -0.35) ml kg-1 min-1. Interestingly there was no significant change in the clearance of lignocaine (6.4 vs 5.8 (95% CI for the difference -2.74, -1.51) ml kg-1 min-1). Furthermore no correlation at all was observed between the MEGX-test and lignocaine or midazolam clearances. Considering the data on day 1, 3 and 5 the intra-individual coefficient of variation in the MEGX-test was 45.3% at 15 min and 23.5% at 30 min, respectively. CONCLUSIONS: It is concluded that there is a significant correlation between lignocaine and midazolam clearances but this correlation is lost after CYP3A4 inhibition by erythromycin. The MEGX-test is of no value in assessing intra- and inter-individual variability in midazolam clearance.     

The human pharmacokinetics of cefotaxime and its metabolites and the role of renal tubular secretion on their elimination

The pharmacokinetics of cefotaxime were investigated in human volunteers given constant intravenous infusions, intravenous bolus, and intramuscular doses of the drug. After intravenous dosing, the plasma levels of cefotaxime declined in a biphasic manner with a terminal half-life varying between 0.92 and 1.65 hr. Moreover, the pharmacokinetics were linear up to at least a 2.0 g dose for volume of distribution based on area (23.3–31.31), plasma clearance (249–288 ml/min), and renal clearance (151–177 ml/min). Renal tubular secretion of intact cefotaxime and each of its metabolites was demonstrated by its interaction with probenecid, although the ratio of drug to metabolites ultimately excreted in urine after probenecid was similar to that seen normally (54±6, 19±4, 6.5±0.7 and 5.5±0.7% for cefotaxime, DACM, M2, and M3, respectively, when calculated as a percentage of the dose). The observed half-lives of DACM, M2, and M3 were 2.3±0.4, 2.2 ±0.1 and 2.2 hr, respectively. However, when the true half-life of DACM was calculated (0.83±0.23 hr) it was not only significantly shorter than that observed but also shorter than that for intact cefotaxime. The plasma clearance of DACM (744 ±226 ml/min) was much higher than that of cefotaxime while the volume of distribution was of a similar order (56 ±241). When administered intramuscularly, there was good absorption of cefotaxime from the site of injection (92–94%) giving maximum plasma levels of the drug of between 30 and 35 mg/l at approximately 40 min after dosing. Thereafter, the plasma levels of cefotaxime declined in a monophasic manner with a half-life (1.0–1.2 hr) similar to that of the terminal half-life seen after intravenous administration. Lidocaine had no significant effect on either its absorption or elimination kinetics.     

The pharmacokinetics of lignocaine and beta-adrenoceptor antagonists in patients with acute myocardial infarction

Lignocaine (lidocaine) and beta-adrenoceptor antagonists are widely used after acute myocardial infarction. The therapeutic value of these agents depends on the achievement and maintenance of safe and effective plasma concentrations. Lignocaine pharmacokinetics after acute myocardial infarction (MI) are controlled by a number of variables. The single most important is left ventricular function, which affects both volume of distribution and plasma clearance. Other major factors include bodyweight, age, hepatic function, the presence of obesity, and concomitant drug therapy. Lignocaine is extensively bound to alpha 1-acid glycoprotein, a plasma protein which is also an acute phase reactant. Increases in alpha 1-acid glycoprotein concentration occur after an acute MI, decreasing the free fraction of lignocaine in the plasma and consequently decreasing total plasma lignocaine clearance without altering the clearance of non-protein-bound lignocaine. Complex changes in lignocaine disposition occur with long term infusions, and therefore early discontinuation of lignocaine infusions (within 24 hours) should be undertaken whenever possible. Because the risk of ventricular tachyarrhythmia declines rapidly after the onset of an acute MI, lignocaine therapy can be rationally discontinued within 24 hours in most patients. Lignocaine has a narrow toxic/therapeutic index, so that pharmacokinetic factors are critical in dose selection. In contrast, beta-adrenoceptor antagonists' adverse effects are more related to the presence of predisposing conditions (such as asthma, heart failure, bradyarrhythmias, etc.) than to plasma concentration. The pharmacokinetics of beta-adrenoceptor antagonists are important to help assure therapeutic efficacy, to provide information about the anticipated time course of drug action, and to predict the possible role of ancillary drug effects (such as direct membrane action) and loss of cardioselectivity. Lipid solubility is the main determinant of the pharmacokinetic properties of a beta-adrenoceptor antagonist. Lipid-soluble agents like propranolol and metoprolol are well absorbed orally, and undergo rapid hepatic metabolism, with important presystemic clearance and a short plasma half-life. Water-soluble drugs like sotalol, atenolol, and nadolol are less well absorbed, and are eliminated more slowly by renal excretion. Clinical assessment of beta-adrenoceptor antagonism is more valuable than plasma concentration determinations in evaluating the adequacy of the dose of a particular beta-adrenoceptor antagonist.(ABSTRACT TRUNCATED AT 400 WORDS)     

Impulse-response Studies on Tracer Doses of [14C]Lignocaine and its Multiple Metabolites in the Perfused Rat Liver

The outflow-concentration-time profiles for lignocaine (lidocaine) and its metabolites have been measured after bolus impulse administration of [¹⁴C]lignocaine into the perfused rat liver. Livers from female Sprague-Dawley rats were perfused in a once-through fashion with red-blood-cell-free Krebs-Henseleit buffer containing 0 or 2% bovine serum albumin. Perfusate flow rates of 20 and 30 mL min^? were used and both normal and retrograde flow directions were employed. Significant amounts of metabolite were detected in the effluent perfusate soon after lignocaine injection. The early appearance of metabolite contributed to bimodal outflow profiles observed for total ¹⁴C radioactivity. The lignocaine outflow profiles were well characterized by the two-compartment dispersion model, with efflux rate «influx rate. The profiles for lignocaine metabolites were also characterized in terms of a simplified two-compartment dispersion model. Lignocaine was found to be extensively metabolized under the experimental conditions with the hepatic availability ranging between 0.09 and 0.18. Generally lignocaine and metabolite availability showed no significant change with alterations in perfusate flow rate from 20 to 30 mL min^? or protein content from 0 to 2%. A significant increase in lignocaine availability occurred when 1200 μm unlabelled lignocaine was added to the perfusate. Solute mean transit times generally decreased with increasing flow rate and with increasing perfusate protein content. The results confirm that lignocaine pharmacokinetics in the liver closely follow the predictions of the well-stirred model. The increase in lignocaine availability when 1200 μm unlabelled lignocaine was added to the perfusate is consistent with saturation of the hydroxylation metabolic pathways of lignocaine metabolism.