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 (5.5 mg/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 arterio-venous equilibration; an arterio-venous difference of 22% (SD 5%) 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.     

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.     

Logical approach to lignocaine therapy.

Plasma lignocaine concentrations were measured during and after lignocaine infusions administered for suppressing ventricular dysrhythmias. Twenty-four patients with a primary diagnosis of acute myocardial infarction without gross circulatory disturbance received, after a bolus of lignocaine, either 4 mg/min for 30 minutes, 2 mg/min for two hours, then 1 mg/min thereafter or 1 mg/min throughout. The higher dose regimen produced continous therapeutic levels of lignocaine, which were achieved only after four hours by the lower dose. On the other hand, in patients who had undergone cardiac surgery and who had circulatory and heptic dysfunction the lower dose regimen achieved therapeutic levels early. The plasma half life was longer in the surgical group (P less than 0.02). The higher initial infusion rate is recommended for patients with acute myocardial infarction without gross circulatory impairment.     

Pharmacokinetics of recombinant human superoxide dismutase.

Superoxide dismutase (SOD) disposition was studied in order to design a rational approach for drug administration in the setting of acute myocardial infarction. Four chronically instrumented conscious dogs received the following dosage regimens of recombinant human SOD (rhSOD) on successive days: (a) 5 mg/kg left atrial (LA) bolus, (b) 5 mg/kg central vein (CV) bolus, (c) 15 mg/kg CV bolus, and (d) 5 mg/kg CV infusion over 60 min; additionally, all dogs received (e) a 5 mg/kg CV bolus under pentobarbital anesthesia. Serial serum samples were obtained after each dose and serial myocardial samples were obtained after dose (e). The serum rhSOD concentration was measured by radioimmunoassay and the data were fit to a two-compartment model. The distribution half-life was 7.8 +/- 1.7 min (mean +/- SEM), and the elimination half-life was 51.1 +/- 5.9 min; the central compartment volume of distribution (Vc) was 81 +/- 26 ml/kg and the steady-state volume of distribution was 156 +/- 20 ml/kg. The dosage regimen had no influence on clearance rates. Peak plasma concentrations (micrograms/ml) for the dosage regimens were (a) 65 +/- 28, (b) 89 +/- 19, (c) 214 +/- 61, (d) 20 +/- 5, and (e) 86 +/- 9. The peak level following continuous infusion did not occur until 50 min of infusion and was only one-fourth of the level achieved with a bolus of the same dose. Myocardial levels were less than 1% of serum levels, suggesting negligible rhSOD penetration into the myocardium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Impaired Lignocaine metabolism in patients with myocardial infarction and cardiac failure.

Plasma concentrations of lignocaine were measured during and after infusion of lignocaine at 1.4 mg/min for 36-46 hours in 12 patients with myocardial infarction and one patient with cardiac failure due to uncontrolled ventricular tachycardia. In six patients without cardiac failure the plasma concentrations of lignocaine rose progressively during the infusion and the mean lignocaine half life was 4.3 hours compared with 1.4 hours in healthy subjects. Mean plasma lignocaine concentrations were significantly higher in seven patients with cardiac failure, and concentrations also rose during the infusion and the half life was considerably prolonged to 10.2 hours. Lignocaine concentrations rose rapidly to toxic levels when cardiogenic shock developed in one patient and did not fall when the infusion was stopped. The mean plasma antipyrine half life was moderately prolonged (19.4 hours) in a larger group of patients with myocardial infarction and cardiac failure but returned to normal during convalescence (13.2 hours). The metabolism of lignocaine is grossly abnormal in patients with cardiac failure and cardiogenic shock after myocardial infarction.     

The appropriate dosage regime for the transition from intravenous lignocaine to oral tocainide after acute myocardial infarction

Summary To define the appropriate regime for the transition from intravenous lignocaine to oral tocainide after uncomplicated acute myocardial infarction, 43 patients received lignocaine to steady state. Each patient then received a tocainide dosage schedule. Plasma concentration of lignocaine and tocainide was measured frequently until the third peak plasma tocainide level. Tocainide 400 mg 8 hourly starting 4 h before cessation of lignocaine and tocainide 400 mg 4 hourly starting at the end of the infusion produced therapeutic plasma tocainide concentration (3.5–9 mg/l) only after the second dose. Tocainide 600 mg 12 hourly starting 6 h before cessation of lignocaine and tocainide 600 mg 6 hourly starting at the end of the infusion quickly achieved therapeutic plasma tocainide concentration which declined to give subtherapeutic first dose troughs of 2.42 mg/l (±0.28 SEM) and 2.79 mg/l (±0.27 SEM) respectively. Consistently therapeutic plasma tocainide concentrations were achieved by both of these regimes after the second dose. The short plasma halflife of lignocaine which for these regimes was 3.71 h (±0.25 SEM), resulted in subtherapeutic lignocaine concentrations before consistently therapeutic plasma tocainide concentrations had been achieved. On the basis of these results, the 600 mg 6 hourly tocainide dosage schedule was studied with cessation of lignocaine infusion either two or six h after the first tocainide dose. With the former regime only three of 5 patients had therapeutic lignocaine at the subtherapeutic tocainide trough. When lignocaine was discontinued on administration of the second tocainide dose however, therapeutic lignocaine concentration was maintained in all patients until tocainide was rising within the therapeutic range. The latter regime, which we would recommend, was not accompanied by increased side effects. Steady state tocainide was found to be present 12 h after the third tocainide dose allowing continued therapy with tocainide 600 mg 12 hourly.     

The influence of drug sorption on pharmacokinetic studies of chlormethiazole and lignocaine

The influence of drug sorption on the measurement of dose and blood concentrations during pharmacokinetic studies of chlormethiazole and lignocaine in a chronically catheterized sheep preparation has been examined. There was no sorption to soda glass tubes, borosilicate glass volumetric flasks or soda glass microlitre syringes but minor sorption to polypropylene syringes, polypropylene pipette tips and rubber bottle stoppers after 240 min contact. During infusions through administration sets including either polyvinyl chloride or polyethylene catheters, no significant loss of lignocaine occurred, but only 41.7-63.9% of the chlormethiazole dose was delivered. No significant decreases in either drug occurred from blood sampled through an intravascular catheter and stopcock system. There was negligible degradation of the samples over 4 h. Sorption of chlormethiazole or lignocaine to the laboratory equipment used was not a significant source of error but polyvinyl chloride infusion catheters could result in significant reductions in chlormethiazole dose.     

HI-6 pharmacokinetics in rabbits after intravenous and intramuscular administration.

The pharmacokinetics of HI-6 ((4-carboxamidopyridinium (1) methyl)-(2'-hydroxyiminomethyl-pyridinium (1') methyl) ether dichloride) have been studied in rabbits receiving an intramuscular (50 micrograms kg-1) or intravenous (12.5 micrograms kg-1) dose. The plasma concentration-time profile for the intramuscular dose (n = 8) fits a one-compartment open model with first-order absorption and elimination. The absorption half-life was 2 min and maximum concentration (51 micrograms mL-1) was reached in 9 min. The pharmacokinetics for the intravenous dose (n = 8) was described by a two-compartment open model with first-order distribution and elimination. The apparent volume of distribution was 0.1 L kg-1. Half-lives of distribution and elimination were 5 and 38 min, respectively. The results indicate HI-6 is rapidly absorbed, distributed and eliminated in rabbits receiving an intramuscular dose.     

Effects of lignocaine and propranolol on experimental cardiac arrhythmias

1. The effects of intravenous injection of lignocaine and propranolol were studied in dogs.2. Ventricular ectopic beats produced by intravenous injection of adrenaline in anaesthetized dogs respired with halothane were abolished in four out of six dogs by lignocaine. Propranolol was effective in all three dogs tested.3. Intravenous infusion of lignocaine at (0.2 and 1.0 mg/kg)/min to total doses of 3.0 +/- 1.0 and 2.2 +/- 0.5 mg/kg, respectively, abolished the ventricular tachycardia produced in anaesthetized dogs by ouabain. A similar effect was produced by infusion of propranolol at (0.2 mg/kg)/min to a total dose of 1.9 +/- 0.4 mg/kg. Intravenous injection of single doses of lignocaine (4.0-8.0 mg/kg) also abolished the arrhythmia.4. The frequency of the ventricular ectopic beats occurring in conscious dogs 20-44 h after ligation of the anterior descending branch of the left coronary artery was reduced, with an increase in the number of sinus beats, after intravenous injection of lignocaine (8.0 mg/kg). Larger doses produced excitement. Propranolol (4.0 mg/kg) had a greater effect than the same dose of lignocaine but after 8.0 mg/kg, three of the four dogs died.5. Propranolol was more effective than lignocaine in abolishing the three different types of arrhythmia.6. Dose-response curves showed that lignocaine was more active in abolishing the ouabain induced arrhythmia than the halothane-adrenaline arrhythmia and was least active on the arrhythmia caused by ligation of the coronary artery.     

The use of mass balance principles to describe regional drug distribution and elimination

Mass balance principles were used to derive a number of terms that are helpful in describing the rate and extent of regional drug uptake. Regional drug uptake was defined as the net movement of drug from the blood perfusing a region into the extravascular space of the region due to the distribution and/or elimination of the drug. By analogy with the traditional physiological definition of flux, net drug flux was defined as the difference in mass per unit time of drug respectively entering and leaving a region via the arterial and venous blood vessels. The time-integral of net drug flux, net drug mass, was defined as the mass of drug that has entered a region via the arterial blood vessels but has not left the region via the venous blood vessels. For regions in which no drug elimination occurs, the mean regional drug concentration was defined as the net drug mass divided by the mass of the region. When a number of criteria are satisfied, the net drug flux is approximately the rate of drug uptake and the net drug mass is approximately the extent of drug uptake. Several examples are given to demonstrate the broad range of applications of mass balance principles. First, the method was used to characterize the differences between drug distribution and elimination in a hypothetical region using drug concentrations simulated from compartmental models of either distribution alone or distribution with elimination. Second, the whole body distribution net flux was described during a constant rate infusion of iodohippurate (IOH) into a sheep from the difference between the whole body net flux and renal net flux of IOH. Third, the time course of the mean myocardial lignocaine (lidocaine) concentrations in a sheep after an intravenous bolus of lignocaine were described. The time course of the lignocaine-induced depression of myocardial contractility followed more closely the mean myocardial lignocaine concentrations than that of either the arterial or coronary sinus blood concentrations. It is concluded that the use of mass balance principles provides a simple, empirical, and physiologically based method for the determination of the rate and extent of both drug distribution and elimination in regions as simple as single organs or as complex as the whole body.     

ENDOTOXIN ALTERS THE SYSTEMIC DISPOSITION OF NITRIC OXIDE SYNTHASE INHIBITORS IN THE AWAKE SHEEP

1. We evaluated the haemodynamic effects and systemic disposition of the nitric oxide synthase (NOS) inhibitor N^L-nitro-L-arginine (NOLA) after intravenous (i.v.) administration of two different doses (5 and 20 mg/kg) in awake healthy sheep and awake sheep given a continuous i.v. infusion of endotoxin (lipopolysaccharide, 12 ng/kg per h, i.v., for 18 h). In addition, we determined the systemic disposition of another NOS inhibitor, N^L-nitro-L-arginine methylester (L-NAME; 20 mg/kg, i.v.) in awake healthy sheep only. 2. A^rL-Nitro-L-arginine produced a dose-dependent decrease in heart rate (HR) and cardiac output (CO) together with a dose-dependent increase in mean arterial pressure (MAP) and peripheral vascular resistance (PVR) when compared to baseline. In endotoxic sheep NOLA produced a greater increase in MAP and mean pulmonary arterial pressure (MPAP). 3. In healthy sheep there was a dose-related increase in total body clearance (CI) of NOLA. The CI increased from 0.028 L/min after the lower dose to 0.032 L/min after the higher dose. The infusion of endotoxin caused an increase in CI of NOLA to 0.040 and 0.047 L/min, respectively, and a decrease in plasma slow half-life (t_1/2 from 825 to 546 min and from 780 to 453 min, respectively. 4. N^L-Nitro-L-arginine methylester was rapidly cleared from the plasma with a slow half-life of approximately 7.5 min and there was a simultaneous appearance of NOLA in the plasma. 5. These results support the view that nitric oxide has a significant role in regulating vascular tone in healthy and endotoxic sheep and indicate that the increases in CI of NOLA with an increase in its dose and the presence of endotoxin will be important in influencing appropriate dosage regimens in clinical studies.     

Phenobarbital pharmacokinetics in obesity. A case report.

A morbidly obese woman [190 kg total bodyweight (TBW)] was admitted to hospital with a rapidly progressing wound infection. Over the next 2 weeks the patient developed congestive heart failure, acute renal failure, septic shock and multiple seizure episodes. Intravenous phenobarbital was added to phenytoin therapy to achieve seizure control. A total loading dose of phenobarbital 3700 mg (19.5 mg/kg TBW) was administered in 3 divided doses. The initial dose of 1100 mg resulted in a serum phenobarbital concentration of 6.3 mg/L 5h postinfusion, a second 1100 mg dose increased the concentration to 13.1 mg/L 1h postinfusion and a final dose of 1500 mg resulted in a 22.5 mg/L concentration at the end of the infusion. A phenobarbital maintenance regimen of 120 mg every 12h was then started. Peak serum concentrations of 19.8 and 17.8 mg/L were measured. All of the available serum phenobarbital concentrations and dosage amounts were fitted with least-squares nonlinear regression analysis to a 1-compartment model. An apparent volume of distribution (Vd) of 154.9L (0.82 L/kg TBW), total body clearance (CL) of 29 ml/min (1.74 L/h) and elimination half-life of 61h were determined. Our case report suggests that the dose of intravenous phenobarbital should be calculated using TBW. Additional studies are needed to precisely define the appropriate dosage weight, serum concentrations and clinical efficacy associated with intravenous phenobarbital in morbidly obese patients.     

Disposition of HI-6 oxime in rats after intravenous and intramuscular administration

The pharmacokinetics of HI-6, a cholinesterase-reactivating oxime, were studied in rats, following intravenous or intramuscular administration. A two-compartment model was used to analyse the intravenous data and a one-compartment open model with first-order absorption was used for intramuscular data. Drug concentration had no influence on rate and extent of absorption of intramuscular injections, and bioavailability was 100%. Peak plasma concentrations of HI-6 occurred 15 min after intramuscular injection. No significant differences were found between mean values for half-life, plasma clearance, volume of distribution and area under the plasma concentration versus time curve for the two intramuscular doses and the intravenous dose used. Mean HI-6 plasma concentrations were 140.5 +/- 4.2 micrograms ml-1 3 min after 20 mg ml-1 i.v., with a mean elimination half-life of 65.2 +/- 21 min. Plasma clearance rate was 3.95 +/- 0.93 ml min-1 kg and the apparent volume of distribution was 0.38 +/- 0.17 litre kg-1. The oxime is rapidly distributed in and eliminated by rats when administered intravenously or intramuscularly.     

On the role of alpha 1-acid glycoprotein in lignocaine accumulation following myocardial infarction.

1 Blood plasma and free lignocaine concentrations have been measured 12 h after beginning a constant infusion of 2 mg/min and again at the end of the infusion (36-72 h) in five patients with myocardial infarction (MI) and compared with five control patients who did not develop objective evidence of MI. 2 In MI patients, total plasma concentration rose significantly between 12 h and the end of infusion. Because of an increase in alpha 1 acid glycoprotein (AAG) plasma binding increased, so that free drug concentration did not change. The rise in whole blood concentration was less than that in plasma as a result of drug redistribution out of red cells due to enhanced binding. 3 In control patients, neither blood nor plasma concentrations changed with time and plasma binding remained constant. Free drug concentrations, however, rose slightly. 4 The concentrations of GX and MEGX remained unchanged in all patients, but the ratio of lignocaine/MEGX concentrations fell in controls but rose in MI patients. 5 Pharmacokinetic modelling suggested that at least some of the rise in blood lignocaine concentration was due to reduced clearance resulting from enhanced plasma binding. 6 We conclude that the rise in AAG following MI is responsible for increased plasma binding and drug redistribution within blood. These changes, together with a reduction in lignocaine clearance, can explain much of the phenomenon of lignocaine accumulation in MI.     

Pharmacokinetics of lignocaine and bupivacaine in surgical patients following epidural administration. Simultaneous investigation of absorption and disposition kinetics using stable isotopes

The pharmacokinetics of lignocaine (lidocaine) and bupivacaine following epidural administration were studied in 12 surgical patients using a stable isotope method. Shortly after epidural administration of the agent to be evaluated, a deuterium-labelled analogue was administered intravenously. Plasma concentrations of the unlabelled and the deuterium-labelled local anaesthetics were determined using gas chromatography and mass fragmentography. The pharmacokinetic behaviour of both agents was consistent with a 2-compartment open model and two parallel first-order absorption processes. The mean distribution and elimination half-lives were 12 minutes and 100 minutes for lignocaine, and 22 minutes and 143 minutes for bupivacaine. The mean volumes of the central compartment and the mean steady-state volumes of distribution were: lignocaine, 43L and 99L; bupivacaine, 33L and 68L. Total plasma clearances averaged 0.95 L/min (57 L/h) for lignocaine and 0.52 L/min (31.2 L/h) for bupivacaine. The half-lives, characterising the fast and slow absorption processes, were 9.3 and 82 minutes for lignocaine, and 7.0 minutes and 362 minutes for bupivacaine; the fractions of the doses absorbed in the fast and slow processes were lignocaine 0.38 and 0.58, bupivacaine 0.28 and 0.66, respectively. The results indicate that the local anaesthetics are completely absorbed from the epidural space into the general circulation. The initial absorption rates of both local anaesthetics appear to be similar, but, later, the absorption of bupivacaine proceeds much more slowly than the absorption of lignocaine.     

Disposition of phenytoin in critically ill trauma patients

Estimates of phenytoin pharmacokinetic variables and protein binding were determined in 10 adult critically ill trauma patients. Each study subject received phenytoin sodium as an intravenous loading dose of 15 mg/kg, followed by an initial intravenous maintenance dose of 6 mg/kg/day. Serial blood samples were obtained throughout the seven-day study period and analyzed for total and unbound serum phenytoin concentrations. The concentration data for each patients were fitted to a one-compartment model with elimination defined by the Michaelis-Menten constant Km and the maximum rate of metabolism (Vmax) and to a one-compartment model with first-order elimination. The Michaelis-Menten model used Bayesian parameter estimation while the linear model used weighted non-linear least-squares regression analysis. Unbound phenytoin fraction ranged from 0.073 to 0.25. Free fraction increased 7% to 108% in 9 of 10 patients (median increase 29%) from day 1 to day 7 of therapy. Variable estimates using the Michaelis-Menten model were as follows: volume of distribution, 0.76 +/- 0.15 L/kg (0.58-1.01 L/kg); Vmax, 568 +/- 197 mg/day (350-937 mg/day); and Km, 4.5 +/- 1.8 mg/L (1.8-6.2 mg/L). These estimates fell within the wide range of values obtained in studies using stable patients or healthy volunteers. The Michaelis-Menten model was significantly less biased and more precise than the linear model. Three of four patients who continued to receive their study maintenance dose had substantially lower measured total serum concentrations of phenytoin than predicted using the study variable estimates.(ABSTRACT TRUNCATED AT 250 WORDS)     

The use of mass balance principles to describe regional drug distribution and elimination

Mass balance principles were used to derive a number of terms that are helpful in describing the rate and extent of regional drug uptake. Regional drug uptake was defined as the net movement of drug from the blood perfusing a region into the extravascular space of the region due to the distribution and/or elimination of the drug. By analogy with the traditional physiological definition of flux, net drug flux was defined as the difference in mass per unit time of drug respectively entering and leaving a region via the arterial and venous blood vessels. The timeintegral of net drug flux, net drug mass, was defined as the mass of drug that has entered a region via the arterial blood vessels but has not left the region via the venous blood vessels. For regions in which no drug elimination occurs, the mean regional drug concentration was defined as the net drug mass divided by the mass of the region. When a number of criteria are satisfied, the net drug flux is approximately the rate of drug uptake and the net drug mass is approximately the extent of drug uptake. Several examples are given to demonstrate the broad range of applications of mass balance principles. First, the method was used to characterize the differences between drug distribution and elimination in a hypothetical region using drug concentrations simulated from compartmental models of either distribution alone or distribution with elimination. Second, the whole body distribution net flux was described during a constant rate infusion of iodohippurate (IOH) into a sheep from the difference between the whole body net flux and renal net flux of IOH. Third, the time course of the mean myocardial lignocaine (lidocaine) concentrations in a sheep after an intravenous bolus of lignocaine were described. The time course of the lignocaine-induced depression of myocardial contractility followed more closely the mean myocardial lignocaine concentrations than that of either the arterial or coronary sinus blood concentrations. It is concluded that the use of mass balance principles provides a simple, empirical, and physiologically based method for the determination of the rate and extent of both drug distribution and elimination in regions as simple as single organs or as complex as the whole body.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.     

Influence of lignocaine on plasma protein binding and pharmacokinetics of verapamil in dogs

The effect of lignocaine (lidocaine) on the plasma protein binding of verapamil has been studied in-vitro and in-vivo in dogs. The binding of verapamil was ca 85%. In-vitro addition of lignocaine at therapeutic concentrations displaced verapamil from its plasma binding sites. Lignocaine in this regard was equipotent with tris(2-butoxyethyl)phosphate, suggesting an interaction at the level of alpha 1-acid glycoprotein binding sites. On in-vivo administration of 4 mg kg-1 in a bolus to dogs in which steady state concentrations of verapamil were present, the free fraction of verapamil increased transiently. During the lignocaine maintenance infusion, it then decreased to a level higher than that before administration of the local anaesthetic. The free verapamil concentrations increased suddenly upon the administration of the lignocaine loading dose, and then returned to values slightly higher than those before lignocaine. After a bolus injection of verapamil during a lignocaine infusion, the verapamil total plasma concentrations were lower than during a saline infusion, but the free concentrations were not different. The volume of distribution of verapamil was increased, whereas the blood clearance had not changed; the lignocaine infusion did not change the hepatic blood flow, as measured by indocyanine green clearance. These results show that lignocaine displaces verapamil in-vitro and in-vivo from its plasma protein binding sites, but the ensuing pharmacokinetic changes do not lead to significant changes in free verapamil concentrations.     

Gentamicin monitoring in neonates

The elimination of gentamicin (G) was studied in 103 neonates (30 premature) during the first month of life after 2.5 mg/kg i.v. (as infusion) over 20-30 min. G plasma levels, measured by EMIT assay, were obtained before and at 1, 2, 3, and 6 h after infusion. We derived individual first-order kinetic parameters and designed optimal dose regimens. G plasma clearance, half-life, and recommended dose (mg/kg/h) changed exponentially with postnatal age during the first 14 days of life. No significant changes in kinetic values were noted during the first 3 days of life; however, they varied linearly with gestational age when they were measured during this period. Apgar score at 10 min and blood urea nitrogen significantly influenced the same parameters. The predictive value of a designed dose regimen was evaluated at steady-state, after dosage adjustment using two plasma concentration values: the minimum plasma concentration was below 2 mg/L in 93% of the patients; the plasma concentration observed within 1 h after completion of the infusion was (mean +/- SD) 5.33 +/- 0.97 mg/L. Our data suggest that 2.5 mg/kg every 12 h is appropriate in most neonates except for 0-2-day-old premature infants who require 2.5 mg/kg every 18 h. Monitoring of G plasma levels is advisable in infants with low Apgar score and/or renal failure.     

Myocardial uptake of lignocaine: pharmacokinetics and pharmacodynamics in the isolated perfused heart of the rabbit.

1. The uptake kinetics and pharmacodynamics of lignocaine were studied in isolated perfused heart of the rabbit. 2. Six hearts were perfused with increasing concentrations of lignocaine in a modified Krebs-Henseleit buffer. The effluent concentration together with the increase in QRS duration were measured during lignocaine infusion and during 20 min after cessation of lignocaine infusion. 3. Lignocaine disposition and elimination were best described by a two-compartment open model. Terminal half-life was 11.0 +/- 2.9 min. The unidirectional transfer was slower from central to peripheral compartment than from peripheral to central compartment (T1/2.12 = 42.6 +/- 10.5 min whereas T1/2.21 = 10.7 +/- 2.8 min). The myocardium/perfusate concentration-ratio was 4.7 +/- 0.4. 4. The pharmacodynamic effect was best described in the central compartment by using the Hill equation. Calculated maximum QRS duration (Emax) was 77 +/- 8 ms. Emax was also directly measured in four additional rabbits by infusing ten times the dose of lignocaine used in the main experiment: the value of Emax measured in these conditions was 92.5 +/- 9.6 ms, i.e. a QRS widening of 150%. The steady-state perfusate concentration producing half the effect (C50) was 15.7 +/- 7.6 micrograms ml-1. 6. In conclusion, the specific lignocaine binding leading to increase in QRS duration appeared to be more closely related to the vascular stream than non specific binding leading to a deeper accumulation process.