Propofol: Assay and regional mass balance in the sheep

1. Pharmacokinetic data for propofol, a new intravenous anaesthetic agent, indicate that there may be extensive extrahepatic clearance. This was investigated during intravenous infusions of propofol in adult merino ewes with chronic intravascular cannulae using a newly developed simple and rapid assay for propofol in blood and other biological samples.

2. The assay was based on organic solvent extraction of pH 4.5 buffered blood, urine or tissue homogenate, followed by reverse-phase?h.p.l.c. with fluorescence detection.

3. A mean total body clearance of propofol of 3.151/min, (SD 0.871/min; n=8) was found, consistent with a high hepatic extraction ratio (overall mean 0.87, SD 0.19; n=8) and clearance (overall mean 1.12, SD 0.251/min; n=7). The difference between total and hepatic clearances consisted principally of pulmonary clearance, but its extent was variable.

4. Other regional pharmacokinetic data were consistent with propofol distribution into muscle and brain tissues and propofol ‘production’ by the kidney, probably from a propofol metabolite formed elsewhere.

5. If these data are confirmed in humans then clinical pharmacokinetic data so far derived from peripheral venous blood sampling will require re-evaluation.     

Clinical pharmacokinetics of clozapine in chronic schizophrenic patients

Summary The clinical pharmacokinetics of clozapine, an atypical neuroleptic, was evaluated in 10 chronic schizophrenic male patients after intravenous and oral administration. The mean equilibrium-state concentration ratio between blood and plasma was experimentally determined to be 0.87. The average values for blood clearance, hepatic extraction ratio and oral bioavailability were 250 ml/min, 0.2 and 0.27, respectively. Plasma concentration peaked on average at 3 h. The mean volume of distribution at steady-state and the terminal half-life was 1.6 l/kg and 10.3 h, respectively. A large fraction of the dose is most probably metabolized by some extrahepatic presystemic routes. The large inter-individual variability in the bioavailability and clearance is probably the main reason for large variation in the steady-state plasma level in patients receiving the same oral dosage regimen.     

Propofol in cesarean section. A pharmacokinetic and pharmacodynamic study

The induction properties and pharmacokinetics of propofol, 2.5 mg/kg i.v., were studied in twelve unpremedicated healthy pregnant patients at term. The onset of anesthesia was rapid (27.7 +/- 7.3 sec) and the quality of induction, maintenance of and rapid recovery from anesthesia were clinically very acceptable. On the basis of Apgar scores and blood gas analyses of the feto-placental unit, propofol appears to be a safe alternative to other available induction agents. The pharmacokinetics of propofol in pregnant women (n = 8) were described by a high value for total body clearance (mean 2189.6 ml/min) and a short elimination half-life (mean 24.1 min). There was no correlation between the pharmacokinetic parameters determined for propofol and some pharmacodynamic observations during the induction of anesthesia (n = 8), nor was there any correlation between drug levels of propofol in the feto-placental unit and blood-gas tensions and pH values or Apgar scores (n = 12).     

Kidneys contribute to the extrahepatic clearance of propofol in humans, but not lungs and brain

AIMS: The principal site for the metabolism of propofol is the liver. However, the total body clearance of propofol is greater than the generally accepted hepatic blood flow. In this study, we determined the elimination of propofol in the liver, lungs, brain and kidneys by measuring the arterial-venous blood concentration at steady state in patients undergoing cardiac surgery. METHODS: After induction of anaesthesia, propofol was infused continuously during surgery. For measurement of propofol concentration, blood samples were collected from the radial and pulmonary artery at predetermined intervals. In addition, blood samples from hepatic and internal jugular vein were collected at the same times in 19 patients in whom a hepatic venous catheter was fitted and the other six in whom an internal jugular venous catheter was fitted, respectively. In six out of 19 patients fitted with a hepatic venous catheter, blood samples from the radial artery and the renal vein were also collected at the same time, when the catheter was inserted into the right renal vein before insertion into the hepatic vein. RESULTS: Hepatic clearance of propofol was approximately 60% of total body clearance. The hepatic extraction ratio of propofol was 0.87 +/- 0.09. There was no significant difference in the concentration of propofol between the radial, pulmonary arteries and internal jugular vein. However, a high level of propofol extraction in the kidneys was observed--the renal extraction ratio being 0.70 +/- 0.13. CONCLUSIONS: We have demonstrated substantial renal extraction of propofol in human. Metabolic clearance of propofol by the kidneys accounts for almost one-third of total body clearance and may be the major contributor to the extrahepatic elimination of this drug.     

Pharmacokinetics and pharmacodynamics of propofol in patients undergoing abdominal aortic surgery

Available propofol pharmacokinetic protocols for target-controlled infusion (TCI) were obtained from healthy individuals. However, the disposition as well as the response to a given drug may be altered in clinical conditions. The aim of the study was to examine population pharmacokinetics (PK) and pharmacodynamics (PD) of propofol during total intravenous anesthesia (propofol/fentanyl) monitored by bispectral index (BIS) in patients scheduled for abdominal aortic surgery. Population nonlinear mixed-effect modeling was done with Nonmem. Data were obtained from ten male patients. The TCI system (Diprifusor) was used to administer propofol. The BIS index served to monitor the depth of anesthesia. The propofol dosing was adjusted to keep BIS level between 40 and 60. A two-compartment model was used to describe propofol PK. The typical values of the central and peripheral volume of distribution, and the metabolic and inter-compartmental clearance were V(C) = 24.7 l, V(T) = 112 l, Cl = 2.64 l/min and Q = 0.989 l/min. Delay of the anesthetic effect, with respect to plasma concentrations, was described by the effect compartment with the rate constant for the distribution to the effector compartment equal to 0.240 min(-1). The BIS index was linked to the effect site concentrations through a sigmoidal E(max) model with EC(50) = 2.19 mg/l. The body weight, age, blood pressure and gender were not identified as statistically significant covariates for all PK/PD parameters. The population PK/PD model was successfully developed to describe the time course and variability of propofol concentration and BIS index in patients undergoing surgery.     

Disposition Kinetics of Intravenous Halofantrine-HCl in an Animal Model

Abstract

The disposition kinetics of intravenous halofantrine-HCl was studied in beagle dogs. In a dose-ranging study, three dose levels of halofantrine, 2.5 mg/kg, 5 mg/kg, and 10 mg/kg, were administered intravenously by infusion pump over 10 min or 2 h. the mode of intravenous administration of halofantrine was well tolerated by all animals. the 5 mg/kg dose infused over a period of 10 min produced adequate blood and plasma levels for pharmacokinetic analysis. therefore, this dose and infusion rate was employed in the definitive study.

The disposition of halofantrine followed a tri-exponential decline. the mean (± SD) elimination clearance is 15.7 ± 4.3 L/h for blood and 12.9 ± 2.6 L/h for plasma; while the steady-state volume of distribution for blood and plasma are 275.7 ± 165.9 L and 402.0 ± 205.6 L respectively. the terminal elimination half-lives in blood and plasma are 111.3 ± 72.1 h for blood and 192.8 ± 104.5 h for plasma.

Halofantrine was observed to be a low extraction drug with hepatic extraction ratio of approximately 0.25 and, is highly distributed in the peripheral compartments. It has a short mean residence time of about 0.3 h in the central compartment and there was evidence of preferential concentration of desbutyl-halofantrine in red blood cells. the implications of these in malaria therapy with halofantrine is unknown.     

Pharmacokinetics of postoperative intravenous indomethacin in children

The disposition of indomethacin was studied in children aged one to four years. Indomethacin 0.35 mg/kg was administered as an intravenous infusion during 15 min. Venous blood samples were collected until 24 hr after infusion. Serum indomethacin was determined with gas chromatography. Using a non-linear regression analysis, the individual data were fitted by a two-compartment open mammillary model with central elimination. Calculated pharmacokinetic parameters were (mean +/- SD); alpha half-life 25.2 +/- 11.3 min; beta half-life 366 +/- 295 min; steady-state volume of distribution 0.74 +/- 0.75 l/kg; volume during elimination phase 1.53 +/- 1.27 l/kg; total body clearance 3.2 +/- 1.7 ml/min./kg. Accordingly, with respect to the pharmacokinetics of indomethacin, children seem to mature early, not later than at the age of one year.     

Pharmacokinetics of haloperidol in psychotic patients

Nine psychotic patients under continuous oral treatment with haloperidol were randomly given a test dose of 1.5–5 mg haloperidol orally and/or intravenously. Serum levels of haloperidol were determined by high performance liquid chromatography and serum concentration data obtained were submitted to pharmacokinetic analysis. The steady state concentration ratio between blood and plasma was determined and found to be 0.79±0.03. The blood clearance was then calculated to be 550±133 ml/min. The mean hepatic extraction ratio was intermediate (0.37). Consequently, for a drug mainly eliminated by hepatic metabolism like haloperidol, the total blood clearance and the extent of oral bioavailability can be affected by changes in hepatic blood flow, hepatic enzyme activities and drug binding. During continuous oral treatment with haloperidol, however, it can be shown that changes in the total metabolic capacity of the liver due to hepatic enzyme induction or inhibition should be important for the therapeutic effects of haloperidol. The volume of distribution at steady state (Vdss) was large (7.9±2.5 l/kg). The terminal half-life was 18.8 h after intravenous and 18.1 h after oral administration. The oral bioavailability (0.60±0.18) were in accordance with previous results in healthy subjects. A mean lag time after oral dose was 1.3±1.1 h and a longer absorption half-life (1.9±1.4 h) was found in the patients compared with healthy volunteers.     

Stereospecific assay of nicoumalone: application to pharmacokinetic studies in man.

1. A stereospecific h.p.l.c. assay of nicoumalone in plasma has been developed. 2. The assay was applied to a study in which 20 mg racemic nicoumalone was given orally to three volunteers and blood samples taken for 168 h. 3. The mean pharmacokinetic parameters of the individual enantiomers were: clearance/bioavailability 1.28 1 h-1, R-enantiomer; 17.5 1 h-1, S-enantiomer: volume of distribution/bioavailability 12.5 1, R-enantiomer; 22.6 1, S-enantiomer: terminal half-life 6.8 h, R-enantiomer; 0.91 h, S-enantiomer. 4. The data are consistent with a substantial first-pass hepatic loss of S-nicoumalone.     

An integrated study of pharmacokinetics and pharmacodynamics of chlormethiazole in healthy young volunteers

Summary Chlormethiazole ethanedisulphonate (0.8%) (Hemineurin, Astra) was administered to 10 healthy unpremedicated volunteers at a constant-rate infusion of 2.5 ml/min for 60 min (Phase 1, n=5) and 113 min (Phase 2, n=5). With one exception, chlormethiazole blood concentration-time data were described by a two-compartment open model. Total body clearance was the same in both phases (1.15 l · min^–1, SD 0.49; and 1.05 l · min^–1, SD 0.36 respectively) and was similar to the clearance of indocyanine green. No correlation was found between clearance, initial dilution volume (137 l, SD 62; and 125 l, SD 33 in 1 and 2 phases respectively) or volume of distribution at steady-state equilibrium (308 l, SD 91; and 224 l, SD 59) with either body weight or estimated lean tissue mass. Slow half-life was 289 min (SD 169) in Phase 1 and 253 min (SD 172) in Phase 2. Moderately heavy sedation associated with amnesia while retaining the ability to readily obey verbal commands was achieved in one subject of Phase 1 and 4 subjects of Phase 2 and occurred at a mean chlormethiazole ethanedisulphonate blood concentration of 9.2 mg · l^–1 (SD 2.9). Transient nasal irritation was experienced by all subjects during the initial stages of infusion. A rise in pulse rate (33%, SD 8) was a prominent feature but blood pressure and respiratory rates were very stable.     

Antipyrine and lidocaine are cleared faster in horses than in humans: acetaminophen may be handled similarly

The following studies were designed to evaluate plasma elimination kinetics of intravenously administered antipyrine, acetaminophen and lidocaine among 9 healthy adult horses and 9 healthy drug-free humans (3 each per drug group), in order to compare potential species differences in drug-metabolizing ability. Acetaminophen is largely biotransformed in humans by hepatic glucuronide and sulfate conjugation, whereas both antipyrine and lidocaine are oxidized by hepatic microsomal mixed-function oxidases. Thus, plasma clearances of these drugs are thought to reflect differences in hepatic oxidative and conjugative activity, and possibly hepatic blood flow in the case of lidocaine. Results showed that mean (+/- SD, n = 3) acetaminophen clearance was similar in both horses (4.84 +/- 0.637 ml/min/kg) and humans (4.68 +/- 0.691 ml/min/kg). However, antipyrine clearance was 10 times greater in horses (5.83 +/- 2.21 ml/min/kg) than in humans (0.536 +/- 0.110 ml/min/kg), which may reflect enhanced hepatic microsomal activity in horses. Although lidocaine clearance in humans was similar to estimated hepatic blood flow (20.6 +/- 5.81 ml/min/kg), clearance in horses was more than 2 times greater (52.0 +/- 11.7 ml/min/kg). The cause of the higher clearance of lidocaine in horses (like dogs) remains unexplained, and may involve significant metabolism of lidocaine at extrahepatic, extravascular sites, for intravascular degradation and renal excretion of intact lidocaine in horses was negligible. Although precise biochemical mechanisms underlying pharmacokinetic parameters for these drugs in horses were not determined, it is nonetheless concluded from antipyrine results that horses may have an enhanced ability (compared with humans) to clear drugs from the circulation that are primarily metabolized in the liver by phase I oxidative reactions.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of ranitidine on the plasma clearance and hepatic extraction of indocyanine green in patients with chronic liver disease.

Since hepatic clearance of ICG is reduced by H2-receptor antagonists in normal subjects, it has been suggested that they reduce liver blood flow. We have studied the effect of intravenous ranitidine on ICG clearance in twelve patients with chronic liver disease. Wedged and free hepatic venous pressure were measured before and after intravenous ranitidine in nine of the patients, and the hepatic extraction of ICG was determined in six patients. ICG clearance fell by 22 +/- 11% (s.e. mean) 60 min after ranitidine. In patients in whom ICG clearance fell after intravenous ranitidine the hepatic extraction of ICG was also reduced. There was no significant change in the gradient between wedged and free hepatic venous pressure after ranitidine. It is therefore unlikely that ranitidine lowers liver blood flow.     

Plasma naltrexone kinetics after intravenous bolus administration in dogs and monkeys.

This investigation generated data characterize a specific electron-capture GLC assay reported previously for naltrexone and applied the method to a determination of naltrexone pharmacokinetics. Extraction efficiencies are reported for the assay, and mass spectral evidence indicates that naltrexone forms a triester when derivatized for electron-capture GLC with pentafluoropropionic anhydride and a base catalyst. Plasma level-time data for intravenous naltrexone at two dose levels in monkeys yielded no evidence of dose-dependent kinetics. A two-compartment open pharmacokinetic model was fitted to plasma level-time data for naltrexone in two dogs and yielded a total body clearance of 51-55 ml/min/kg. Urine collected for 0-24 hr contained 36% of the dose as naltrexone conjugates with less than 1% as unchanged naltrexone. Plasma level-time data for intravenous naltrexone in six monkeys yielded an average terminal half-life of 7.8 hr and a total body clearance of 64 ml/min/kg. The total body clearance for naltrexone was greater than the hepatic plasma or blood flow in both dogs and monkeys. This finding, together with the extremely low renal excretion of naltrexone, suggests the existence of elimination mechanisms besides liver metabolism and renal excretion.     

Pharmacokinetics of the new benzodiazepine antagonist Ro 15-1788 in man following intravenous and oral administration.

During clinical pharmacology studies with the benzodiazepine antagonist Ro 15-1788 the pharmacokinetic characteristics of high intravenous doses (20 and 40 mg) and of an oral dose (200 mg) were examined in six healthy male volunteers. Ro 15-1788 was rapidly and extensively distributed in the body with an apparent volume of distribution Vss of 1.06 l kg-1. Elimination occurred rapidly by hepatic metabolism and the high plasma clearance of 1.14 l min-1 resulted in a short elimination half-life of less than 1 h. No difference in the disposition parameters calculated from the data after the 20 and 40 mg doses was observed reflecting a dose-proportionality in the areas under plasma concentration-time curves and unchanged distribution characteristics. Because the blood/plasma distribution coefficient is close to unity the disposition parameters obtained from plasma concentrations are similar to the corresponding parameters with reference to blood. Following oral administration of 200 mg the drug is rapidly absorbed. Peak levels were reached after 20-90 min and were close to or even higher than the values after the 40 mg intravenous dose at the same time point. Due to the high hepatic extraction ratio the fraction reaching the systemic circulation unchanged was reduced to approximately 16% during the absorption step.     

Influence of Different Fat Emulsion-Based Intravenous Formulations on the Pharmacokinetics and Pharmacodynamics of Propofol

Purpose. The influence of different intravenous formulations on the pharmacokinetics and pharmacodynamics of propofol was investigated using the effect on the EEG (11.5-30 Hz) as pharmacodynamic endpoint. Methods. Propofol was administered as an intravenous bolus infusion (30 mg/kg in 5 min) or as a continuous infusion (150 mg/kg in 5 hours) in chronically instrumented male rats. Propofol was formulated as a 1% emulsion in an Intralipid 10%^®-like fat emulsion (Diprivan-10^®, D) or as a 1%- or 6% emulsion in Lipofundin^® MCT/LCT-10% (Pl% and P6%, respectively). EEG was recorded continuously and arterial blood samples were collected serially for the determination of propofol concentrations using HPLC. Results. Following bolus infusion, the pharmacokinetics of the various propofol emulsions could adequately be described by a two-compart-mental pharmacokinetic model. The average values for clearance (Cl), volume of distribution at steady-state (V_d,ss) and terminal half-life (t_{1/2, 2}) were 107 ± 4 ml/min/kg, 1.38 ± 0.06 l/kg and 16 ± 1 min, respectively (mean ± S.E., n = 22). No significant differences were observed between the three propofol formulations. After continuous infusion these values were 112 ± 11 ml/min/kg, 5.19 ± 0.41 l/kg and 45 ± 3 min, respectively (mean±S.E., n = 20) with again no statistically significant differences between the three propofol formulations. Comparison between the bolus- and the continuous infusion revealed a statistically significant difference for both V_d,ss and t_{1/2, 2} (p < 0.05), whereas Cl remained unchanged. In all treatment groups infusion of propofol resulted in a burst-suppression type of EEG. A profound hysteresis loop was observed between blood concentrations and EEG effect for all formulations. The hysteresis was minimized by a semi-parametric method and resulted in a biphasic concentration-effect relationship of propofol that was described non-parametrically. For P6% a larger rate constant onset of drug effect (t,_{1/2, keo}) was observed compared to the other propofol formulations (p<0.05). Conclusions. The pharmacokinetics and pharmacodynamics of propofol are not affected by to a large extent the type of emulsion nor by the concentration of propofol in the intravenous formulation.     

Race but not age affects erythromycin breath test results in older hypertensive men

Erythromycin breath tests (ERBT) were performed to determine age and racial effects on CYP3A4-mediated hepatic clearance in hypertensive men (n = 43) in the clinical setting. Older hypertensive African American men (n = 19: 71 +/- 8 years, mean +/- SD) had faster ERBT clearance compared with Caucasian (n = 20: 72 +/- 6 years) hypertensive men (at 20 minutes after dosing: 0.042 +/- 0.01 percent dose/min exhaled vs. 0.033 +/- 0.013; at 60 minutes after dosing: 0.030 +/- 0.05 vs. 0.023 +/- 0.007 percent dose/min exhaled; ANOVA, p = 0.007), while age, smoking, and reported alcohol intake did not affect ERBT. The data suggest faster hepatic CYP3A-mediated clearance in African American men compared with Caucasian men, and that race may significantly affect CYP3A-mediated hepatic clearance in patients treated for hypertension.     

Hepatic Blood Flow Measurements and Indocyanine Green Kinetics in a Chronic Dog Model

The objective of this study was to compare hepatic blood flow measurements using ultrasonic flow probes and ICG in a conscious dog model and to evaluate whether ICG can be used to estimate relative change in hepatic blood flow. Seven mongrel dogs (3 M, 4 F, BW = 21 ± 1.8 kg, Hct = 0.39 ± 0.05) were used in the study. Catheters were surgically inserted into carotid artery and portal, hepatic and jugular vein. Transit-time ultrasonic flow probes were implanted around the portal vein and hepatic artery. After two weeks of recovery, a single i.v. bolus dose of ICG (0.5 mg/kg) was administered to each dog. The disposition profiles for ICG in the four catheters were measured for 15 minutes and the hepatic blood flow reading from the probes recorded. Jugular vein ICG blood clearance (Cl = 5.9 ± 1.1 ml/min/kg) was low compared to the electronically measured hepatic blood flow rate (Q = 27.8 ± 9.1 ml/min/kg). Extraction ratios (E = 0.15 ± 0.05) estimated using data from the inlet and the outlet of the liver were consistent with the clearance values, suggesting that ICG is not highly extracted by dog livers. Three dogs were used in experiments where liver blood flow was increased by food intake. Consistent with characteristics of low extraction ratio drugs, ICG was insensitive to blood flow changes while there was an overall increase in electronically measured liver blood flow of 30%. Therefore, ICG is a poor indicator of hepatic blood flow and the present dog model permits continuous and reliable measurements of hepatic blood flow and can be a useful tool in studying the effects of hepatic hemodynamics on pharmacokinetics.     

Influence of the rate of hepatic portal vein infusion on hexobarbital pharmacokinetics in the rat

Pharmacokinetic parameters of hexobarbital were estimated in rats after hepatic portal infusion of a 10-mg dose. Infusion during 10 min resulted in an area under the blood concentration-time curve (AUC) of 556 +/- 83 micrograms.min/ml and a clearance of 83 +/- 13 ml/min.kg, whereas infusion of the same dose during 40 min resulted in values of 272 +/- 36 micrograms.min/ml and 169 +/- 30 ml/min.kg, respectively (mean values +/- SD, n = 3). Infusion during 15 and 20 min provided intermediate values. The decrease of the AUC and the increase of the blood clearance of hexobarbital following decreasing infusion rates clearly indicate nonlinear pharmacokinetics related to the hepatic inflow concentration of hexobarbital.     

Pharmacokinetics and effects of propofol 6% for short-term sedation in paediatric patients following cardiac surgery

AIMS: This paper describes the pharmacokinetics and effects of propofol in short-term sedated paediatric patients. METHODS: Six mechanically ventilated children aged 1-5 years received a 6 h continuous infusion of propofol 6% at the rate of 2 or 3 mg kg-1 h-1 for sedation following cardiac surgery. A total of seven arterial blood samples was collected at various time points during and after the infusion in each patient. Pharmacokinetic modelling was performed using NONMEM. Effects were assessed on the basis of the Ramsay sedation score as well as a subjective sedation scale. RESULTS: The data were best described by a two-compartment pharmacokinetic model. In the model, body weight was a significant covariate for clearance. Pharmacokinetic parameters in the weight-proportional model were clearance (CL) = 35 ml kg-1 min-1, volume of central compartment (V1) = 12 l, intercompartmental clearance (Q) = 0.35 l min-1 and volume of peripheral compartment (V2) = 24 l. The interindividual variabilities for these parameters were 8%, < 1%, 11% and 35%, respectively. Compared with the population pharmacokinetics in adults following cardiac surgery and when normalized for body weight, statistically significant differences were observed the parameters CL and V1 (35 vs 29 ml kg-1 min-1 and 0.78 vs 0.26 l kg-1P < 0.05), whereas the values for Q and V2 were similar (23 vs 18 ml kg-1 min-1 and 1.6 vs 1.8 l kg-1, P > 0.05). In children, the percentage of adequately sedated patients was similar compared with adults (50% vs 67%) despite considerably higher propofol concentrations (1.3 +/- 0.10 vs 0.51 +/- 0.035 mg l-1, mean +/- s.e. mean), suggesting a lower pharmacodynamic sensitivity to propofol in children. CONCLUSIONS: In children aged 1-5 years, a pharmacokinetic model for propofol was described using sparse data. In contrast to adults, body weight was a significant covariate for clearance in children. The model may serve as a useful basis to study the role of covariates in the pharmacokinetics and pharmacodynamics of propofol in paediatric patients of different ages.     

Propofol hydroxylation by dog liver microsomes: assay development and dog breed differences.

Pharmacokinetic studies indicate that clearance of propofol, an anesthetic agent, is slower in greyhounds compared with other dog breeds. Biotransformation of propofol to 2,6-diisopropyl-1,4-quinol (4-hydroxypropofol) by cytochrome P-450 in the liver is proposed as a critical initial step in the elimination of this drug in dogs. Breed differences in the activity of this enzyme could therefore explain pharmacokinetic differences. An in vitro propofol hydroxylase assay was developed and then used to compare enzyme activities in liver microsomes from male greyhound, beagle, and mixed-breed dogs (five each). HPLC of incubate identified only one NADPH-dependent metabolite, which had a chromatographic retention time and UV absorbance, fluorescence, and mass spectra that were identical with authentic 4-hydroxypropofol standard. HPLC with fluorescence detection provided a highly sensitive quantitation method for 4-hydroxypropofol with a quantitation limit of 8 ng/ml using optimized excitation/emission wavelengths (288 nm/330 nm, respectively). Estimates of apparent K(m) and V(max) for propofol hydroxylation by microsomes from a male beagle dog were 7.3 microM and 3.8 nmol/mg/min, respectively. At a substrate concentration of 20 microM, propofol hydroxylase activity was significantly lower (p =.032) in greyhound microsomes (1.7 +/- 0.4 nmol/mg/min) compared with beagle microsomes (5.1 +/- 1.3 nmol/mg/min) but was not statistically different (p =.42) compared with mixed-breed microsomes (3.1 +/- 1.2 nmol/mg/min). These results indicate that there are breed differences in propofol hydroxylase activity and that deficient hydroxylation of propofol by one or more hepatic cytochrome P-450 isoforms may contribute to slow pharmacokinetic clearance of propofol by greyhounds.