The pharmacokinetics of remifentanil in patients undergoing coronary artery bypass grafting with cardiopulmonary bypass

Remifentanil is a potent opioid with a short duration of action. It has the potential for large-dose opioid anesthesia without an obligatory prolonged period of mechanical ventilation. However, because of high clearance and rapid tissue distribution, cardiopulmonary bypass (CPB) may influence its pharmacokinetics and alter drug requirements. We administered remifentanil by continuous infusion to 68 patients having coronary artery bypass graft surgery during CPB with hypothermia to describe the effects of these interventions on its pharmacokinetics. Remifentanil concentrations were measured before, during, and after CPB. Disposition was best described by a two-compartment model. The volume of distribution increased by 86% with institution of CPB and remained increased after CPB. Elimination clearance decreased by 6.37% for each degree Celsius decrease from 37 degrees C.

IMPLICATIONS

Remifentanil concentrations decrease with the institution of cardiopulmonary bypass because of an increase in the volume of distribution. The decrease in elimination clearance with hypothermia results in increased total remifentanil concentrations during cardiopulmonary bypass if the infusion rate is not altered. More constant blood remifentanil levels may be obtained by reducing remifentanil infusion rate by 30% for each 5 degrees C decrease in temperature.

Pharmacokinetics of a glycine site antagonist (gavestinel) following multiple dosing in patients with acute stroke

OBJECTIVE

The objective of this study was to characterize the pharmacokinetics of gavestinel in patients with acute stroke.

METHODS

Gavestinel was administered as an 800-mg loading dose and followed by either 100-, 200-, or 400-mg maintenance doses given every 12 h for five doses. Blood and urine samples were collected for pharmacokinetic evaluation. The pharmacokinetics of gavestinel were determined using compartmental analysis.

RESULTS

The mean clearance (CL) and central (Vc) and steady-state (Vss) volumes of distribution across the dose groups were 0.31-0.40 l x h(-1), 3.3-3.9 l, and 9.8-17 l, respectively. The mean terminal half-life ranged from 29 h to 56 h. Gavestinel was extensively bound to plasma protein (median percentage free <0.01). During gavestinel administration, some patients exhibited elevated levels of bilirubin, which may be the result of shared mechanisms of elimination (glucuronide conjugation and excretion in bile).

CONCLUSIONS

This study characterized the pharmacokinetics of gavestinel following multiple doses in acute stroke patients and showed that the pharmacokinetics are similar for increasing maintenance doses. The high protein binding of gavestinel was confirmed in acute stroke patients. A pharmacokinetic interaction between gavestinel and bilirubin may contribute to the increase in bilirubin.

First time in human for GV196771: interspecies scaling applied on dose selection

The utility of interspecies scaling in early drug development has been extensively debated. The authors discuss the dose selection strategy for a first time into man (FTIM) study for GV196771, a new glycine antagonist, using techniques of interspecies scaling. The FTIM dose selection strategy was based on predicted plasma profiles of GV196771 in humans using allometric scaling and considerations of safety and pharmacological activity in animals. Allometric techniques were first retrospectively applied to data obtained in humans and animals for GV150526, a glycine antagonist with similar pharmacokinetic characteristics to GV196771. GV196771 and GV150526 are extensively protein bound; thus, protein binding differences among species were considered in the scaling. Using the scaled pharmacokinetic parameters, compartmental modeling was performed to prospectively simulate concentration profiles for the oral administration of GV196771. This article will discuss the outcome of the prospective dose selection strategy for GV196771 compared to the actual concentration profiles observed in the FTIM study.

The pharmacokinetics and electroencephalogram response of remifentanil alone and in combination with esmolol in the rat

PURPOSE

The goal of this study was to determine if the co-administration of esmolol (ES), a short acting cardioselective beta-blocker, significantly alters the pharmacokinetics and/or pharmacodynamics of remifentanil (REMI), an ultra short-acting opioid, in the rat.

METHODS

Sprague-Dawley rats (N = 8, Wt. = 325 +/- 15 g) were surgically implanted with stainless steel cerebrocortical EEG electrodes three days before the study. Each rat was dosed with REMI (15 micrograms/kg/min), and REMI & ES (15 micrograms/kg/min and 600 micrograms/kg/min) for 21 minutes in a random crossover design. Six serial blood samples were collected over 25 minutes into test-tubes containing 0.5 ml acetonitrile. Blood samples were extracted with methylene chloride and analyzed by a validated GC-MS assay. EEG was captured and subjected to power spectral analysis (0.1-50 Hz) for spectral edge (97%).

RESULTS

No significant differences (p < 0.05) were found in clearance (REMI = 287 + 73 ml/min/leg vs. REMI & ES = 289 +/- 148 ml/min kg) or Vd (REMI = 286 +/- 49 ml/kg vs REMI & ES = 248 + 40 ml/kg). A linked sigmoid Emax PK-PD model was used and the pharmacodynamic parameters were not statistically different. Mean Emax and EC50 after REMI were 18.0 +/- 6.0 Hz and 32 +/- 12 ng/ml; and after REMI + ES were 19 + 4.8 Hz and 26 + 8.6 ng/ml.

CONCLUSIONS

At the doses tested, there is no pharmacokinetic or pharmacodynamic interaction between remifentanil and esmolol in the rat.

Evaluating a possible pharmacokinetic interaction between remifentanil and esmolol in the rat

Remifentanil (Ultiva) is a novel, ultra-short-acting opioid which has recently been approved for use as an analgesic during induction and maintenance of general anesthesia. Esmolol is a short-acting beta-blocker used during surgical procedures to reduce heart rate and blood pressure. Both drugs are metabolized by nonspecific esterases in the blood and other tissues and may be administered concomitantly during surgery. The goal of this study was to determine if coadministration of esmolol significantly alters the pharmacokinetics of remifentanil in the rat. Two groups of rats were dosed with remifentanil [25 micrograms/kg/min (n = 8)] and remifentanil plus esmolol [25 and 200 mg/kg/min (n = 7)] for 20 min. Cardiovascular measurements were collected continuously over the course of the study. Serial blood samples (12) were collected over 25 min into test tubes containing 0.5 mL of acetonitrile. Blood samples were extracted (liquid-liquid) with methylene chloride and then analyzed by a validated GC-MS assay. Compartmental data analysis was performed using PCNONLIN. The mean(+/- SD) for Cl and t1/2 observed in treatment I were 390(+/- 98) mL/min/kg and 0.69(+/- 0.27) min and in treatment II were 421(+/- 164) mL/min/kg and 0.56(+/- 0.22) min, respectively. Comparison of clearance, volume of distribution, and terminal half-life between the two groups showed that coadministration of esmolol had no significant (p < 0.05) effect on the pharmacokinetics of remifentanil in the rat.

Pharmacokinetics and pharmacodynamics of remifentanil in persons with renal failure compared with healthy volunteers

BACKGROUND

Remifentanil is an opioid analgesic for use in anesthesia. An ester linkage renders it susceptible to rapid metabolism by blood and tissue esterases. Thus it was hypothesized that remifentanil elimination would be independent of renal function. Because its principal metabolite (GR90291) is eliminated renally, it would depend on renal function. This study was designed to evaluate the pharmacokinetics and pharmacodynamics of remifentanil and its metabolite in persons with and without renal failure.

METHODS

Two groups of volunteers received two-stage infusions of remifentanil: low dose with 0.0125 microg x kg(-1) x min(-1) for 1 h followed by 0.025 microg x kg(-1) x min(-1) for 3 h; and high dose with 0.025 microg x kg(-1) x min(-1) for 1 h followed by 0.05 microg x kg(-1) x min(-1) for 3 h. Blood samples were collected for analysis of remifentanil and GR90291 concentrations. The pharmacokinetics of remifentanil were fit using a one-compartment pharmacokinetic model. Remifentanil's effect was determined intermittently using minute ventilation during a hypercapnic (7.5% CO2) challenge.

RESULTS

Fifteen patients with renal failure and eight control participants were enrolled. The clearance and volume of distribution of remifentanil were not different between those with renal failure and the controls. Patients with renal failure showed a marked reduction in the elimination of GR90291; the half-life of the metabolite increased from 1.5 h in the controls to more than 26 h in patients with renal failure. The steady-state concentration of GR90291 is likely to be more than 25 times higher in persons with renal failure. There were no obvious differences in opioid effects on minute ventilation in the controls and in patients with renal failure.

CONCLUSIONS

The pharmacokinetics and pharmacodynamics of remifentanil were not altered in patients with renal disease, but the elimination of its principal metabolite, GR90291, was markedly reduced. Based on simulations, the concentration of GR90291 at the end of a 12-h remifentanil infusion of 2 microg x kg(-1) x min(-1) is not likely to produce significant opioid effects.

Comparative pharmacokinetics and pharmacodynamics of remifentanil, its principle metabolite (GR90291) and alfentanil in dogs

Remifentanil is an esterase-metabolized opioid developed for use in anesthesia. The principal metabolite of remifentanil, GR90291, is considered to be less potent. This study determined the relative potency of GR90291 and alfentanil, compared with remifentanil, in anesthetized dogs. Male dogs received thiamylal sodium, and anesthesia was maintained using isoflurane and N2O in oxygen. Each dog received a 5-min infusion of 0.5 microg/kg/min remifentanil, 500 microg/kg/min GR90291 and 1.6 mg/kg/min alfentanil in random order, separated by 1 week. Serial blood samples were collected during and after the infusion. The electroencephalogram was evaluated using aperiodic analysis. The pharmacokinetics and pharmacodynamics of remifentanil, GR90291 and alfentanil were determined using nonlinear least-squares regression analysis. Remifentanil was rapidly eliminated, with a terminal half-life of 6 min, compared with 19 min for GR90291 and alfentanil. Using the estimated concentration that elicits 50% of the maximum response (EC50) for delta EEG activity and spectral edge95, remifentanil was 4213 to 4637 times more potent than GR90291 and 7.7 to 8.5 times more potent than alfentanil. The blood-brain equilibration half-life was 2.3 to 5.2 min for remifentanil, 0.39 to 0.41 min for GR90291 and 3.1 to 3.7 min for alfentanil.

Influence of age and gender on the pharmacokinetics and pharmacodynamics of remifentanil. I. Model development

BACKGROUND

Previous studies have reported conflicting results concerning the influence of age and gender on the pharmacokinetics and pharmacodynamics of fentanyl, alfentanil, and sufentanil. The aim of this study was to determine the influence of age and gender on the pharmacokinetics and pharmacodynamics of the new short-acting opioid remifentanil.

METHODS

Sixty-five healthy adults (38 men and 27 women) ages 20 to 85 y received remifentanil by constant-rate infusion of 1 to 8 micrograms.kg-1.min-1 for 4 to 20 min. Frequent arterial blood samples were drawn and assayed for remifentanil concentration. The electroencephalogram was used as a measure of drug effect. Population pharmacokinetic and pharmacodynamic modeling was performed using the software package NONMEM. The influence of volunteer covariates were analyzed using a generalized additive model. The performances of the simple (without covariates) and complex (with covariates) models were evaluated prospectively in an additional 15 healthy participants ages 41 to 84 y.

RESULTS

The parameters for the simple three-compartment pharmacokinetic model were V1 = 4.98 l, V2 = 9.01 l, V3 = 6.54 l, Cl1 = 2.46 l/min, Cl2 = 1.69 l/min, and Cl3 = 0.065 l/min. Age and lean body mass were significant covariates. From the ages of 20 to 85 y, V1 and Cl1 decreased by approximately 25% and 33%, respectively. The parameters for the simple sigmoid Emax pharmacodynamic model were Ke0 = 0.516 min-1, E0 = 20 Hz, Emax = 5.62 Hz, EC50 = 11.2 ng/ml, and gamma = 2.51. Age was a significant covariate of EC50 and Ke0, with both decreasing by approximately 50% for the age range studied. The complex pharmacokinetic-pharmacodynamic model performed better than did the simple model when applied prospectively.

CONCLUSIONS

This study identified (1) an effect of age on the pharmacokinetics and pharmacodynamics of remifentanil; (2) an effect of lean body mass on the pharmacokinetic parameters; and (3) no influence of gender on any pharmacokinetic or pharmacodynamic parameter.

Reduction of isoflurane minimal alveolar concentration by remifentanil

BACKGROUND

Remifentanil is a new micro-specific opioid receptor agonist currently under investigation. The interaction between opioids and volatile anesthetics is complex. Defining this interaction provides a basis for more rational dosing schemes when such combinations are used for anesthesia and allows the anesthetic potency of remifentanil relative to other opioids to be determined.

METHODS

Two centers enrolled a total of 220 patients. Patients were randomized to receive a target concentration of remifentanil via a computer-assisted continuous infusion device of either 0.0, 0.5, 1.0, 1.5, 2.0, 4.0, 8.0, 16.0, and 32.0 ng/ml initiated before the administration of isoflurane. Patients were also stratified by groups 18-30, 31-55, and 56-65 yr. After induction of anesthesia with isoflurane the initial patient in each dose group was assigned an age-adjusted isoflurane concentration. The isoflurane concentration for each subsequent patient was adjusted according to the up/down technique until a minimum of 12 patients were enrolled in each group. Arterial blood samples for remifentanil whole blood concentrations were obtained. The patient was observed for purposeful movement for up to 1 min after skin incision. The minimum alveolar concentration (MAC) of isoflurane (0 ng/ml remifentanil group) and MAC reduction of isoflurane by remifentanil were determined.

RESULTS

The MAC of isoflurane alone was 1.3%. Remifentanil caused an exponential reduction in the MAC of isoflurane with 1.37 ng/ml remifentanil a 77% reduction and 32 ng/ml a 91% reduction of isoflurane MAC.

CONCLUSION

The MAC reduction of isoflurane by remifentanil is similar to that produced by other opioids. Although remifentanil was given at extremely high concentrations in the absence of isoflurane, it did not provide adequate anesthesia. A 50% isoflurane MAC reduction is produced by 1.37 ng/ml remifentanil whole blood concentration compared to previously published plasma concentrations of fentanyl of 1.67 ng/ml or sufentanil of 0.14 ng/ml.

Pharmacokinetics and pharmacodynamics of remifentanil in volunteer subjects with severe liver disease

BACKGROUND

Remifentanil, a new mu-opioid agonist with an extremely short duration of action, is metabolized by circulating and tissue esterases; therefore, its clearance should be relatively unaffected by changes in hepatic or renal function. This study was designed to determine whether severe hepatic disease affects the pharmacokinetics or pharmacodynamics of remifentanil.

METHODS

Ten volunteers with chronic, stable, severe hepatic disease and awaiting liver transplantation and ten matched controls were enrolled. Each subject was given a 4-h infusion of remifentanil. The first five pairs received 0.0125 microgram x kg(-1) x min(-1) for 1 h followed by 0.025 microgram x kg(-1) x min(-1) for 3 h; the second five pairs received double these infusion rates. During and after the infusion, arterial blood was obtained for pharmacokinetic analyses, and the ventilatory response to a hypercarbic challenge was assessed. Simultaneous pharmacokinetic and pharmacodynamic analyses were performed. The pharmacokinetics were described using a one-compartment intravenous infusion model, and ventilatory depression was modelled using the inhibitory E(max) model. The pharmacokinetics of the metabolite GR90291 were determined using noncompartmental methods.

RESULTS

There were no differences in any of the pharmacokinetic parameters for remifentanil or GR90291 between the two groups. The subjects with liver disease were more sensitive to the ventilatory depressant effects of remifentanil. The EC(50) values (the remifentanil concentrations determined from simultaneous pharmacokinetic/pharmacodynamic analyses to depress carbon dioxide-stimulated minute ventilation by 50%) in the control and hepatic disease groups were 2.52 ng/ml (95% confidence interval 2.07-2.97 ng/ml) and 1.56 ng/ml (95% confidence interval 1.37-1.76 ng/ml), respectively.

CONCLUSIONS

The pharmacokinetics of remifentanil and GR90291 are unchanged in persons with severe, chronic liver disease. Such patients may be more sensitive to the ventilatory depressant effects of remifentanil, a finding of uncertain clinical significance, considering the extremely short duration of action of the drug.

Histamine concentrations and hemodynamic responses after remifentanil

Remifentanil is a new potent opioid analgesic that undergoes rapid esterase metabolism. The purpose of this study was to investigate hemodynamic responses to 2-30 micrograms/kg remifentanil (escalating doses) injected as a bolus over 1 min during general anesthesia. After general anesthesia with endotracheal intubation, placement of a radial artery catheter, and pretreatment with glycopyrrolate, remifentanil 2, 5, 15, or 30 micrograms/kg (six patients, three male and three female per group) was administered over 1 min. Arterial blood pressure and heart rate were measured noninvasively before drug administration, after drug administration, and then every minute for 5 min. Arterial blood was taken for histamine determinations before drug administration and then at 1, 3, and 5 min after drug administration. Administration of remifentanil was associated with a reduction in systolic blood pressure from 134 +/- 18 to 91 +/- 16 mm Hg and heart rate from 99 +/- 20 to 69 +/- 21 bpm and was not associated with alterations in histamine concentration.

Pharmacokinetics of remifentanil (GI87084B) and its major metabolite (GI90291) in patients undergoing elective inpatient surgery

BACKGROUND

Remifentanil is a highly potent opioid with a rapid onset and a short duration of action due to its rapid hydrolysis by esterases in blood and tissues. The major metabolite of remifentanil, GI90291, is much less potent than remifentanil.

METHODS

The pharmacokinetics of remifentanil and its major metabolite, GI90291, were determined in 24 patients undergoing elective inpatient surgery. Remifentanil was administered as a 1-min infusion (2, 5, 15, and 30 micrograms/kg) after the induction of anesthesia and tracheal intubation. Serial arterial blood samples were collected over 6 h and assayed for remifentanil and GI90291.

RESULTS

The pharmacokinetics of remifentanil were described using a three-compartment model. Total clearance (250-300 l/h) of remifentanil was independent of dose and was approximately three to four times greater than the normal hepatic blood flow. Volume of distribution at steady state (25-40 l) also was independent of dose. The terminal half-life of remifentanil ranged from 10 to 21 min. Covariate analysis of remifentanil clearance and patient demographics showed that patient body weight, age, and gender did not influence total clearance. This suggests that remifentanil may not need to be dosed according to body weight in adult patients. A simulation was conducted to determine the time required for a 50% reduction in effect site concentration after an infusion designed to maintain a constant effect site concentration. The time required for a 50% reduction in the effect site concentration of remifentanil (3.65 min) was considerably less than that for sufentanil (33.9 min), alfentanil (58.5 min), and fentanyl (262 min). The pharmacokinetics of the major metabolite, GI90291, were independent of the dose of remifentanil. The mean terminal half-life of GI90291 ranged from 88 to 137 min.

CONCLUSIONS

The pharmacokinetics of remifentanil are consistent with its rapid elimination by blood and tissue esterases; its major metabolite is eliminated more slowly but is not likely to make any significant contribution to the total effect because of its much lower potency. The rapid onset and short duration of action of remifentanil make it well suited for titration of dose (infusion rate) to the desired degree of effect.

Pharmacokinetics and metabolism of vigabatrin following a single oral dose of [14C]vigabatrin in healthy male volunteers

14C-labeled vigabatrin (50 microCi), an antiepileptic drug, was administered to six healthy male volunteers as a single oral dose containing 1500 mg of vigabatrin to determine the disposition profile of 14C and parent drug, and to investigate the metabolism of vigabatrin in humans. Vigabatrin was well tolerated by all subjects. There were no clinically important changes in any clinical laboratory parameter. Plasma concentration profiles of both 14C and vigabatrin exhibited biexponential decay. AUC, Cmax, Tmax, and terminal phase t1/2, for 14C were consistently greater than vigabatrin (248.2 vs. 176.0 micrograms-hr/ml; 48.8 vs. 42.8 micrograms/ml; 0.7 vs. 0.6 hr; and 9.5 vs. 7.7 hr, respectively). Mean renal clearance, oral clearance, and volume of distribution for 14C was consistently lower than vigabatrin (1.20 vs. 1.45 ml/min/kg; 1.26 vs. 1.77 ml/min/kg; and 1.01 vs. 1.18 liters/kg, respectively). The mean percentage of recovery of 14C in urine was higher than vigabatrin (95.4 vs. 82.0%). The mean percentage of recovery of 14C in feces was 1.0%. Concentration ratios of 14C showed that vigabatrin distributes into red blood cells at a concentration of 30-80% of that in plasma. The concentration of vigabatrin in saliva was approximately 10% of that in the plasma. The main radioactive component eliminated in the urine was vigabatrin. Two minor urinary metabolites (< 5% of total dose) of vigabatrin were detected using liquid scintillation counting of HPLC eluant fractions. One urinary metabolite was identified by thermospray-LC/MS as the lactam metabolite of vigabatrin.

Pharmacokinetics of vigabatrin following single and multiple oral doses in normal volunteers

The pharmacokinetics of vigabatrin were investigated after single and multiple oral doses in two groups of 24 healthy male volunteers. Vigabatrin was well tolerated by the volunteers; headache was the most frequently reported adverse event. There were no clinically remarkable changes in serum chemistry, urinalysis, or hematology attributable to vigabatrin. For the single-dose study, a stepwise linear contrast method was used to assess dose proportionality. The results showed that vigabatrin exhibited dose linear pharmacokinetics after single oral doses ranging from 0.5 to 4.0 g. Slight changes in the terminal phase half-life and renal clearance were evident in the higher dosage groups. These changes with increasing dose of vigabatrin were relatively minor and not considered to be clinically important. Evaluation of the multiple-dose pharmacokinetics indicated that vigabatrin exhibited dose linearity over the range of 0.5 to 2.0 g administered every 12 hours. The terminal phase half-life and renal clearance of vigabatrin during multiple dosing were consistent with that after single doses. During multiple dosing, steady-state concentrations of vigabatrin were reached on the second day of dosing, and drug accumulation was minimal.

Physiological effects of a perfluorochemical blood substitute in beagle dogs

Perfluorochemical (PFC) emulsions have been examined for use as erythrocyte substitutes in the treatment of various disease states. The physiological changes induced by PFC infusion would be an important determinant of successful clinical therapy. Previous studies have reported PFC induced changes in the disposition of drugs. This report describes some physiological (hematology, cardiovascular, liver enzyme) changes resulting from a 30% blood exchange with a PFC emulsion in Beagle dogs. A 30% blood exchange with hydroxyethylstarch (HES) also was evaluated and compared to the PFC emulsion exchange. The blood pressure was markedly reduced shortly after PFC infusion while HES infusion produced only minor changes. Changes in the heart rate following blood replacement were similar for PFC and HES treated dogs. Hematology profiles also were similar for the PFC and HES treatment groups. The liver enzyme levels in PFC treated dogs showed marked elevations beginning shortly after PFC infusion and remained elevated for months after the initial PFC blood replacement. In contrast, HES treated dogs exhibited no observable changes in liver enzyme levels over the time course of the study.

Effect of a perfluorochemical erythrocyte substitute on the in vitro metabolism of lidocaine using rat liver slices

Perfluorochemical (PFC) emulsions have recently been investigated for use in the treatment of various clinical conditions requiring red blood cell replacement. The physiological changes which develop following PFC infusion may directly, or indirectly alter the disposition of concomitantly administered agents. This study examined the in vitro metabolism of lidocaine (LC) following pretreatment of rats with a PFC emulsion. Studies were conducted from 2 days to 6 months after initial blood replacement. The control treatment included rats that received a blood exchange with their own blood (SHAM). Analysis of LC and its metabolites was performed using solid phase extraction (SPE) and a modified high performance liquid chromatography (HPLC) method. The predominate metabolite observed in the liver slice preparation was monoethylglycinexylidide (MEGX). No glycinexylidide (GX) was noted in any of the treatments. The results indicate an increase in the in vitro rate of metabolism of LC in rats pretreated with the PFC emulsion. These effects appeared to be time-dependent with maximal increase in metabolism at approximately 5 weeks after the blood exchange and persisting for up to 6 months. These changes in the disappearance of LC in liver slice preparations may reflect PFC-induced enzyme induction and/or altered tissue uptake of LC.

Perfluorochemical erythrocyte substitutes: disposition and effects on drug distribution and elimination

As a result of their ability to transport oxygen, PFC emulsions are being investigated for possible use in a wide variety of conditions. The recent FDA approval of F-DA to diminish myocardial ischemia during angioplasty is the first marketing approval for such a product in the world. The many potential uses of such products may result in their common application in the future, especially as new and better products are developed. The elimination, distribution, and tissue retention of PFC emulsions as well as the physiological changes that occur upon their administration have been the subject of many investigations. The results indicate that these agents may influence the pharmacokinetic properties of other drugs by a wide variety of mechanisms. Several studies have shown significant, but not necessarily consistent, changes in drug elimination and distribution following PFC emulsion infusion. Changes appear dependent on the drug examined, emulsion utilized, degree of blood exchange, species utilized, and the controls chosen for comparison. Often, the changes are time dependent indicating the importance of conducting long-term studies. While PFC emulsions do not appear to alter renal elimination of drugs, several studies have demonstrated that these agents have the potential to induce drug metabolism from several days to possibly months after exposure. Observed changes in drug volumes of distribution, which are often time dependent, may be due to changes in normal drug transport throughout the circulation and/or changes in membrane permeability and cell transport mechanisms. Changes in drug transport may result from depletion of plasma proteins or increases in alpha 1-acid glycoprotein levels due to trauma or PFC emulsion effects. The binding of drugs by PFC emulsion droplets varies greatly and PFC emulsion components displace some plasma protein bound drugs. The wide variability in the results and conclusions of the pharmacokinetic studies conducted to date emphasize the importance of utilizing adequate controls to identify which alterations are PFC emulsion specific.

Liquid chromatographic determination of sulindac and metabolites in serum

An improved liquid chromatographic procedure is described for the quantitative determination of sulindac, sulindac sulfone, and sulindac sulfide from serum. The procedure makes use of acetonitrile extraction of the compounds of interest from acidified serum samples. Under these conditions extraction efficiencies in the 85 percent range are obtained for each of the compounds. The liquid chromatographic separation of the compounds of interest and the internal standard (indomethacin) is accomplished in an isocratic elution procedure using a nitrile (CN) stationary phase. The HPLC separation procedure is completed in less than 10 minutes, giving excellent resolution and peak shape.