B. Oosterhuis

Use of microdosing to predict pharmacokinetics at the therapeutic dose: Experience with 5 drugs

A volunteer trial was performed to compare the pharmacokinetics of 5 drugs—warfarin, ZK253 (Schering), diazepam, midazolam, and erythromycin—when administered at a microdose or pharmacologic dose. Each compound was chosen to represent a situation in which prediction of pharmacokinetics from either animal or in vitro studies (or both) was or is likely to be problematic.

Pharmacokinetics of fexofenadine: Evaluation of a microdose and assessment of absolute oral bioavailability

A human pharmacokinetic study was performed to assess the ability of a microdose to predict the pharmacokinetics of a therapeutic dose of fexofenadine and to determine its absolute oral bioavailability. Fexofenadine was chosen to represent an unmetabolized transporter substrate (P-gP and OATP). Fexofenadine was administered to 6 healthy male volunteers in a three way cross-over design. A microdose (100microg) of (14)C-drug was administered orally (period 1) and intravenously by 30min infusion (period 2). In period 3 an intravenous tracer dose (100microg) of (14)C-drug was administered simultaneously with an oral unlabelled therapeutic dose (120mg). Plasma was collected from all 3 periods and analysed for both total (14)C content and parent drug by accelerator mass spectrometry (AMS). For period 3, plasma samples were also analysed using HPLC-fluorescence to determine total drug concentration. Urine was collected and analysed for total (14)C. Good concordance between the microdose and therapeutic dose pharmacokinetics was observed. Microdose: CL 13L/h, CL(R) 4.1L/h, V(ss) 54L, t(1/2) 16h; therapeutic dose: CL 16L/h, CL(R) 6.2L/h, V(ss) 64L, t(1/2) 12h. The absolute oral bioavailability of fexofenadine was 0.35 (microdose 0.41, therapeutic dose 0.30). Despite a 1200-fold difference in dose of fexofenadine, the microdose predicted well the pharmacokinetic parameters following a therapeutic dose for this transporter dependent compound.

A pharmacokinetic evaluation of five H1 antagonists after an oral and intravenous microdose to human subjects

AIMS To evaluate the pharmacokinetics (PK) of five H(1) receptor antagonists in human volunteers after a single oral and intravenous (i.v.) microdose (0.1 mg). METHODS Five H(1) receptor antagonists, namely NBI-1, NBI-2, NBI-3, NBI-4 and diphenhydramine, were administered to human volunteers as a single 0.1-mg oral and i.v. dose. Blood samples were collected up to 48 h, and the parent compound in the plasma extract was quantified by high-performance liquid chromatography and accelerator mass spectroscopy. RESULTS The median clearance (CL), apparent volume of distribution (V(d)) and apparent terminal elimination half-life (t(1/2)) of diphenhydramine after an i.v. microdose were 24.7 l h(-1), 302 l and 9.3 h, and the oral C(max) and AUC(0-infinity) were 0.195 ng ml(-1) and 1.52 ng h ml(-1), respectively. These data were consistent with previously published diphenhydramine data at 500 times the microdose. The rank order of oral bioavailability of the five compounds was as follows: NBI-2 > NBI-1 > NBI-3 > diphenhydramine > NBI-4, whereas the rank order for CL was NBI-4 > diphenhydramine > NBI-1 > NBI-3 > NBI-2. CONCLUSIONS Human microdosing provided estimates of clinical PK of four structurally related compounds, which were deemed useful for compound selection.

Comparative pharmacokinetics between a microdose and therapeutic dose for clarithromycin, sumatriptan, propafenone, paracetamol (acetaminophen), and phenobarbital in human volunteers

A clinical study was conducted to assess the ability of a microdose (100 μg) to predict the human pharmacokinetics (PK) following a therapeutic dose of clarithromycin, sumatriptan, propafenone, paracetamol (acetaminophen) and phenobarbital, both within the study and by reference to the existing literature on these compounds and to explore the source of any nonlinearity if seen. For each drug, 6 healthy male volunteers were dosed with 100 μg (14)C-labelled compound. For clarithromycin, sumatriptan, and propafenone this labelled dose was administered alone, i.e. as a microdose, orally and intravenously (iv) and as an iv tracer dose concomitantly with an oral non-labelled therapeutic dose, in a 3-way cross over design. The oral therapeutic doses were 250, 50, and 150 mg, respectively. Paracetamol was given as the labelled microdose orally and iv using a 2-way cross over design, whereas phenobarbital was given only as the microdose orally. Plasma concentrations of total (14)C and parent drug were measured using accelerator mass spectrometry (AMS) or HPLC followed by AMS. Plasma concentrations following non-(14)C-labelled oral therapeutic doses were measured using either HPLC-electrochemical detection (clarithromycin) or HPLC-UV (sumatriptan, propafenone). For all five drugs an oral microdose predicted reasonably well the PK, including the shape of the plasma profile, following an oral therapeutic dose. For clarithromycin, sumatriptan, and propafenone, one parameter, oral bioavailability, was marginally outside of the normally acceptable 2-fold prediction interval around the mean therapeutic dose value. For clarithromycin, sumatriptan and propafenone, data obtained from an oral and iv microdose were compared within the same cohort of subjects used in the study, as well as those reported in the literature. For paracetamol (oral and iv) and phenobarbital (oral), microdose data were compared with those reported in the literature only. Where 100 μg iv (14)C-doses were given alone and with an oral non-labelled therapeutic dose, excellent accord between the PK parameters was observed indicating that the disposition kinetics of the drugs tested were unaffected by the presence of therapeutic concentrations. This observation implies that any deviation from linearity following the oral therapeutic doses occurs during the absorption process.

Beta-2-adrenoceptor—mediated hypokalemia and its abolishment by oxprenolol

The time course and concentration‐effect relationship of terbutaline‐induced hypokalemia was studied, using computer‐aided pharmacokinetic‐dynamic modeling. Subsequently we investigated the efficacy of oxprenolol in antagonizing such hypokalemia, together with the pharmacokinetic interaction between both drugs. Six healthy subjects were given a 0.5 mg subcutaneous dose of terbutaline on two occasions: 1 hour after oral administration of a placebo and 1 hour after 80 mg oxprenolol orally. In the 7‐hour period after terbutaline administration, plasma samples were taken for determination of plasma potassium levels and drug concentrations. The sigmoid Emax model offered a good description of the relation between terbutaline concentrations and potassium effects. Oxprenolol caused decreases of 65% and 56% of terbutaline volume of distribution and clearance, respectively, and an increase of 130% of its AUC. In spite of higher terbutaline concentrations after oxprenolol pretreatment, the hypokalemia was almost completely antagonized by the β2‐blocking action.

Determination of salbutamol in human plasma with bimodal high-performance liquid chromatography and a rotated disc amperometric detector.

The sensitivity of electrochemical detection was combined with the selectivity of a bimodal high-performance liquid chromatographic system for the successful determination of salbutamol in human plasma. Following initial sample clean-up using Sep-Pak cartridges, analytes were passed first through a cation-exchange column, and then, after column switching, through a reversed-phase column. An amperometric detector with a rotated disc working electrode was used for detection. The detection limit was 0.5 ng/ml when 1.0 ml of plasma was used. The coefficient of variation was 9.8% at an average concentration of 4.7 ng/ml. The method was adequate for pharmacokinetic studies and for clinical applications.

Determination of the Bioavailability of [14C]‐Hexaminolevulinate Using Accelerator Mass Spectrometry After Intravesical Administration to Human Volunteers

Hexaminolevulinate (HAL) is a diagnostic agent that allows the visualization of tumor tissue in the bladder by fluorescence cystoscopy. It is administered intravesically via a catheter for 1 hour, followed by blue light bladder inspection to induce selective red tumor fluorescence. Hexaminolevulinate should ideally be confined to the bladder only, but it is likely that some absorption occurs during administration, and therefore the systemic bioavailability is of interest. The bioavailability of HAL was determined by intravesical and intravenous administration of [14C]‐HAL hydrochloride to 8 human volunteers. To reduce the radiation dose as low as possible, the ultrasensitive analytical technique of accelerator mass spectrometry was used to measure [14C]‐HAL. The bioavailability of [14C]‐HAL after intravesical and intravenous administration was determined from the respective area under the curve based on total radioactivity and was determined to be 7% (range, 5%–10%; 90% confidence interval). The systemic absorption of [14C]‐HAL after intravesical administration is low and supports previous clinical experience with HAL showing no systemic side effects.

The effect of oxprenolol dosage time on its pharmacokinetics and haemodynamic effects during exercise in man.

SummaryWe have studied the effect of dosage time of oxprenolol (Trasicor®) on its pharmacokinetics and pharmacodynamics in six healthy volunteers. The drug effects measured were heart rate and systolic blood pressure during exercise. Oxprenolol was taken orally at 08.00 h, 14.00 h, 20.00 h, and 02.00 h in randomized order, with 1 week between successive doses.There were differences in the pharmacokinetics of oxprenolol for the ratio between the apparent volume of distribution and systemic availability (P=0.04) and for elimination half-life (P=0.006). Both were lowest after administration at 14.00 h (163 (77) l and 1.2 (0.6) h; mean (SD)) and highest after administration at 02.00 h (229 (100) l, and 1.7 (0.6) h).The systolic blood pressure during exercise before oxprenolol did not vary with dosage time, but heart rate during exercise before intake was lowest before dosage time 08.00 h and highest before dosage time 20.00 h (P=0.03).The time-course of heart rate during exercise after oxprenolol was described by a model that incorporated the factors drug concentration and spontaneous diurnal variation. EC50 and Emax did not vary between dosage times. The spontaneous diurnal variation in heart rate during exercise was unaffected by oxprenolol, leading to an apparently greater effect of oxprenolol during the night than during the day.

Pharmacokinetic‐pharmacodynamic modeling of terbutaline bronchodilation in asthma

The study of terbutaline pharmacodynamics in patients with asthma is hampered by interfering stimuli when steady‐state methods are employed. With pharmacokinetic‐dynamic modeling, many of these interferences can be avoided. Using this technique, we studied the effect of terbutaline on lung function in 10 asthmatic patients with >15% lung function reversibility. Terbutaline plasma concentrations, forced expiratory volume in 1 second (FEV1) airway resistance (Raw), and specific airway conductance (sGaw) were measured before and during 7 hours after subcutaneous dosing with 469.75 mg terbutaline. A hyperbolic concentration‐effect relation was found. Fitting the time course of the effects required an effect compartment in the integrated model. Thus the delay between plasma concentration and effect time course was characterized by the rate constant keO. Essentially the same keO was found for FEvl, Raw, and sGaw, indicating that the concerning receptors are “localized” in the same pharmacokinetic compartment. Of the lung function measures, sGaw was less sensitive to terbutaline than Raw and FEVl, whereas the latter tended to be the most sensitive one.

Liquid chromatography with electrochemical detection for monitoring mebendazole and hydroxymebendazole in echinococcosis patients

Summary A sensitive method is described for the simultaneous determination of mebendazole and hydroxymebendazole using flubendazole as an internal standard. The analytes were isolated with a single chloroform extraction from 1.0 ml of alkalinized plasma or cyst liquid samples. Separation and quantitation were performed with high-performance liquid chromatography with electro-chemical detection. The limit of detection for mebendazole and hydroxymebendazole was ∼5 and 2.5 ng/ml, respectively. The accuracy of the method was confirmed for mebendazole by a good correlation with an existing radioimmunoassay method. The method was applied for monitoring mebendazole therapy in echinococcosis patients. The results presented support the necessity of such monitoring, as most of the observed peak plasma concentrations did not reach the level regarded as minimal for therapeutic effect.