Jarmo S. Salonen

Regio- and Stereospecific N-Glucuronidation of Medetomidine: The Differences between UDP Glucuronosyltransferase (UGT) 1A4 and UGT2B10 Account for the Complex Kinetics of Human Liver Microsomes

Medetomidine is a chiral imidazole derivate whose dextroenantiomer is pharmacologically active. The major metabolic pathway of dexmedetomidine [(+)-4-(S)-[1-(2,3-dimethylphenyl)ethyl]-1H-imidazole] in humans is N-glucuronidation at the imidazolate nitrogens. We have purified the N3- and N1-glucuronides of dexmedetomidine, termed DG1 and DG2, respectively, according to their elution order in liquid chromatography and determined their structure by 1H nuclear magnetic resonance (NMR). Studying medetomidine glucuronidation by human liver microsomes (HLMs) and recombinant UDP glucuronosyltransferase (UGT) 1A4 indicated that another human UGT plays a major role in these activities. We now demonstrate that this enzyme is UGT2B10. HLMs catalyzed DG1 and DG2 formation, at a ratio of 3:1, with two-enzyme kinetics that contain both a high-affinity component, Km1 values of 6.6 and 8.7 μM, and a low-affinity component, Km2 values > 1 mM. The DG1/DG2 ratio in the case of UGT2B10 was lower, 1.4:1, whereas the substrate affinity for both reactions was high, Km values of 11 and 16 μM. UGT1A4 produced mainly DG1 (DG1/DG2 ratio of 6.6:1) at low substrate affinities, Km values above 0.6 mM, but superior expression-normalized Vmax values. Levomedetomidine [(-)-4-(R)-[1-(2,3-dimethylphenyl)ethyl]-1H-imidazole] glucuronidation by HLMs yielded mostly the N3-glucuronide (LG1, structure determined by NMR), with monophasic kinetics and a Km value of 14 μM. The activity of UGT1A4 toward levomedetomide was low and generated both LG1 and LG2, whereas UGT2B10 exhibited relatively high activity and sharp regioselectivity, yielding only LG1, with a Km value of 7.4 μM. The results highlight the contribution of UGT2B10 to medetomidine glucuronidation and its potential importance for other N-glucuronidation reactions within the human liver.

Biotransformation of medetomidine in the rat

1. The metabolites of a novel alpha 2-adrenoceptor agonist, medetomidine, in rat urine after subcutaneous administration at two dose levels (80 micrograms/kg or 5 mg/kg), and after incubation with rat liver fractions, were characterized by h.p.l.c., 1H-n.m.r and mass spectrometry. 2. Hydroxylation of a methyl substituent was the main biotransformation in vitro. Hydroxylation occurred at a rate sufficient for high metabolic clearance. 3. The major urinary metabolites were the glucuronide of hydroxymedetomidine (about 35% of urinary metabolites) and medetomidine carboxylic acid (about 40%). 4. Medetomidine unchanged represented about 1% or 10% of the urinary excretion products, dependent on dose. 5. A metabolic pathway consisting of hydroxylation with subsequent glucuronidation, or further oxidation to carboxylic acid, is suggested.

COMPARISON OF THE EFFECTS OF ACUTE AND SUBCHRONIC ADMINISTRATION OF ATIPAMEZOLE ON REACTION TO NOVELTY AND ACTIVE AVOIDANCE LEARNING IN RATS

The effects of an α2-adrenoceptor antagonist, atipamezole, on exploratory behaviour in a novel environment, spontaneous motor activity and active avoidance learning were studied after acute injection and continuous infusion (0.1 mg/kg h) for 24 h and 6–9 days in rats. The effects of atipamezole on biogenic amines and their main metabolites in brain were studied after an acute injection (0.3 mg/kg s.c.) and continuous infusion (0.1 mg/kg h) for 24 h and 10 days. The level of central α2-adrenoceptor antagonism and the drug concentration in blood and in the brain were measured after continuous infusion for 24 h and 10 days. In behavioural tests, atipamezole had no effect on spontaneous motor activity at any of the doses studied. However, after both acute administration and continuous 24-h infusion, atipamezole decreased exploratory behaviour in a staircase test, but no longer after 6 days of continuous infusion. Acute administration of atipamezole impaired performance in active avoidance learning tests causing a learned helplessness-like behaviour. When the training was started after 7 days of continuous infusion, atipamezole significantly improved active avoidance learning. There was a significant increase in the metabolite of noradrenaline (NA), 3-methoxy-4-hydroxyphenylethyleneglycol sulphate (MHPG-SO4), after 24 h but not any longer after 10 days of continuous atipamezole infusion, although the extent of central α2-adrenoceptor antagonism was unchanged and the atipamezole concentration present in brain was even elevated at 10 days compared to levels after 24-h infusion. In conclusion, these results reveal that acute and sub-chronic atipamezole treatments have different and even opposite effects on behaviour in novel, stressful situations. After acute treatment, atipamezole potentiates reaction to novelty and stress, causing a decrease in exploratory activity and impairment in shock avoidance learning. After subchronic treatment, there was no longer any effect on exploratory behaviour and, in fact, there was an improvement in the learning of a mildly stressful active avoidance test. The changes in behaviour occurred in parallel with attenuation in the MHPG-SO4-increasing effect, thus the suppressed behaviour in the present test conditions after acute atipamezole injection is associated with a major increase in central NA release. The results support the role of α2-adrenoceptors and noradrenergic system in reactions both to novelty and stress and have possible implications in cognitive functions as well as in depression.

The establishment of a network of European human research tissue banks.

This is a report of a workshop held on the establishment of human research tissue banking which was held in Levi, Finland 21–24 March 2002.There were 21 participants from 7 European countries. This meeting was attended by representatives from academia, research tissue banks and from the Biotech and Pharmaceutical Industries. The principal aim of the workshop was to find a way to progress the recommendations from ECVAM workshop 44 (ATLA 29, 125–134,2001) and ECVAM workshop 32 (ATLA 26, 763–777, 1998). The workshop represented the first unofficial meeting of the European Network of Research Tissue Banks (ENRTB) steering group. It is expected that in the period preceding the next workshop the ENRTB steering group will co-ordinate the ethical,legislative and organisational aspects of research tissue banking. Key issues dealt with by the Levi workshop included the practical aspects of sharing expertise and experiences across the different European members. Such collaboration between research tissue banks and end users of such material seeks to ultimately enable shared access to human tissue for medical and pharmaco-toxicological research while maintaining strict adherence to differences in legal and ethical aspects related to the use of human tissue in individual countries.

Metabolism of detomidine in the rat. II. Characterisation of metabolites in urine.

SummaryIn order to investigate the biotransformation of a new a2-adrenoceptor agonist, detomidine, metabolites were isolated from rat urine by solid phase extraction and purified by TLC. The isolated compounds were structurally analysed by1H-NMR, MS and GC-MS as such or as their methyl and/or silyl derivativesIn addition to detomidine, which was found in trace amounts, four major metabolites were identified: hydroxymethyldetomidine, the corresponding O-glucuronide, detomidine carboxylic acid, and detomidine mercapturate. Together the identified components make up about 80% of urinary detomidine derived compounds.On the basis of these findings a major biotransformation pathway could be suggested. The reaction sequence is initiated by a hydroxylation. Subsequent glucuronidation, glutathione conjugation or secondary oxidation divide the route into three branches each producing one of the other three identified metabolites.

Radioimmunoassay of detomidine, a new benzylimidazole drug with analgesic sedation properties

A sensitive and specific radioimmunoassay was developed for detomidine, 4(5)-(2,3-dimethylbenzyl)imidazole. The antibodies were raised in rabbits against a conjugate of detomidine and bovine thyroglobulin prepared by diazo reaction. Detomidine was iodinated with chloramine-T and immunoreactive tracer was purified in cation exchange chromatography. The sensitivity of the RIA was 1.6 fmol/tube allowing direct detomidine measurements from minute serum and urine samples (0.1-0.2 microliter) as well as tissue homogenates (10 microliters). For concentrations below 16 pmol/ml chloroform extraction was used to extend the measurement range to 0.3 pmol/ml. Detomidine (80 micrograms/kg iv and im) was given to one horse and two calves and blood samples were taken and urine collected for 24 h whereafter the horse was slaughtered and tissue samples taken for RIA analyses. Serially diluted serum, urine and tissue samples produced a linear displacement curve parallel to synthetic detomidine in RIA. HPLC studies showed that serum and tissue immunoreactivity was unchanged detomidine whereas most immunoreactivity in the urine was due to an unknown metabolite.

Systemic absorption and systemic effects of ocularly administered dexmedetomidine in rabbits

Dexmedetomidine is a selective alpha 2-adrenoceptor agonist which has previously been shown to reduce the ocular pressure of normotensive rabbits as well as those with pressures artificially elevated by laser irradiation. In this study instillation of an equivalent hypotensive dose (12.5 micrograms) did not cause changes in heart rate, blood pressure, blood glucose or plasma catecholamine content even though dexmedetomidine could be detected in plasma. However, this dose given intravenously (i.v.) was also without effect. Higher ocular doses resulted in equivalent bradycardia and changes in blood glucose levels as when the dose was given i.v. These two parameters proved to be most sensitive indicators of systemic alpha 2-agonism, blood pressure did not change and plasma catecholamine levels were too low to be reliably assayed. It is concluded that when hypotensive doses of dexmedetomidine are instilled into the eye, intraocular concentrations are sufficiently high to exert pharmacological effects. As it is absorbed into the general circulation, it is diluted such that its systemic effects are minimal.