Zhao Rong Chen

Mu receptor binding of some commonly used opioids and their metabolites

The binding affinity to the mu receptor of some opioids chemically related to morphine and some of their metabolites was examined in rat brain homogenates with 3H-DAMGO. The chemical group at position 6 of the molecule had little effect on binding (e.g. morphine-6-glucuronide Ki = 0.6 nM; morphine = 1.2 nM). Decreasing the length of the alkyl group at position 3 decreased the Ki values (morphine less than codeine less than ethylmorphine less than pholcodine). Analgesics with high clinical potency containing a methoxyl group at position 3 (e.g. hydrocodone, Ki = 19.8 nM) had relatively weak receptor binding, whilst their O-demethylated metabolites (e.g. hydromorphone, Ki = 0.6 nM) had much stronger binding. Many opioids may exert their pharmacological actions predominantly through metabolites.

Simultaneous determination of dextromethorphan and three metabolites in plasma and urine using high-performance liquid chromatography with application to their disposition in man.

A simple, sensitive, and reproducible high-performance liquid chromatrography assay is described for the simultaneous determination of dextromethophan, dextrorphan, 3-hydroxymorphinan, and 3-methoxymorphinan in plasma and urine. A conventional solvent-solvent extraction procedure was used for the isolation of the analytes from plasma and urine samples. The compounds were separated on a cyano column (150 x 4.6 mm, 5-μm particle size) using a mobile phase of acetonitrile/triethylamine/distilled water (17:0.06:82.94, vol/vol), pH 3.0, and then were measured by fluorescence detection. Calibration curves in the range 2–200 ng/ml for plasma and 0.05–10 μg/ml for urine were linear and passed through the origin. The precision and accuracy were >90% and the lowest detectable concentrations were 0.5 ng/ml for 3-hydroxymorphinan and 3-methoxymorphinan and 1 ng/ml for dextromethorphan and dextrophan in plasma. The utility of this method is demonstrated in a preliminary study of dextromethorphan metabolism and pharmacokinetics in man.

Morphine formation from codeine in rat brain: A possible mechanism of codeine analgesia

The O-demethylation of codeine to morphine was demonstrated in rat brain homogenate. Maximal formation occurred at 10 minutes, with a Vmax of 5.93 +/- 0.16 nmol/g brain/h and Km of 37.82 +/- 4.99 microM. The formation was significantly (P less than 0.05) greater in the microvessel-rich brain fraction. Intraperitoneal injection of codeine in the rat resulted in brain concentrations of morphine which could not be solely attributed to transfer of morphine from the blood stream across the blood-brain barrier. Morphine formed in the brain after codeine administration may be an important mechanism for codeine-induced analgesia.

Simultaneous determination of codeine, norcodeine and morphine in biological fluids by high-performance liquid chromatography with fluorescence detection

A novel high-performance liquid chromatographic method for the determination of codeine, norcodeine and morphine in plasma and urine has been developed. The compounds were separated on a cyano column (15 cm x 4.6 mm, 5 microns particle size) using a mobile phase of acetonitrile-triethylamine-distilled water (4:0.1:95.9, v/v) pH 3.1 and then determined by fluorescence detection. Calibration curves in the range 5-200 ng/ml for plasma and 0.1-10 micrograms/ml for urine were linear and passed through the origin. The imprecision and inaccuracy of the assay were less than 10% and the limits of detection were 2 ng/ml for all three compounds in human plasma.

Dextromethorphan metabolism in rat: Interstrain differences and the fate of individually administered oxidative metabolites

1. Dextromethorphan undergoes O- and N-demethylation, with the resultant metabolites being further N- and O-demethylated respectively to 3-hydroxymorphinan. The polymorphically expressed O-demethylation reaction is catalysed by P4502D1 in the Sprague-Dawley (SD) rat. The Dark-Agouti (DA) rat lacks this enzyme. 2. The aims were: (1) to determine if there were strain differences also in the Hooded Wistar (HW) and Albino Wistar (AW) rats with respect to the four demethylation reactions after dextromethorphan 20 mg/kg intraperitoneally; (2) to investigate the inhibition of the demethylation reactions by quinine and quinidine (each 40 mg/kg i.p.) in the above strains; and (3) to investigate the fate of separately administered metabolites (5 mg/kg i.p.) of dextromethorphan in the SD strain. 3. The total recovery of dextromethorphan and metabolites in the four strains ranged from 38 to 64% of the dose. The O-demethylation ratios (expressed as the ratio of urinary total dextrorphan divided by dextromethorphan) in the AW and DA strains were similar but less than in the SD/HW strains; the N-demethylation ratios (expressed as the ratio of urinary total 3-hydroxymorphinan plus 3-methoxymorphinan divided by dextromethorphan) in the DA and SD strains were similar but greater than in the AW and HW strains. Quinine and quinidine significantly reduced the O-demethylation ratio in the SD and DA rat strains, and the N-demethylation ratio in the SD strain. 4. In the SD rat the major metabolic route was via O-demethylation to dextrorphan. The source of 3-hydroxymorphinan is primarily from N-demethylation of dextromethorphan to 3-methoxymorphinan and its subsequent O-demethylation to 3-hydroxymorphinan. The O-demethylation metabolic ratio for dextromethorphan should be calculated as the quotient of urinary total dextrorphan divided by dextromethorphan.

Direct determination of codeine-6-glucuronide in plasma and urine using solid-phase extraction and high-performance liquid chromatography with fluorescence detection

A sensitive and selective method was developed for the direct determination of codeine-6-glucuronide in plasma and urine using high-performance liquid chromatography (HPLC) with fluorescence detection. Codeine-6-glucuronide was synthesised and its purity estimated using acid and enzyme hydrolysis. The hydrolysis of codeine-6-glucuronide by beta-glucuronidase was incomplete and urine reduced the extent of hydrolysis. Codeine-6-glucuronide was recovered from plasma using a solid-phase extraction column and separated on a reversed-phase C18 HPLC column. The assay showed good reproducibility and accuracy (within 10%), and standard curves were linear between 32 and 1600 ng/ml in plasma and between 0.32 and 160 micrograms/ml in urine. The assay has been applied to the study of the pharmacokinetics and metabolism of codeine in patients.

Lack of effect of paracetamol on the pharmacokinetics and metabolism of codeine in man.

SummaryPlasma and urine concentrations of codeine and its measurable metabolites were determined by HPLC in six healthy subjects after a single 30 mg oral dose of codeine either alone or after 7 doses of 1 g paracetamol 8 hourly.After codeine alone, the t1/2 (h), AUC (μmol·l−1·h) and CLR (ml·min−1) for codeine were 2.2, 0.81, and 252 respectively. These were not significantly altered by paracetamol: 2.2, 0.84, and 291 respectively.For codeine-6-glucuronide the values were 2.4, 22.0, and 29.7 respectively. These were not significantly different from those after codeine plus paracetamol: 2.4, 21.9, and 39.6. There were no significant differences between the two treatments in the apparent partial clearances (ml·min−1) of codeine to morphine (88 codeine alone, 70 codeine plus paracetamol), to norcodeine (71 codeine alone, 88 codeine plus paracetamol), and to codeine-6-glucoronide (820 codeine alone, 1022 codeine plus paracetamol).The urinary excretion of codeine-6-glucuronide, morphine, norcodeine, and codeine were not significantly different between the two treatments.