R M Major scite author profile

R M Major

4Publications

30Citation Statements Received

8Citation Statements Given

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106

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St. James's Hospital, Huntingdon College

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Isosorbide 5‐mononitrate pharmacokinetics in humans

Taylor¹,

Chasseaud²,

Major³

et al. 1981

Biopharm & Drug Disp

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When isosorbide 5-mononitrate was intravenously infused at a rate of 4 mg h-1 for 2.5 h to five human subjects, its concentrations in plasma increased slowly to 185 ng ml-1 +/- 5 per cent C.V. at 2.5 h and a steady-state plasma level was not reached during the infusion. When the infusion was discontinued, plasma drug concentrations declined with an elimination half-life of 4.2 h +/- 6 per cent C.V. The systemic clearance after the infusion doses was 132 ml min-1 +/- 18 per cent C.V. and the volume of distribution was 48.4 +/- 16 per cent C.V. After equal oral doses of 10 mg, the peak plasma isosorbide 5-mononitrate concentration of 191 ng ml-1 +/- 16 per cent C.V. was reached at 1.1 h +/- 30 per cent C.V., and plasma levels declined with a terminal half-life of 4.9 h. The complete systemic availability of isosorbide 5-mononitrate indicated that pre-systemic elimination after the oral doses was negligible. A one-compartment open model appeared adequate to describe the plasma level data after intravenous infusion and oral dose. After single oral doses of 10 mg isosorbide dinitrate, the peak plasma concentration of the 5-mononitrate metabolite of 72 ng ml-1 +/- 27 per cent C. V. occurred at 1.7 h +/- 41 per cent C.V. Approximately 50 per cent (range 22--68 per cent) of the oral dose of isosorbide dinitrate circulated in plasma as the 5-mononitrate metabolite. The pharmacokinetics of isosorbide mononitrates are markedly different to those of the parent dinitrate and these differences follow from the greater systemic availability and volume of distribution of the mononitrates.

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Isosorbide 5-mononitrate kinetics

Major

Taylor

Chasseaud

et al. 1984

Clin Pharmacol Ther

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The kinetics of isosorbide 5-mononitrate (5-ISMN) were studied in 12 healthy subjects after intravenous infusion and oral doses of 20 mg. Kinetic parameters calculated by model-independent methods or by assumption of a one-compartment open model were in good agreement. Mean (+/- SD) systemic clearance of 5-ISMN was 127 +/- 21 ml/min, volume of distribution was 48.5 +/- 6.1 l, t 1/2 was 4.4 +/- 0.5 hr, and mean residence time was 6.2 +/- 0.7 hr. At the end of intravenous infusion of 5-ISMN at a rate of 8 mg/hr for 2.5 hr, mean plasma drug concentrations reached 356 +/- 39 ng/ml. Oral doses of 5-ISMN were essentially completely absorbed (93% +/- 13% systemic availability), and mean peak plasma drug concentrations of 388 +/- 70 ng/ml occurred at 0.83 +/- 0.46 hr. Mean absorption t 1/2 was 19 +/- 12 min. Unlike other vasodilator organic nitrates in clinical use, 5-ISMN is notable for its relatively long t 1/2, essentially complete oral absorption, lack of active metabolites, and low intersubject variability in kinetics.

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Bioequivalence of a sustained‐release isosorbide dinitrate formulation at steady‐state

Taylor¹,

Chasseaud²,

Major³

et al. 1985

Biopharm & Drug Disp

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Isosorbide 2,5-dinitrate and its pharmacologically active metabolites, isosorbide 2-nitrate and isosorbide 5-nitrate, in plasma accumulated to the predicted steady-state after five consecutive oral doses of sustained-release tablets containing 40 mg isosorbide dinitrate at 12-h intervals and after five consecutive oral doses of reference standard-release tablets containing 20 mg at 6-h intervals to 12 subjects in a crossover study. The comparative bioavailability of isosorbide dinitrate, isosorbide 2-nitrate and isosorbide 5-nitrate from the sustained-release tablet was 110 per cent (p greater than 0.05), 89 per cent (p greater than 0.05), and 89 per cent (p less than 0.05), respectively, of that from the reference standard-release tablet. The isosorbide dinitrate plasma level data were the more variable, as expected for a drug of low systemic availability subject to extensive first-pass elimination. The posterior probability that the true bioavailability of isosorbide dinitrate was included within the usually accepted limits of 80-120 per cent was 0.74, a value which is probably insufficient to justify claims of bioequivalence with the reference formulation in respect of extent of availability. In contrast, the posterior probability that the bioavailability of the metabolites isosorbide 2- and 5-nitrate was included within these limits was 0.90 and 0.98, respectively. On the basis of the mononitrate data, these two formulations may be judged bioequivalent in respect of extent of availability despite a formal statistically significant formulation-related effect in the analysis of variance of the isosorbide 5-nitrate bioavailability data. Claims of bioequivalence of isosorbide dinitrate sustained-release formulations may be more economically justified by analysis of the mononitrate plasma concentrations, although concentrations of the formulated parent dinitrate should also be known.

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Species differences in the pharmacokinetics and metabolism of reparixin in rat and dog

Midgley¹,

Fitzpatrick²,

Wright³

et al. 2006

Xenobiotica

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The pharmacokinetics and metabolism of reparixin (formerly repertaxin), a potent and specific inhibitor of the chemokine CXCL8, were investigated in rats and dogs after intravenous administration of [14C]-reparixin L-lysine salt. Protein binding of reparixin was investigated in vitro in rat, dog, rabbit, cynomolgus monkey and human plasma. Plasma protein binding of reparixin was >99% in the laboratory animals and humans up to 50 microg ml-1, but lower at higher concentrations. Although radioactivity was rapidly distributed into rat tissues, Vss was low (about 0.15 l kg-1) in both rat and dog. Nevertheless, reparixin was more rapidly eliminated in rats (t1/2 approximately 0.5 h) than in dogs (t1/2 approximately 10 h). Systemic exposure in dog was due primarily to parent drug, but metabolites played a more prominent role in rat. Oxidation of the isobutyl side-chain was the major metabolic pathway in rat, whereas hydrolysis of the amide bond predominated in dog. Urinary excretion, which accounted for 80-82% of the radioactive dose, was the major route of elimination in both species, and biotransformation of reparixin was complete before excretion.

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R M Major

Isosorbide 5‐mononitrate pharmacokinetics in humans

Isosorbide 5-mononitrate kinetics

Bioequivalence of a sustained‐release isosorbide dinitrate formulation at steady‐state

Species differences in the pharmacokinetics and metabolism of reparixin in rat and dog

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