Nobuyoshi Kaneniwa scite author profile

The hygroscopicity of theophylline anhydrate has been investigated by gas adsorption and hydration kinetic methods. Type 1 theophylline anhydrate was obtained by recystallization from distilled water at 95 degrees C, and type II was obtained by dehydration of theophylline monohydrate. The X-ray diffraction pattern of types I and II agreed with the data of theophylline anhydrate. However, the diffraction peaks of the (200) and (400) planes of type I were much stronger than those of type II. The particles of type I were clear crystalline-like single crystals. However, the particles of type II had many cracks. The gas affinity balance (H/N) of type II, measured by gas adsorption, was about 7 times that of type I. After the hygroscopicity of types I and II had been tested at various levels of relative humidity (RH) at 35 degrees C, type I was stable at less than 82% RH, but transformed into the monohydrate at more than 88% RH. Type II was stable at less than 66% RH and transformed into the monohydrate at less than 75% RH. The hydration data of type I at 88% RH and type II at 75% RH were calculated for hydration kinetics using various solid-state kinetic models, but no particular model could be preferred from these data.

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Pharmacokinetic study of the fate of acetaminophen and its conjugates in rats

Watari

Iwai

Kaneniwa

1983

Journal of Pharmacokinetics and Biopharmaceutics

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Pharmacokinetic studies of the fate of acetaminophen and its major metabolites, acetaminophen sulfate (AS) and acetaminophen glucuronide (AG), were made in rats. The rates of conjugate formation were calculated by deconvolution. The Michaelis-Menten equation gave maximum velocity and Michaelis constant (Km) values of 4.92 mumol/min/kg and 109 microM for AS formation, and 2.76 mumol/min/kg and 915 microM for AG formation. However, AG formation showed approximately first-order behavior in the present dose range because of its large Km value. The disposition of acetaminophen could be described by a two-compartment model with simultaneous first-order and Michaelis-Menten type elimination kinetics for AS formation. Curve fitting of the data based on this model was successfully done for doses of up to 1058 mumol/kg, suggesting that sulfation proceeds without depletion of sulfate in the blood at least up to this dose. The disposition of AS could be described by a two-compartment model and was apparently dose-independent over an 8-fold dose range. Although a slight dose dependence in the elimination of AG was suggested over a 16-fold dose range, for the purpose of the present study, it was assumed that the disposition of AG is approximately linear. The excretion of AS in the bile was negligibly small, whereas a considerable amount of AG was excreted into the bile. The results following intraduodenal injection of AS or AG indicated that AS or AG was hydrolyzed by the microflora and the liberated acetaminophen was reabsorbed, confirming enterohepatic circulation of the conjugates. This was consistent with the urinary metabolite excretion patterns observed after acetaminophen injection in normal and bile fistula rats. Based on the kinetic parameters obtained, the plasma concentrations of AS and AG after acetaminophen injection were simulated, and a fairly good agreement was obtained between calculated and observed values at the dose of 264.6 mumol/kg. Although the urinary metabolite excretion pattern differs from that of humans, the kinetic parameters obtained for rats were similar to those for humans in some respects, suggesting that the rat might be useful as a model animal to predict human data.

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Nobuyoshi Kaneniwa

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Pharmacokinetic study of the fate of acetaminophen and its conjugates in rats

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