Spontaneous chemiluminescence production, lipid peroxidation, and covalent binding in rat hepatocytes exposed to acetaminophen

Spontaneous chemiluminescence associated with the cell injury was observed in the isolated rat hepatocyte suspension during acetaminophen (APAP) metabolism, indicating the occurrence of oxidative stress. APAP apparently affected the hepatocytes in various manners. APAP, at low concentrations (1-2 mM), damaged the hepatocytes due to lipid peroxidation provoked during APAP metabolism, while at high concentrations (5-50 mM), APAP protected the hepatocytes due to a chemical antioxidant effect of the unmetabolized APAP that remained in the medium because of the saturation of APAP metabolism. The covalent binding of APAP to the hepatocytes increased with APAP concentration up to 50 mM without loss of cell viability. When an overdose of APAP was administered to rats, the APAP plasma concentration was around 1-3 mM, which corresponded to the concentration range where lipid peroxidation occurred in the isolated hepatocytes. Thus, it seems likely that lipid peroxidation contributes to the APAP-induced hepatotoxicity in the early stage of the toxic process.     

Repeat exposure to incremental doses of acetaminophen provides protection against acetaminophen-induced lethality in mice: an explanation for high acetaminophen dosage in humans without hepatic injury

In studies designed to simulate a clinical observation in which an individual became tolerant to normally lethal doses of acetaminophen (APAP), mice were pretreated with increasing doses of APAP for 8 days and challenged on day 9 with normally supralethal doses of APAP. These animals developed minimal hepatotoxicity after a challenge dose with a fourfold increase in LD50 to 1,350 mg/kg. The pretreatment regimen resulted in hepatic changes including: centrilobular localization of 3-(cysteine-S-yl)APAP protein adducts, selective down-regulation of cytochrome P4502E1 (CYP2E1) and CYP1A2 that produced the toxic metabolite, N-acetyl-p-benzoquinone imine, higher levels of reduced glutathione (GSH), centrilobular inflammation, and a fourfold increase in hepatocellular proliferation. The protection against the lethal APAP doses afforded by pretreatment is secondary to these changes and to the associated regional shift in the bioactivation of the APAP challenge dose from centrilobular to periportal regions where CYP2E1 is not found, protective GSH is more abundant, and where cell-proliferative responses are better able to sustain repair. This shift in APAP bioactivation results in less-intense covalent binding that is more diffuse and spread uniformly throughout the hepatic lobe, most likely contributing to protection by delaying the early onset of liver injury that has been generally associated with centrilobular localization of the adducts. Intervention of APAP pretreatment-induced cell division in mice with colchicine left them resistant to a 500-mg/kg (normally lethal) dose of APAP, but unable to survive a 1,000-mg/kg APAP challenge dose. The data demonstrate multiple mechanistic components to the protection afforded by APAP pretreatment. Whereas metabolic and physiological changes not dependent on cell proliferation are adequate to protect against 500 mg/kg APAP, these changes plus a potentiated cell-proliferative response are necessary for protection against the supralethal 1,000-mg/kg APAP dose. Furthermore, the data document an uncoupling of the traditional association between covalent binding and toxicity, and suggest that the assessment of toxicity following repeated or chronic APAP exposure must consider altered drug interactions and parameters besides those historically used to assess acute APAP overdose.     

Refining the level for anticipated hepatotoxicity in acetaminophen poisoning

Treatment of an acetaminophen overdose with N-acetyl cysteine usually is based on the position of the 4-h acetaminophen (APAP) level on the Rumack-Matthew nomogram; however, there is disagreement on the level at which clinically relevant hepatotoxicity occurs. A retrospective review of all acute adult formulation APAP exposures reported to our poison center between 1986 and 1993 was performed and cases corresponding to the "possible risk or toxicity" range on the nomogram were identified. Our current poison center protocol for APAP poisoning does not recommend treatment with N-acetylcysteine (NAC) in low-risk patients if the 4-h serum APAP level or the extrapolated equivalent falls within the possible toxicity range on the nomogram. Seventeen cases met the inclusion criteria for the study and received no NAC; six additional patients met inclusion criteria but received one or two doses of NAC before therapy was discontinued. No patients in either group demonstrated clinical evidence of hepatotoxicity. This pilot study suggests that patients with no risk factors and APAP levels in the "possible risk" range may not require NAC therapy.     

Acute hepatotoxicity of acetaminophen in rats treated with ethanol plus isopentanol

Acetaminophen (APAP) hepatotoxicity was investigated in rats fed ethanol and isopentanol alone or in combination in a liquid diet for 7 days. Serum levels of aspartate aminotransferase (AST) and histological examination of liver slices were used to assess hepatotoxicity. At 7 hr after intragastric administration of 0.5 or 1.0 g APAP/kg, there was no significant increase in serum levels of AST in rats treated with APAP alone, or in rats pretreated with ethanol or isopentanol alone followed by APAP. There was mild central lobular congestion in the livers of rats pretreated with ethanol alone followed by APAP. In contrast, in rats pretreated with the combination of ethanol and isopentanol, administration of APAP caused a dramatic increase in serum levels of AST, along with marked central lobular necrosis, including steatosis and ischemic changes. Hepatic glutathione levels were decreased to 40-50% of control values in APAP-treated rats that had been pretreated with ethanol either alone or in combination with isopentanol. The serum concentrations of APAP were significantly lower in rats pretreated with the combination of ethanol and isopentanol followed by 1 g APAP/kg than in rats treated with APAP alone, suggesting a greater rate of APAP metabolism. We had reported previously that combined treatment of rats with ethanol and isopentanol resulted in additive to synergistic increases in CYP3A, with no further increases in CYP2E than that caused by ethanol alone. CYP3A may, therefore, be responsible for the increased APAP hepatotoxicity caused by the combined alcohol treatment.     

Probenecid protects against In vivo acetaminophen-induced nephrotoxicity in male Wistar rats

Renal effects of acetaminophen (APAP) were studied in rats pretreated with probenecid to analyze whether acute APAP-induced nephrotoxicity could be related to a probenecid-sensitive transport system for APAP or its S-derived conjugates. The administration of probenecid (200 mg/kg b.wt. i.p.) 30 min before APAP administration (1000 mg/kg b.wt. i.p.) improved urine flow rate and protected against the alterations on glomerular filtration rate and urea and creatinine plasma levels induced by APAP. Fewer epithelial cells and granular casts and a decrease in the urinary excretion of protein and glucose were observed in rats pretreated with probenecid. Probenecid pretreatment promoted an elevation in the urinary 16-hr excretion of APAP and a diminution in the plasma levels attained by APAP. These results suggest that protection afforded by probenecid in vivo could be a consequence of the inhibition of APAP S-conjugate renal uptake and/or an increase in APAP renal clearance. The effects of APAP in presence of probenecid were studied with the isolated perfused kidney model. Perfusion with probenecid (0.1 mM) before APAP (10 mM) did not change APAP direct renal effects, APAP urinary excretion, or APAP renal clearance relative to glomerular filtration rate. Our results suggest that protection afforded by probenecid in vivo could be the result of the inhibition of the uptake of nephrotoxic APAP metabolites and/or a diuresis-induced enhanced APAP renal excretion.     

Repeated dosing with the peroxisome proliferator clofibrate decreases the toxicity of model hepatotoxic agents in male mice

Pretreatment of mice with clofibrate (CFB) has been shown to protect against acetaminophen (APAP) hepatotoxicity. To determine if pretreatment with CFB prevents the toxicity of other model hepatotoxicants, male C57BL6J or CD-1 mice received 500 mg CFB/kg, i.p., daily for 10 days, and then were challenged with either 250 mg bromobenzene (BrB)/kg, 0.025 ml carbon tetrachloride (CCl4)/kg or 0.5 ml chloroform (CHCl3)/kg. Liver and kidney injury was assessed by plasma sorbitol dehydrogenase activity (SDH) and blood urea nitrogen (BUN), respectively and histopathology. Challenge with BrB significantly elevated plasma SDH activity in C57Bl6J mice. This was prevented in CFB pretreated mice receiving the same dose of BrB. Changes in BUN were not detected in either group of BrB treated mice. Similarly, pretreatment of male CD-1 mice with CFB significantly reduced CCl4-induced elevation in plasma SDH activity, with no BUN elevation detected in either group. CFB pretreatment also diminished elevation in plasma SDH activity produced by CHCl3 in CD-1 mice, while BUN was significantly elevated in both groups, indicating that CFB did not protect against CHCl3-induced nephrotoxicity. Histopathological examination of liver and kidney sections confirmed these results. This study shows that mice pretreated with CFB were protected from toxicity at 24 h after challenge with other model hepatotoxic agents besides APAP.     

Attenuation of acetaminophen hepatotoxicity in mice as evidence for the bioavailability of the cysteine in D-glucose-L-cysteine in vivo

A substantial fraction of the cysteine added to total parenteral nutrition (TPN) solutions is converted to the corresponding thiazolidine derivative, while in solution with relatively large concentrations of glucose typical of TPN (700 mM and higher). It was recently reported (Roberts et al. (1987) J. Med. Chem. 30, 1891-1896) that this thiazolidine, D-glucose-L-cysteine (DGC), offered no significant protection against the hepatic injury caused by 5 mmol/kg of acetaminophen in mice, suggesting that the cysteine present as DGC is poorly bioavailable in vivo. In the present study, fasted male ICR mice given 1.6 or 2.6 mmol/kg of acetaminophen sustained hepatic injury, estimated by elevations in plasma alanine aminotransferase (ALT) activities. Administration of 2.5 mmol/kg of N-acetylcysteine (NAC) 1 h before acetaminophen given i.p. prevented the rise in plasma ALT activities, apparently through support of glutathione (GSH) synthesis. Administration of 2.5 mmol/kg of DGC prior to acetaminophen resulted in slightly lower mean plasma ALT activities than were observed in animals given saline before acetaminophen, but the effect was not statistically significant. When DGC was given 1 h before p.o. administration of 1.6 or 2.6 mmol/kg of acetaminophen, the protective effects of DGC were statistically significant (P < 0.01, 0.025, respectively), although NAC afforded significantly greater protection than did DGC at the higher dose of acetaminophen. Given 4 h before acetaminophen, DGC attenuated acetaminophen-induced increases in plasma ALT activities significantly, whereas NAC was without effect. These results indicate that the cysteine in DGC is at least partially bioavailable in vivo and, further, that DGC may function as a slow release formulation of cysteine.     

N-hydroxyacetaminophen: a postulated toxic metabolite of acetaminophen

The decomposition of N-hydroxyacetaminophen has been shown to occur via an initial first-order dehydration step to N-acetyl-p-benzoquinone imine with a rate constant at pH 7.6 of 8.66 x 10(-3) min-1 and a half-life of 80 min. This is followed by a complex reaction between the quinone imine and the N-hydroxy compound to ultimately yield p-nitrosophenol and acetaminophen. The glucuronide and sulfate conjugates of N-hydroxyacetaminophen have been observed as urinary metabolites of N-hydroxyacetaminophen. No N-hydroxylated metabolites were found among the metabolites of acetaminophen. These results have been interpreted to show that N-hydroxyacetaminophen is not a metabolite of acetaminophen. It is proposed that the hepatotoxicity and nephrotoxicity of acetaminophen are mediated by a direct oxidation of acetaminophen to the toxic reactive intermediate N-acetyl-p-benzoquinone imine by the cytochrome P450 dependent mixed-function oxidase system.     

Methohexital impairs osmoregulation. Studies in conscious and anesthetized volume-expanded dogs

BACKGROUND: Anesthetic agents influence central regulations. This study investigated the effects of methohexital anesthesia on renal and hormonal responses to acute sodium and water loading in dogs in the absence of surgical stress. METHODS: Fourteen experiments (two in each dog) were performed in seven well-trained, chronically tracheotomized beagle dogs kept in highly standardized environmental and dietary conditions (2.5 mmol sodium and 91 ml water/kg body weight daily). Experiments lasted 3 h, while the dogs were conscious (7 experiments) or, after 1 h control, while they were anesthetized (7 experiments) with methohexital (initial dose 6.6 mg/kg body weight and maintenance infusion 0.34 mg.min-1.kg-1 body weight) over a period of 2 h. In both experiments, extracellular volume expansion was performed by intravenous infusion of a balanced isoosmolar electrolyte solution (0.5 ml.min-1.kg-1 body weight). Normal arterial blood gases were maintained by controlled mechanical ventilation. In another five dogs the same protocol was used, and vasopressin (0.05 mU.min-1.kg-1 body weight) was infused intravenously during methohexital anesthesia. RESULTS: Values are given as means. During methohexital anesthesia, mean arterial pressure decreased from 108 to 101 mmHg, and heart rate increased from 95 to 146 beats/min. Renal sodium excretion decreased; urine volume increased; and urine osmolarity decreased from 233 to 155 mosm/l, whereas plasma osmolarity increased from 301 to 312 mosm/l because of an increase in plasma sodium concentration from 148 to 154 mmol/l. Plasma renin activity, plasma aldosterone concentration, plasma atrial natriuretic peptide, and plasma antidiuretic hormone concentrations (range 1.8-2.8 pg/ml) did not change in either protocol. In the presence of exogenous vasopressin (antidiuretic hormone 3.3 pg/ml), water diuresis did not occur, and neither plasma osmolarity nor the plasma concentration of sodium changed. CONCLUSIONS: Methohexital may impair osmoregulation by inhibiting adequate pituitary antidiuretic hormone release in response to an osmotic challenge.     

Quantification and predictors of plasma volume expansion from mannitol treatment

OBJECTIVE: To determine the effects of acute hypertonic mannitol infusion on intravascular volume expansion and to identify potential predictors of hypervolemia. DESIGN: Measurements of plasma volume and volume regulatory hormones were performed in healthy volunteers before and over 90 min after acute infusion of 20% mannitol solution in a therapeutic dose of 0.5 g/kg body weight, equalling an average infusion volume of 180 ml. SETTING: Clinical research unit in an 800-bed teaching hospital in the eastern part of Switzerland. PARTICIPANTS: Eight normal male volunteers. MEASUREMENTS AND RESULTS: Baseline plasma volume was determined by the indocyanine green dye dilution technique. Serial plasma protein measurements were performed after mannitol infusion to calculate intravascular volume changes. Mannitol administration resulted in a plasma expansion that persisted for more than 90 min and peaked at 112% of the baseline plasma volume 15 min after infusion. Concomitantly, an increase in systolic blood pressure and a fall in plasma sodium concentration occurred. Pharmacokinetic analyses of mannitol distribution and elimination revealed a close relation between plasma volume expansion and mannitol serum concentrations. While renin activity and aldosterone concentrations were suppressed proportionally to the intravascular volume increase, antidiuretic hormone was increased despite notable volume expansion and hyponatremia. Similarly, a rise in atrial natriuretic peptide was detected. CONCLUSIONS: Therapeutic doses of hypertonic mannitol cause substantial plasma volume expansion, resulting in increased blood pressure. Plasma volume expansion is related to mannitol serum concentrations and mannitol clearance determines the time required to restore normovolemia. ADH and ANP are potentially aggravating factors of mannitol-induced hyponatremia.     

Mechanism of acetaminophen-induced hepatotoxicity: covalent binding versus oxidative stress

The hepatotoxicity of acetaminophen is believed to be mediated by the reactive metabolite N-acetyl-p-benzoquinone imine; however, the mechanism by which this metabolite produces the toxicity is unknown. The metabolite, which is both an electrophile and an oxidizing agent, may covalently bind to critical proteins, or it may initiate oxidative damage. We have previously developed a Western blot assay for detection of acetaminophen covalently bound to protein and have reported the relationship between covalent binding and the development of hepatotoxicity. Recently, we developed a Western blot assay for protein aldehyde formation, which may occur via the reactive oxygen species, the hydroxyl radical. In this paper, we have compared covalent binding to protein aldehyde formation. Toxic doses of acetaminophen (400 mg/kg) were administered to mice, and the mice were subsequently killed at 0, 1, 2, 4, and 6 h. Since the oxidizing agent FeSO4 has been reported to potentiate lipid peroxidation when administered with acetaminophen, other mice received FeSO4 (100 mg/kg) plus acetaminophen. Compared to saline-treated control mice, acetaminophen treatment significantly increased serum alanine aminotransferase levels, an index of hepatotoxicity, at 4 and 6 h, but not at 1 or 2 h. Acetaminophen plus FeSO4 treatment of mice significantly increased serum alanine aminotransferase levels at 2, 4, and 6 h compared to controls. Levels of alanine aminotransferase in serum of acetaminophen plus ferrous sulfate-treated mice were higher at 4 and 6 h than those of acetaminophen-treated mice, but not significantly different. FeSO4 alone did not increase alanine aminotransferase levels. Western blot assays revealed that acetaminophen did not cause an increase in protein aldehydes over control at any time, nor did acetaminophen plus FeSO4; however, FeSO4 alone increased the intensity of staining of the immunoblot for protein aldehydes over control at all times after 0 time. Acetaminophen-protein adducts were detected in acetaminophen- and acetaminophen plus FeSO4-treated mice. In vitro experiments indicated that FeSO4 plus tert-butyl hydroperoxide in the presence of bovine serum albumin increased protein aldehyde formation. Inclusion of acetaminophen in the incubation mixture inhibited protein oxidation of bovine serum albumin in a concentration dependent manner. The data indicate that acetaminophen quenches protein oxidation, presumably by reacting with the hydroxyl radical. These data are consistent with the theory that acetaminophen covalent binding is the primary mechanism of toxicity and argue against a role for protein oxidation in acetaminophen hepatotoxicity.     

Coadministration of acetaminophen and troglitazone: pharmacokinetics and safety

Troglitazone, a PPAR-gamma agonist, enhances the actions of insulin on muscle and liver. It is metabolized predominantly in the liver to a sulfate conjugate and a quinone metabolite. Acetaminophen also undergoes metabolism by conjugation. This three-way crossover study in 12 healthy male volunteers was conducted to investigate the effects of acetaminophen on the metabolism of troglitazone and vice versa. No statistically or clinically relevant differences in area under the concentration-time curve extrapolated to infinity (AUCinfinity) were observed for troglitazone, its quinone metabolite, or acetaminophen. A statistically significant decrease in troglitazone sulfate conjugate during administration with acetaminophen was not clinically relevant. No statistically or clinically relevant differences were observed in maximum concentration (Cmax), time to Cmax (tmax), or elimination half-life of troglitazone, its two main metabolites, and acetaminophen or in acetaminophen urinary sulfate excretion, although there was a slight decrease in acetaminophen glucuronide excretion during administration with troglitazone. Adverse events were minor and similar between treatments. These findings suggest that troglitazone and acetaminophen can be coadministered without adverse clinical consequences.     

Misoprostol protection against acetaminophen-induced hepatotoxicity in the rat

The hepatoprotective effects of misoprostol on acetaminophen (APAP)-induced toxicity were studied in the rat. Liver injury was evaluated at 36 hr after APAP administration by measuring serum ornithine carbamoyltransferase (OCT) and alanine aminotransferase (ALT) levels, by using tetranitroblue tetrazolium (TNBT) staining and by histological analysis. After APAP administration, peak serum levels of the drug were detected at 15 min. Liver GSH was depleted from control levels of 448 +/- 48 micrograms/g to 82 +/- 2 micrograms/g (P < 0.01) within 3 hr. Serum ALT levels increased significantly after 16 hr and H&E staining revealed significant hepatic necrosis after 12 hr. Rats treated with misoprostol before and after APAP administration showed reduced OCT and ALT levels at 36 hr of overdose (454 +/- 446 IU/liter and 2571 +/- 2944 IU/liter, respectively) compared to those without misoprostol treatment (1348 +/- 480 IU/liter and 6077 +/- 3025 IU/liter, respectively, P < 0.01). TNBT staining showed a reduced area of damage from 28.6 +/- 22.3% to 7.3 +/- 8.9% (P < 0.01), and H&E staining also showed less extensive hepatic necrosis in rats treated with misoprostol before and after the overdose. In a time sequence study, misoprostol treatment starting within 10 hr of overdose showed the same protective effect as when it was given before and after APAP ingestion. No protection was detected when the treatment was started during the development of hepatic injury. However, misoprostol given when injury was established seemed to be protective. Our results show that misoprostol protects the liver against APAP-induced injury if given within 10 hr of overdose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of acute hypoxia on blood catecholamine and whole blood platelet aggregation

Experiments were performed on 250-300 g male Sprague-Dawley rats under urethane (700 mg/kg) and alpha-chloralose (35 mg/kg) anesthesia. Plasma catecholamine concentration and the whole blood platelet aggregation were measured during normoxia, acute hypoxia, reoxygenation, acute hypoxia immediately after bilateral adrenalectomy and acute hypoxia at the end of 15 and 30 min after bilateral adrenalectomy. The plasma adrenaline concentration and the whole blood platelet aggregation increased markedly (P < 0.01), while the plasma noradrenaline concentration tended to increase (P > 0.05) during acute hypoxia. The plasma adrenaline concentration and the whole blood platelet aggregation are capable of restoring to the normal level during reoxygenation. The plasma noradrenaline concentration did not change, while the plasma adrenaline concentration and the whole blood platelet aggregation decreased significantly (P < 0.001 or 0.05) during acute hypoxia for 15 min immediately after bilateral adrenalectomy. On the other hand, plasma adrenaline and noradrenaline were not detectable during acute hypoxia 30 min after bilateral adrenalectomy while the whole blood platelet aggregation deceased markedly (P < 0.01). When adrenaline (1 ng/ml) was added to the blood (in vitro), the whole blood platelet aggregation increased significantly (P < 0.01). All the above results indicate that acute hypoxia leads to increament of whole blood platelet aggregation and plasma adrenaline concentration due to release from the adrenal gland and the increament of the whole blood platelet aggregation may be partly mediated by increased plasma adrenaline.     

In vivo murine studies on the biochemical mechanism of acetaminophen cataractogenicity

C57BL/6 and DBA/2 mice are, respectively, susceptible and resistant both to the induction of aryl hydrocarbon hydroxylase (cytochrome P450 1A1, or CYP1A1) and to the cataractogenicity of acetaminophen, which may involve its bioactivation to a toxic reactive intermediate, catalysed by P450 and (or) prostaglandin H synthase (PHS). Following induction of P450 using beta-naphthoflavone, the cataractogenicity of acetaminophen (400 mg/kg ip) in C57BL/6 mice was reduced by pretreatment with the P450 inhibitors SKF 525A and metyrapone, the glutathione precursor N-acetylcysteine, the antioxidant vitamin E, and the free radical spin trapping agent alpha-phenyl-N-t-butylnitrone (p < 0.05). Acetaminophen (200 mg/kg) cataractogenicity was enhanced by pretreatment with the glutathione depletor diethyl maleate (DEM) and the gamma-glutamylcysteine synthetase inhibitor buthionine sulfoximine (BSO) (p < 0.05). No significant effect on acetaminophen cataractogenicity was observed using the PHS cyclooxygenase inhibitors aspirin or naproxen, or the glutathione reductase inhibitor 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). Accordingly, acetaminophen cataractogenicity in C57BL/6 mice does not appear to be dependent upon bioactivation by PHS. In DBA/2 mice treated with beta-naphthoflavone, a high dose of acetaminophen (750 mg/kg ip) was not cataractogenic, even after pretreatment with DEM, BSO, or BCNU. The resistance of DBA/2 mice to acetaminophen cataractogenesis, despite concomitant pretreatments with an inducer of P450 and several agents that interfere with glutathione-dependent detoxifying pathways, suggests differences in this strain involving cytoprotective pathways subsequent to acetaminophen bioactivation and detoxification of the cataractogenic reactive intermediate. These results indicate that acetaminophen cataractogenicity in C57BL/6 mice results from P450-catalysed bioactivation of acetaminophen to a reactive intermediate, possibly a benzoquinone imine and (or) a free radical, the toxicity of which is reduced by glutathione-dependent reactions.     

Dose-dependent pharmacokinetics of rapamycin-28-N,N-dimethylglycinate in the mouse

Rapamycin-28-N,N-dimethylglycinate methanesulfonate salt (RG), synthesized as a potential water-soluble prodrug to facilitate parenteral administration of the antineoplastic macrolide rapamycin (RA), is active against intracranially implanted human glioma in mice. Preclinical pharmacokinetic studies to evaluate the prodrug were conducted in male CD2F1 mice treated with 10, 25, 50 and 100 mg/kg doses of RG by rapid i.v. injection. The plasma concentration of RG decayed in a distinctly triphasic manner following treatment with the 100 mg/kg dose; however, prodrug disposition was apparent biexponential at each of the lower doses. RG exhibited dose-dependent pharmacokinetics, characterized by an increase in the total plasma clearance from 12.5 to 39.3 ml.min-1.kg-1 for dosage escalations in the range 10-50 mg/kg, while clearance values at doses of 50 and 100 mg/kg were similar. The terminal rate constants decreased linearly as the dose was increased from 10 to 100 mg/kg, eliciting an apparent prolongation of the biological half-life from 2.1 to 4.8 h. There was also a sequential increase in the steady state apparent volume of distribution from 1.73 to 8.75 l/kg. These observations are consistent with saturable binding of RG to plasma proteins while binding to tissue remains linear. Nevertheless, conversion to RA appeared to represent a prominent route of RG elimination. The molar plasma concentration of RA exceeded that of the prodrug within 30-90 min after i.v. treatment and declined very slowly thereafter, with plasma levels sustained between 0.1 and 10 microM for 48 h at each of the doses evaluated. Thus, RG effectively served as a slow release delivery system for RA, implying the possibility of maintaining therapeutic plasma levels of the drug from a more convenient dosing regimen than a continuous infusion schedule. The present findings, coupled with the demonstrated in vivo activity of RG against human brain tumor models, warrant its continued development as a much needed chemotherapeutic agent for the treatment of brain neoplasms.     

Pharmacokinetics of acetaminophen after intravenous and oral administration to spontaneously hypertensive rats and normotensive Wistar rats

In our previous study, we reported the faster metabolism of intravenously administered furosemide, hence the smaller diuretic effect of furosemide in spontaneously hypertensive rats (SHRs) of 16 weeks of age than in the age-matched normotensive Wistar rats. In present study, in order to evaluate whether there is some alteration of the phase II metabolism including glucuronide and sulfate conjugations in 16-week-old SHRs and the age-matched Wistar rats, the pharmacokinetic parameters of acetaminophen (A), A-sulfate, and A-glucuronide were investigated after intravenous (iv) and oral 100 mg/kg administration of A to 16-week-old SHRs and the age-matched Wistar rats. After iv administration of A, the mean fraction of iv dose excreted in 24-h urine as A-sulfate (75.6 versus 67.8%) and the partial clearance of A to A-sulfate (8.10 versus 6.89 mL/ min/kg) were significantly greater in SHRs than in Wistar rats. Conversely, the mean fraction of iv dose excreted in 24-h urine as A-glucuronide (9.39 versus 15.0%) and the partial clearance of A to A-glucuronide (1.01 versus 1.49 mL/min/kg) were significantly smaller in these SHRs. Similar results were also obtained after oral dosing of A. The in vitro sulfotransferase activity toward A was significantly smaller (0.397 versus 0.331 microg/min/mg of protein) in 16-week-old SHRs than in the age-matched Wistar rats, whereas, the glucuronyltransferase activity toward A was not significantly different between these SHRs and Wistar rats. On the other hand, there was no significant difference in the both sulfotransferase and glucuronyltransferase activity toward A between 6-week-old SHRs and age-matched Wistar rats. Therefore, the alterations in sulfation and perhaps glucuronidation of A between 16 -week-old SHRs and normotensive Wistar rats suggested that some physiological factors derived from the chronic hypertensive status in SHRs might affect the disposition of drugs.     

Improvement of impaired glucose tolerance by oral administration of vanadyl sulfate by gavage in streptozotocin-induced diabetic rats

We examined the effect of oral administration of vanadyl sulfate by gavage on the levels of blood glucose and plasma insulin during oral glucose tolerance test (OGTT) in diabetic rats. Diabetes was induced by intravenous injection of streptozotocin at the dose of 32 mg/kg. Nondiabetic control animals were injected with an equal volume of saline. Vanadyl sulfate at a dose of 25, 50, or 75 mg/kg was given orally by gavage for 2 weeks, starting 12 hours after streptozotocin injection. When vanadyl sulfate was given twice a day, half of the one-day-dosage was given in the morning and the remaining half in the evening. Glucose tolerance test with 5 g/kg of glucose was carried out 2 weeks after administration of vanadyl sulfate. The fasting the blood glucose level in the diabetic rats was higher than that in the non-diabetic rats, whereas the plasma insulin level in the diabetic rats was lower. An increase in blood glucose seen in the glucose tolerance test was significantly greater in the diabetic rats than in the non-diabetic rats. The level of plasma insulin was increased by glucose tolerance test in the non-diabetic rats, while it was not changed in diabetic rats. Oral administration of vanadyl sulfate by gavage significantly improved the impaired glucose tolerance in the the diabetic rats in a dose-dependent manner without any change in plasma insulin level. In conclusion, oral administration of vanadyl sulfate by gavage is effective on impaired glucose tolerance in streptozotocin-induced diabetic rats.     

Extracellular dextran-induced p-nitrophenyl-alpha-D-glucoside-hydrolyzing enzyme of Bacillus circulans KA-304: a producer of Schizophyllum commune-lytic enzyme

We previously reported that centrally administered neuropeptide FF (NPFF) inhibited arginine vasopressin (AVP) release. In this study, immunoneutralization of central NPFF was performed to evaluate the role of endogenous NPFF in the regulation of AVP release. Intracerebroventricular (ICV) injection of antiserum against NPFF (Anti-NPFF) significantly augmented the plasma AVP increase induced by hyperosmolality [intraperitoneal injection of hypertonic saline (600 mOsm/kg, 2% BW)] at 60 min after ICV injection compared with normal rabbit serum (NRS) (NRS: 4.20+/-0.30 pg/ml, Anti-NPFF: 5.83+/-0.46 pg/ml, p < 0.01). Anti-NPFF did not cause significant change in plasma osmolality, plasma volume or arterial blood pressure. This evidence indicates that endogenous NPFF might be physiologically involved in osmoregulation of the plasma AVP level through its inhibitory action.