[Formation of oxalate in oxaliplatin injection diluted with infusion solutions].

Oxaliplatin use can cause acute peripheral neuropathy characterized by sensory paresthesias, which are markedly exacerbated by exposure to cold temperatures, and is a dose-limiting factor in the treatment of colorectal cancer.Oxalate is eliminated in a series of nonenzymatic conversions of oxaliplatin in infusion solutions or biological fluids.Elimination of oxalate from oxaliplatin has been suggested as one of the reasons for the development of acute neuropathy.In this study, we developed a high-performance liquid chromatography(HPLC)-based method to detect oxalate formation, and investigated the time dependent formation of oxalate in oxaliplatin diluted with infusion solutions.The results obtained showed that the amount of oxalate in the solution corresponded to 1.6% of oxaliplatin 8 h after oxaliplatin dilution with a 5% glucose solution. On the other hand, oxalate formation from oxaliplatin diluted with a saline solution was ten-fold higher than that from oxaliplatin diluted with the 5% glucose solution.Most patients who were intravenously injected with oxaliplatin experienced venous pain.As a preventive measure against venous pain, dexamethasone was added to the oxaliplatin injection.We measured the amount of oxalate formed in the dexamethasone-containing oxaliplatin injection diluted with a 5% glucose solution.The amount of oxalate formed when dexamethasone was added did not differ significantly from that formed when dexamethasone was not added.Thus, there are no clinical problems associated with the stability of oxaliplatin solutions.

Determination of paroxetine in serum treated with simple pretreatment by pre-column high-performance liquid chromatography using 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride as a fluorescent labeling reagent.

The therapeutic drug monitoring of paroxetine could be used to optimize the pharmacological treatment of depressed patients. A simple and sensitive high-performance liquid chromatography procedure was developed for the determination of paroxetine in serum. After simple pretreatment of serum (50 µL) with acetonitrile and o-phthalaldehyde, paroxetine was derivatized with 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride at 70°C for 20 min in borate buffer (0.1 mol/L, pH 8.0) to produce a fluorescent product. The derivative was separated on a reversed-phase column at 40°C for stepwise elution with (A) acetic acid (10 mmol/L) and (B) acetonitrile. The flow rate was 1.0 mL/min. The fluorescence intensity was monitored at excitation and emission wavelengths of 320 and 400 nm, respectively. The within-day and day-to-day relative standard deviations were 3.0-3.4 and 2.7-8.3%, respectively. The detection limit of paroxetine was 8.3 fmol at a signal-to-noise ratio of 3. As the proposed method that only requires a small quantity of serum (50 µL) is simple, sensitive and reproducible, it would be useful for clinical and biochemical research as well as drug monitoring.

[Comparison of hypersensitivity to branded and generic paclitaxel injections in rats].

The use of injectable generic antineoplastic agents has been increasing. Few studies have compared the quality and adverse reactions of generic and branded antineoplastic agents; and therefore, generic agents have not gained wide acceptance. Paclitaxel injections, which are used for treating solid cancers, are being marketed by some companies in Japan. The degree of hypersensitive reactions to these drugs may vary because of the differences in chemical properties of the polyoxyethylene castor oil that is used as a solvent in the paclitaxel preparations. Therefore, we investigated the incidence of pulmonary edema occurring as a hypersensitive reaction in rats administered branded and generic paclitaxel injections. Moreover, we compared the chemical properties of these preparations. We found that the pH of branded and generic paclitaxel preparations diluted with saline was different. This difference in pH may be attributed to a difference in chemical properties from the additive. We observed no significant differences in pulmonary vascular permeability, arterial partial pressure of oxygen, or leakage of protein in the pulmonary alveolus, between paclitaxel preparations administered to rats. These results suggest that both paclitaxel preparations induced pulmonary edema of a similar level in rats, irrespective of the differences in their chemical properties.

[Management system of cancer chemotherapy regimens].

Cancer chemotherapy regimens which had been used at a ward and outpatient chemotherapy in various departments were collected and made available to everybody in October, 2003. However, it was difficult to manage cancer chemotherapy regimens in real time, from the viewpoint of risk management. Then, the Cancer Chemotherapy Center took the leading part and established a chemotherapy exploratory committee, which consists of 4 doctors, 2 nurses and 2 pharmacists, in June, 2006. The department of pharmacy could control all cancer chemotherapy regimens by this system, and lead the proper use of increasing anticancer agents. Inquiries on prescription by the pharmacist contributed to proper medical treatment. The role of the cancer chemotherapy exploratory committee and its outcome are described for the purpose of the prevention of medical accidents in this paper.

Possible relationships between plasma carbamazepine-10,11-epoxide levels and antimanic efficacy and side effects in patients with schizoaffective disorde.

We examined the relationships of plasma levels of carbamazepine (CBZ) and its two major metabolites, carbamazepine-10,11-epoxide (CBZ-E) and carbamazepine-10,11-diol (CBZ-D), with antimanic efficacy and side effects in patients with schizoaffective disorder. Positive relationships were found among plasma concentrations of CBZ-E and the degree of clinical improvement and side effects, whereas neither plasma CBZ nor CBZ-D levels were correlated with the degree of clinical improvement or side effects. Copyright 2000 John Wiley & Sons, Ltd.

Sensitive determination of carnosine in urine by high-performance liquid chromatography using 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride as a fluorescent labeling reagent.

A simple and highly sensitive high-performance liquid chromatography procedure was developed for the determination of carnosine in urine. Carnosine was derivatized with 4-(5,6-dimethoxy-2-phthalimidinyl)-2-methoxyphenylsulfonyl chloride at 70 degrees C for 15 min in borate buffer (20 mmol l(-1), pH 9.0) to produce fluorescent sulfonamides. After hydrolysis of the reaction mixture with formic acid at 100 degrees C for 15 min, the fluorescent derivative of carnosine was separated on a reversed-phase column with a linear gradient elution using solvents of (A) acetate buffer (0.1 mmol l(-1), pH 7.0) and (B) acetonitrile at a flow-rate of 1.0 ml/min and was detected at excitation and emission wavelengths of 318 and 400 nm, respectively. The detection limit of carnosine was 4 fmol at a signal-to-noise ratio of 3. The within-day and day-to-day relative standard deviations were 2.7-4.6% and 0.4-5.2%, respectively. The concentration of carnosine in normal human urine was found to be 4.6-125 nmol (mg creatinine)(-1) (mean+/-SD: 21.6+/-26.6 nmol (mg creatinine)(-1), n=20).

Interaction between fluvoxamine and cotinine or caffeine.

We examined the relationships between plasma fluvoxamine concentrations and plasma levels of cotinine and caffeine, respectively, under steady-state conditions in 30 patients who met DSM-IV criteria for a major depressive disorder and who were being treated with fluvoxamine. The daily dosages of fluvoxamine ranged from 50 to 200 mg (mean +/- SD 108 +/- 42 mg). Eleven patients were smokers and the remaining 19 were nonsmokers. The plasma fluvoxamine concentrations were significantly higher in nonsmokers (0.92 +/- 0.40 ng/ml/mg) than in smokers (0.56 +/- 0.28 ng/ml/mg); in addition, a trend towards negative correlations was observed between the plasma fluvoxamine concentrations and the plasma cotinine levels, although it was not significant. Significant positive correlations were found between the plasma fluvoxamine concentrations and the plasma caffeine levels. These findings are compatible with those in earlier reports that cytochrome P450 1A2 plays a major role in fluvoxamine metabolism.