Yasuyoshi Ishiwata

Gatifloxacin-induced histamine release and hyperglycemia in rats

Gatifloxacin, a fluoroquinolone antimicrobial agent, has been reported to cause both hypoglycemia and hyperglycemia in diabetic and non-diabetic patients. The purpose of the present study was to investigate the mechanism of gatifloxacin-induced hyperglycemia in normal and diabetic rats. Rats received a single intravenous injection of gatifloxacin and samples of their arterial blood were collected periodically. Diabetic rats were produced by the injection of streptozotocin and nicotinamide. In normal rats, the concentration of serum glucose decreased after the injection of gatifloxacin at 50mg/kg, while it increased with gatifloxacin at 100mg/kg. The concentrations of serum epinephrine and histamine increased after the injection of gatifloxacin at 100mg/kg. The increases in serum glucose and epinephrine concentrations were reduced by pretreatment with diphenhydramine at 1mg/kg. In diabetic rats, the concentration of serum glucose actually increased after the injection of gatifloxacin at 50mg/kg, concomitant with increases in the serum epinephrine and histamine concentrations. The concentration of serum immunoreactive insulin slightly increased after the injection of gatifloxacin at 50mg/kg. In addition, repeated oral administration of gatifloxacin to rats at 300 mg/kg twice a day for 7 days did not change glucose tolerance. In conclusion, gatifloxacin-induced release of histamine can contribute to an increase in the serum epinephrine concentration and hyperglycemia in normal rats. In diabetic rats, lower doses of gatifloxacin can induce hyperglycemia owing to the low level of insulin secretion that they exhibit compared with normal animals.

Pharmacokinetic–Pharmacodynamic Analysis of Sunitinib-Induced Thrombocytopenia in Japanese Patients with Renal Cell Carcinoma

The aim of the present study was to clarify the therapeutic range and adequate dose of sunitinib in Japanese renal cell carcinoma patients by means of a pharmacokinetic-pharmacodynamic analysis of sunitinib-induced thrombocytopenia. Six patients with renal cell carcinoma were enrolled in this study. After starting the sunitinib treatment, between three and seven blood samples were obtained from each patient just before the administration of sunitinib. Serum concentrations of sunitinib and its active metabolite N-desethyl-sunitinib were fit to the 1-compartment model with first-order absorption. Changes in platelet counts were fit to the pharmacokinetic-pharmacodynamic model, in which the proliferation of platelet progenitor cells was assumed to be linearly inhibited by sunitinib and its metabolite. All patients using 50 mg as an initial dose of sunitinib developed grade 2 or 3 thrombocytopenia. The pharmacokinetic-pharmacodynamic model created successfully described the time course of sunitinib-induced thrombocytopenia and could predict changes in platelet counts after alterations to the dosage of sunitinib administered. The simulation results indicated that the total trough level of sunitinib to avoid severe thrombocytopenia should be <100 ng/mL, and also that the initial daily dose of sunitinib could be reduced to 37.5 mg or 25 mg in most Japanese patients. In addition to the pharmacokinetic-guided dosage adjustment, the careful monitoring of platelet counts is required for the safe use of sunitinib.

Mechanism Underlying Induction of Hyperglycemia in Rats by Single Administration of Olanzapine

Acute administration of olanzapine rapidly elevates blood glucose levels. However, the mechanism underlying the rapid development of hyperglycemia with the administration of olanzapine remains unclear. The aim of the present study was to clarify the mechanism underlying olanzapine-induced acute hyperglycemia. Male Wistar rats received an intravenous infusion of saline (control) or olanzapine 2.5, 5, or 10 mg/kg. Blood samples were obtained periodically after olanzapine infusion to determine serum concentrations of glucose, olanzapine, and several endogenous substances. In a separate experiment, rats received an intravenous injection of propranolol (2 mg/kg) 30 min before infusion of olanzapine (10 mg/kg). The intravenous infusion of olanzapine induced dose-dependent increases in the serum concentrations of glucose, epinephrine, and insulin. Pretreatment with propranolol suppressed olanzapine-induced elevations in the serum concentration of glucose, but did not affect the serum concentration of olanzapine or olanzapine-induced increase in the serum concentration of epinephrine. Although the serum concentration of corticosterone increased after administration of olanzapine, no significant differences were observed among the olanzapine dose groups. Furthermore, administration of olanzapine did not affect the serum concentration of glucagon or histamine. We developed a pharmacokinetic-pharmacodynamic model assuming that the olanzapine-induced secretion of epinephrine leads to elevated serum glucose concentrations. This model appeared to satisfactorily characterize olanzapine-induced hyperglycemia. In conclusion, a single intravenous dose of olanzapine dose-dependently increased the serum concentration of glucose in rats, and epinephrine plays a role in olanzapine-induced acute hyperglycemia.

Pharmacodynamics of Cibenzoline-Induced Hypoglycemia in Rats

Hypoglycemia is one of the serious adverse effects induced by cibenzoline (CBZ), an antiarrhythmic agent. In order to clarify the pharmacodynamics of CBZ-induced hypoglycemia, CBZ was administered intravenously to conscious rats at a dose of 5, 10 or 20 mg/kg and serum samples were collected periodically to determine the concentrations of CBZ, insulin and glucose. The pharmacokinetics of CBZ showed nonlinear characteristics and could be described by a two-compartment model with Michaelis-Menten elimination kinetics. CBZ induced a rapid increase in the serum concentration of insulin. As the CBZ dose was increased, a greater hypoglycemic effect occurred. The indirect response model was applied to account for the CBZ-induced increase in insulin secretion and the subsequent decrease in serum glucose. A linear relationship was assumed between the serum concentration of CBZ and its stimulating effect on insulin secretion. A nonlinear relationship was assumed between the serum concentration of insulin and its stimulating effect on the elimination of serum glucose. The time courses of serum concentrations of CBZ, insulin and glucose after intravenous injection of CBZ could be described by the pharmacokinetic and pharmacodynamic model developed. This approach will be useful for the identification of variable factors related to CBZ-induced hypoglycemia.

Population Pharmacokinetics of Intravenous Busulfan in Japanese Pediatric Patients With Primary Immunodeficiency Diseases

Primary immunodeficiencies (PIDs) are genetic disorders in which part of the immune system is missing or does not function normally.1 Severe combined immunodeficiency is the most severe form of PID and is a rare genetic disorder characterized by the disturbed development of functional T cells and B cells caused by numerous genetic mutations that result in heterogeneous clinical presentation.2 In addition to severe combined immunodeficiency, WiskottAldrich syndrome,3 hyper-IgM syndrome,4 and severe congenital neutropenia5 were included with typical diseases that required reconstitution of the immune system. Hematopoietic stem cell transplantation (HSCT) is the standard therapy for patients with PIDs to reconstitute the poor or absent immune system.1,3–5 High-dose busulfan (BU) in combination with cyclophosphamide (CY) or melphalan, as well as reduced-intensity conditioning with BU and fludarabine (FLU) have been widely used as preconditioning regimens for HSCT.6 BU has a narrow therapeutic index; the target range of the area under the concentration-time curve (AUC) was set to a reduced-intensity protocol for patients with PIDs in the guidelines by the European Group for Blood and Marrow Transplantation (cumulative AUC for BU was set to 60 ± 5 μg·h/mL).7 In addition, the pharmacokinetics of intravenous BU has high interpatient variability.8 Therefore, dose individualization using therapeutic drug monitoring should be implemented. It is essential to clarify the pharmacokinetic characteristics of BU in the target patient populations. Many population pharmacokinetic approaches in pediatric patients have been reported for both oral9,10 and intravenous BU,11–13 but most analyses were conducted in patients with blood tumors. In the present study we focused on PIDs and developed a population pharmacokinetic model of BU in Japanese pediatric patients with PIDs.

Effects of Miconazole Oral Gel on Blood Concentrations of Tacrolimus and Cyclosporine: A Retrospective Observational Study.

Background: Although azole antifungal agents have been shown to affect the pharmacokinetics of calcineurin inhibitors such as tacrolimus (TAC) and cyclosporine (CyA) by inhibiting drug metabolism, there are few clinical reports on drug interactions between miconazole (MCZ) oral gel and calcineurin inhibitors. In this study, the effects of MCZ oral gel on the blood concentrations of TAC and CyA were investigated. Methods: In this retrospective study, 18 patients concomitantly administered MCZ oral gel and TAC (9 for dermatomyositis, 3 for myasthenia gravis, 2 for systemic lupus erythematosus, 2 for rheumatoid arthritis, 1 for polymyositis, 1 for prevention of graft-versus-host disease after bone marrow transplantation), and 15 patients concomitantly administered MCZ oral gel and CyA (11 for interstitial pneumonia, 2 for pemphigus, 1 for eosinophilic granulomatosis with polyangiitis, 1 for systemic lupus erythematosus) were evaluated. The dose-adjusted blood concentrations of TAC or CyA were compared before and after the initiation of MCZ oral gel. Results: The trough blood concentration/dose (C/D) ratios of TAC and CyA increased significantly with the administration of MCZ oral gel. The median C/D ratios of TAC and CyA increased by 108% (range: –44% to 216%) and 44% (range: −34% to 195%), respectively. Conclusions: These results suggest that MCZ oral gel affects the pharmacokinetics of TAC and CyA. Detailed monitoring of the blood concentrations of these drugs, followed by dose adjustments, is needed for each patient because of the difficulties associated with accurately predicting the degree of the effects of MCZ oral gel.

Haploidentical Bone Marrow Transplantation With Clofarabine and Busulfan Conditioning for a Child With Multiple Recurrent Acute Lymphoblastic Leukemia.

Outcome of children with acute lymphoblastic leukemia (ALL) has improved over the years, but not for those with multiple recurrences because of high therapy resistance and heavily pretreated history that potentially cause physical damages. We describe the case of an 11-year-old boy with a third relapse of ALL and a history of 2 allogeneic bone marrow transplantations. He was successfully treated with clofarabine combination chemotherapy and achieved a fourth remission at 16 months following haploidentical bone marrow transplantation with conditioning regimen of clofarabine and busulfan. Clofarabine/busulfan conditioning might be a preferable option for children with multiple recurrent ALL, and warrants further investigation.

Effect of cimetidine on pentamidine induced hyperglycemia in rats.

The antiprotozoal agent pentamidine, used for the treatment of Pneumocystis jirovecii pneumonia (PCP), is known to cause abnormalities in blood glucose homeostasis, such as hypoglycemia and hyperglycemia. Pentamidine has been reported to be a substrate of organic cation transporter 1 (OCT1). We investigated the combination effects of cimetidine, an OCT1 inhibitor, on the pharmacokinetics of pentamidine and on pentamidine-induced hyperglycemia. Pentamidine was infused intravenously to rats for 20 min at a dose of 7.5 or 15 mg/kg and serum samples were obtained periodically. The serum concentration of glucose did not change significantly after pentamidine infusion at 7.5mg/kg, while it increased with pentamidine at 15 mg/kg, and the maximal concentration of glucose was 167 ± 36 mg/dl, 30 min after the start of pentamidine infusion. Cimetidine (50mg/kg) enhanced the pentamidine-induced elevation of glucose concentration and the maximal concentration of glucose was 208 ± 33 mg/dl in the pentamidine 15 mg/kg treated group. Cimetidine combination significantly reduced total body clearance of pentamidine and increased pentamidine concentrations in the liver, kidneys, and lungs. A significant correlation was found between changes in serum glucose concentrations and serum concentrations of pentamidine 30 min after the start of pentamidine infusion. These results suggest that the hyperglycemic effect of pentamidine is dependent on the concentration of pentamidine and can be enhanced by cimetidine combination.

Clozapine-Induced Acute Hyperglycemia Is Accompanied with Elevated Serum Concentrations of Adrenaline and Glucagon in Rats

Clozapine, an atypical antipsychotic agent, has been reported to cause acute hyperglycemia. However, the mechanism of clozapine-induced rapidly developing hyperglycemia is not well elucidated. To clarify the mechanism underlying clozapine-induced acute hyperglycemia, we investigated the effects of single intravenous administration of clozapine on the serum concentrations of glucose and several endogenous substances in rats. Male Wistar rats received an intravenous injection of saline (control) or clozapine 2.5, 5, 10 mg/kg. Blood samples were obtained periodically after clozapine administration to determine the serum concentrations of glucose, adrenaline, glucagon, insulin, corticosterone, and clozapine. The serum concentrations of glucose, adrenaline, and glucagon increased dose-dependently after the administration of clozapine at 2.5-10 mg/kg, and reached maxima at 5 mg/kg of clozapine. The serum concentration of corticosterone increased after the administration of clozapine, but no significant variation was observed with the dosage of clozapine. The concentration of serum insulin increased in a dose-dependent manner after clozapine administration. In conclusion, a single administration of clozapine increased the serum concentration of glucose in rats, and adrenaline and/or glucagon would be associated with clozapine-induced acute hyperglycemia.