On-site catalytic determination of trace manganese in fresh water using oxidation of malachite green with periodate.

An on-site determination method for trace manganese has been developed using the manganese-catalyzed oxidation of Malachite Green (MG) with potassium periodate. Absorbance measurement of MG was carried out using a laboratory-made palm-top size colorimeter with a red-green-blue light-emitting diode. The reciprocal value (1/τ) of the reaction time at a fixed absorbance value for red light was chosen as a kinetic parameter for simple on-site analyses. The value of 1/τ was proportional to the concentration of manganese in the range of 2 - 20 µg L(-1). At a reaction temperature (T) of 20°C or more, manganese was determined within a reaction time of 25 min. The calibration equation was approximated by 1/τ = (aT + b)[Mn] + (cT + d), where a to d were constants in a range of 10 - 40°C. The two equations for 30°C (for the laboratory-preparation of the calibration equation) and T give the value of 1/τ at 30°C as 1/τ(f) = (30a + b)(1/τ - cT - d)/(aT + b) + 30c + d. Without any temperature control, 1/τ(f) can be calculated by this equation and measurements of 1/τ and T. The calculation introduced analytical errors of within 1 µg L(-1). The proposed method was successfully applied to tap-, river- and lake-water samples.

Transporter-mediated influx and efflux mechanisms of pitavastatin, a new inhibitor of HMG-CoA reductase.

The purpose of this study was to gain a better understanding of the transport mechanism of pitavastatin, a novel synthetic HMG-CoA reductase inhibitor. Experiments were performed using oocytes of Xenopus laevis expressing several solute carrier (SLC) transporters and recombinant membrane vesicles expressing several human ABC transporters. The acid form of pitavastatin was shown to be a substrate for human OATP1, OATP2, OATP8, OAT3 and NTCP, and for rat Oatp1 and Oatp4 with relatively low K(m) values. In contrast, these SLC transporters were not involved in the uptake of the lactone form. A significant stimulatory effect was exhibited by pitavastatin lactone, while the acid form did not exhibit ATPase hydrolysis of P-glycoprotein. In the case of breast cancer resistant protein (BCRP), the acid form of pitavastatin is a substrate, whereas the lactone form is not. Taking these results into consideration, several SLC and ABC transporters were identified as critical to the distribution and excretion of pitavastatin in the body. This study showed, for the first time, that acid and lactone forms of pitavastatin differ in substrate activity towards uptake and efflux transporters. These results will potentially contribute to the differences in the pharmacokinetic profiles of pitavastatin.

Metabolic stability and uptake by human hepatocytes of pitavastatin, a new inhibitor of HMG-CoA reductase.

To gain a better understanding of the metabolic stability and transport of pitavastatin (CAS 147526-32-7), a new and potent 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor, experiments were conducted using human hepatocytes and oocytes of Xenopus laevis expressing human organic anion transporting polypeptide-2 (OATP2), respectively. Almost the entire radioactivity was from the unchanged substance or lactone form in human hepatocytes, and the cytochrome P450 (CYP)-mediated metabolism of pitavastatin was negligible. The results suggested that CYPs are not critically involved in determining the metabolic fate of pitavastatin. The hepatic uptake of pitavastatin reached saturation with a Km of 2.99 +/- 0.79 micromol/L. Also, the uptake of pitavastatin was mediated by OATP2 expressed in oocytes with a Km of 5.53 +/- 1.70 micromol/L. These results indicated that OATP2 plays a major role in the distribution of pitavastatin in liver. Furthermore, to elucidate the increase in the plasma concentration of pitavastatin in a clinical setting, the inhibitory effect of ciclosporin (cyclosporin A, CAS 59865-13-3) on the uptake of pitavastatin was examined. The uptake of pitavastatin was inhibited in the presence of cyclosporin A and the apparent IC50 value was 2.91 +/- 0.78 micromol/L. This result may at least partly explain the drug-drug interaction between pitavastatin and cyclosporin A. In conclusion, the characterization of transporters needs to be taken into account to avoid transporter-mediated drug-drug interaction.

Effect of gemfibrozil on the metabolism of pitavastatin--determining the best animal model for human CYP and UGT activities.

A series of studies was conducted to determine the best animal model for human CYP and UGT activities. The investigation focused primarily on the interactions occurring in the CYP- or UGT-mediated metabolism of pitavastatin, and involved in vitro and in vivo experiments. We found that the best animal models for human CYP-mediated hydroxylation and UGT-mediated lactonization of pitavastatin were rats and dogs, respectively. In addition, a large difference in the metabolic properties of pitavastatin was found between monkeys and humans. In the presence of gemfibrozil, the CYP- or UGT-mediated metabolism of pitavastatin was inhibited in vitro. However, gemfibrozil treatment had no inhibitory effect on the AUC of pitavastatin and its lactone form in rats and dogs. We conclude that the plasma level of pitavastatin would not be increased by co-administration of gemfibrozil in humans.

Interaction between fibrates and statins--metabolic interactions with gemfibrozil.

An in vitro study was carried out in order to examine the metabolic basis of the interaction between fibrates and statins. Metabolic inhibition of statins was noted in the presence of gemfibrozil. However, increase in the unchanged form was fairly small for pitavastatin, compared with other statins. Several CYP enzymes were shown to be principally responsible for the metabolism of gemfibrozil in contrast to other fibrates. In the presence of gemfibrozil, a focal point was obtained in Dixon plots, demonstrating that there was inhibition of CYP2C8-, CYP2C9- and CYP3A4-mediated metabolism. We propose that the increase of plasma concentration caused by co-administration of gemfibrozil and statins is at least partially due to CYP-mediated inhibition.

Studies on the interaction between fibrates and statins using human hepatic microsomes.

To gain a better understanding of the mechanism of drug-drug interaction between fibrates and statins, several in vitro experiments were performed. On coincubation with several fibrates, pitavastatin (CAS 147526-32-7) did not displace fibrates from their protein binding in human plasma. The presence of gemfibrozil (CAS 25812-30-0) inhibited the metabolism of statins (cerivastatin (CAS 145599-86-6) and atorvastatin (CAS 134523-00-5)) remarkably. However, the increase of the unchanged form was fairly small for pitavastatin. The metabolic profile of gemfibrozil was also investigated. The cytochrome P (CYP) enzyme CYP2C9 plays a major role in the metabolism of gemfibrozil. Gemfibrozil showed a high affinity for CYP enzymes and a relatively high metabolism velocity. Moreover, several inhibitory effects of gemfibrozil on CYP-mediated metabolism were detected--in contrast to other fibrates. Although the mechanism of the drug-drug interaction was not completely clarified, it is suggested that the increase of plasma concentration caused by the co-administration of gemfibrozil and statins is at least partially due to the inhibition of the CYP-mediated metabolism.

Interaction between several medicines and statins.

To gain a better understanding of drug-drug interaction between various medicinal substances and statins, in vitro experiments using human hepatic microsomes were performed. The metabolic clearance of atorvastatin (CAS 134523-00-5) was about 32 microliters/min/mg protein, some 15-fold greater than that of pitavastatin (CAS 147526-32-7). On co-incubation with several medicinal substances, metabolic inhibition of pitavastatin was negligible in human hepatic microsomes. However, a remarkable metabolic inhibition of atorvastatin was noted in the presence of various medicinal substances. The intrinsic clearance of atorvastatin lactone was 20-fold greater than that of its acid form, whereas no marked difference was noted between pitavastatin and its lactone form. Pitavastatin lactone showed no inhibitory effect on CYP3A4-mediated metabolism of testosterone in contrast to atorvastatin lactone. These results suggest that pitavastatin and its lactone form will be highly unlikely to interact with other drugs in clinical practice.

Uptake mechanism of pitavastatin, a new inhibitor of HMG-CoA reductase, in rat hepatocytes.

To understand the mechanism underlying the highly liver-selective distribution of pitavastatin, uptake experiments were performed using rat hepatocytes. The uptake of pitavastatin into rat hepatocytes is carrier-mediated and involved nonspecific diffusion in the presence of Na(+). The michaelis constant (K(m)) was 26.0 micromol/L, maximal uptake velocity (V(max)) was 3124 pmol/min/mg protein, and non-specific uptake (P(dif)) was 1.16 microL/min/mg protein. There were no remarkable differences in these kinetic parameters between the presence and absence of Na(+). Experiments using metabolic inhibitors revealed that energy-dependent systems contribute to the uptake of pitavastatin in the liver. Some organic anions reduced the uptake into rat hepatocytes in a concentration-dependent manner. The observed rates of inhibition of pitavastatin uptake by BSP, TCA and pravastatin were compared with the predicted rates. The predicted values were calculated, assuming that BSP, TCA and pravastatin inhibit the uptake of pitavastatin in a competitive manner. The observed inhibition by BSP and TCA was similar to that predicted, but the observed inhibition by pravastatin was considerably less than that predicted. In conclusion, most of the pitavastatin taken up into the liver is transported by multiple carrier-mediated transporters such as Na(+)-independent multispecific anion transporters and energy-dependent transporters. In addition, these systems for pitavastatin may have features in common with the BSP and TCA transport system, and may partially involve the pravastatin transport system.

Metabolic fate of pitavastatin, a new inhibitor of HMG-CoA reductase--effect of cMOAT deficiency on hepatobiliary excretion in rats and of mdr1a/b gene disruption on tissue distribution in mice.

Pitavastatin is a potent competitive inhibitor of HMG-CoA reductase. In the current study, to elucidate the hepatobiliary excretion of pitavastatin, we investigated the plasma concentration and biliary excretion of (14)C-pitavastatin in EHBR. We also evaluated the distribution of pitavastatin in mdr1a/b knockout mice by whole body autoradiography and quantitative radioassay. In view of the widespread clinical use of pitavastatin and the importance of drug-drug interaction, the inhibitory effect on Pgp-mediated activation of ATPase was also investigated. No marked difference was observed in the plasma concentration and biliary excretion of radioactivity between SDR and EHBR after dosing of (14)C-pitavastatin. Little radioactive transfer into the brain was detected in mdr1a/b knockout mice and the ATPase activity of human Pgp was negligible in the presence of pitavastatin. Moreover, no inhibitory effect on the Pgp-mediated activation of ATPase by verapamil was found in the presence of pitavastatin over a wide concentration range. These results indicated that a cMOAT and Pgp-mediated transport mechanism did not play a major role in the distribution of pitavastatin.