Olopatadine ameliorates rat experimental cutaneous inflammation by improving skin barrier function.

Olopatadine hydrochloride (olopatadine) is an antiallergic agent with histamine H(1) receptor antagonistic action. We investigated the possible efficacies of olopatadine on the chronic inflammatory dermatitis and the impaired skin barrier functions induced by repeated application of oxazolone in rats. Oxazolone-sensitized rats were challenged with oxazolone applied to the ear every 3 days. Olopatadine was orally administered once daily (1 and 3 mg/kg/day). The effects of the drug were quantified by measurements of ear thickness, levels of cytokines in the lesioned ear and the number of scratching episodes. As parameters of skin barrier function, transepidermal water loss (TEWL) and hyaluronic acid (HA) levels in the lesioned ear were measured. The effect of olopatadine on the production of HA by cultured dermal fibroblasts was also measured. Repeated topical application of oxazolone to rat ears induced local inflammation that was exemplified by swelling. In inflamed ears, the amount of IFN gamma increased at both the protein and mRNA level, but IL-4 levels changed minimally. Olopatadine significantly decreased ear swelling and the number of scratching episodes. The drug also significantly inhibited the increase of IFN gamma and nerve growth factor production in inflamed ears. Olopatadine significantly inhibited the increase in TEWL and the decrease in HA in lesioned ears. Furthermore, the drug stimulated the production of HA by cultured dermal fibroblasts. These results suggest that olopatadine suppressed inflammation and scratching not only by inhibiting cytokine production, but also by repairing skin barrier function.

Is the monkey an appropriate animal model to examine drug-drug interactions involving renal clearance? Effect of probenecid on the renal elimination of H2 receptor antagonists.

The renal drug-drug interaction between famotidine (an H(2) receptor antagonist) and probenecid has not been reproduced in rats. We have proposed that this is caused by a species difference in the transport activity by human/rat organic anion transporter (OAT) 3 and the expression of organic cation transporter (OCT) 1 in the rodent kidney. Since monkey OATs (mkOATs) exhibit similar transport activities to human orthologs, it is hypothesized that in vivo studies in monkeys will allow a more precise prediction of renal drug-drug interactions in humans. Famotidine and cimetidine were efficiently taken up by mkOAT3-expressing human embryonic kidney cells (Km, 154 and 71 microM, respectively), and their uptake was strongly inhibited by probenecid (Ki, 3.0-5.7 microM). Quantification of mkOCT1 and mkOCT2 mRNAs in the monkey kidney using real-time reverse transcription-polymerase chain reaction revealed their predominant expression in the liver and kidney, respectively. Crossover studies were conducted in cynomolgus monkeys. Famotidine was given by i.v. administration, with or without probenecid. Probenecid treatment caused a 65% reduction in the renal clearance (0.426 +/- 0.079 versus 0.165 +/- 0.027 l/h/kg) and a 90% reduction in the tubular secretion clearance (0.275 +/- 0.075 versus 0.0230 +/- 0.0217 l/h/kg), whereas it had no effect on the renal clearance of cimetidine. In contrast to the species-dependent effect of probenecid, allometric scaling using animal data (rat, dog, and monkey) successfully predicted the renal and tubular secretion clearance of famotidine in humans. These results suggest that monkeys are more appropriate animal species for predicting the renal drug-drug interactions in humans.

CYP2D6.10 present in human liver microsomes shows low catalytic activity and thermal stability.

Comparing bufuralol 1'-hydroxylase activity among liver microsomes prepared from individuals whose CYP2D6 genotypes had been determined, we found that the activity tended to decrease depending on the number of the CYP2D6*10 allele. Pre-incubation of liver microsomes from individuals homozygous for the CYP2D6*10 allele resulted in a decrease in the enzyme activity more rapidly than those from individuals homozygous for the CYP2D6*1, suggesting that not only the catalytic activity but also the thermal stability of the enzyme appeared to be affected by the genetic polymorphism. To confirm this hypothesis, the kinetic parameters of CYP2D6.1 and CYP2D6.10 were compared for bufuralol 1'-hydroxylation and dextromethorphan O-demethylation using microsomes prepared from yeast transformed with plasmids carrying CYP2D6 cDNAs (*1A and *10B). Kinetic studies of these CYP2D6 forms indicated clear differences in the metabolic activities between the wild (CYP2D6.1) and the mutant enzymes (CYP2D6.10). Bufuralol 1(')-hydroxylase activity in microsomes of yeast expressing CYP2D6.10 was rapidly decreased by heat treatment, supporting the idea that the thermal stability of the enzyme was reduced by amino acid replacement from Pro (CYP2D6.1) to Ser (CYP2D6.10). These data strongly suggest that the thermal instability together with the reduced intrinsic clearance of CYP2D6.10 is one of the causes responsible for the known fact that Orientals show lower metabolic activities than Caucasians for drugs metabolized mainly by CYP2D6, because of a high frequency of CYP2D6*10 in Orientals.