Herrlin Karin, Yasui-Furukori Norio, Tybring Gunnel, Widén Jolanta, Gustafsson Lars L, Bertilsson Leif
Division of Clinical Pharmacology at Department of Medicine Laboratory, Karolinska Institutet at Huddinge University Hospital, Huddinge, Sweden.
Br J Clin Pharmacol. 2003 Oct;56(4):415-21. doi: 10.1046/j.1365-2125.2003.01874.x.
To investigate pharmacokinetics of the enantiomers of citalopram (CT) and its metabolites desmethylcitalopram (DCT) and didesmethylcitalopram (DDCT) in Swedish healthy volunteers in relation to CYP2C19 and CYP2D6 geno- and phenotypes.
Racemic CT was given for seven days to panels with different genotypes and the following mephenytoin (Me) and debrisoquine (De) hydroxylation phenotypes: EMDe/EMMe, PMDe/EMMe, EMDe/PMMe (n = 6 in all groups), and one PMDe/PMMe subject. Blood sampling was carried out during day 7, and all urine was collected for 12 h after the last dose of CT.
The AUC of S-CT was significantly higher in the EMDe/PMMe panel compared to the EMDe/EMMe and PMDe/EMMe panels (P < 0.05), whereas the AUC of R-CT did not differ between the panels. Similar differences, although they did not reach statistical significance, were noted for S-DCT and R-DCT. The enantiomers of DDCT were not quantifiable in PMDe, and there was no difference in DDCT enantiomer concentrations between the other two panels. A PMDe/PMMe subject stopped taking CT after five days due to severe adverse effects. Based on two time points, this subject had a very long CT half-life of 95 h. The value of 1.0 for the S/R ratio of the CT trough in this subject was similar to the mean S/R CT trough ratio of the EMDe/PMMe panel, but higher than the S/R CT ratio of the EMDe/EMMe panel (0.56; 95% CI 0.49-0.63) and the PMDe/EMMe panel (0.44; 95% CI 0.31-0.57). Thus the latter two phenotypes eliminated S-CT more rapidly via CYP2C19. An adverse effect described as an 'alcohol hangover' feeling was reported by one subject from each of the three panels. These individuals had the highest concentrations of both CT enantiomers.
The AUC of S-, but not R-(CT) was found to be significantly higher in PM of mephenytoin compared to EMs, PMs may need a lower dosage of CT.
研究西酞普兰(CT)对映体及其代谢产物去甲基西酞普兰(DCT)和双去甲基西酞普兰(DDCT)在瑞典健康志愿者体内的药代动力学,以及与CYP2C19和CYP2D6基因和表型的关系。
将消旋CT给予具有不同基因型以及以下美芬妥英(Me)和异喹胍(De)羟化表型的受试者组:快代谢De/快代谢Me、慢代谢De/快代谢Me、快代谢De/慢代谢Me(所有组n = 6),以及一名慢代谢De/慢代谢Me受试者。在第7天进行血样采集,并在最后一剂CT后12小时收集所有尿液。
与快代谢De/快代谢Me组和慢代谢De/快代谢Me组相比,快代谢De/慢代谢Me组中S-CT的AUC显著更高(P < 0.05),而R-CT的AUC在各受试者组之间无差异。S-DCT和R-DCT也有类似差异,尽管未达到统计学显著性。DDCT的对映体在慢代谢De受试者中无法定量,另外两组之间DDCT对映体浓度无差异。一名慢代谢De/慢代谢Me受试者因严重不良反应在五天后停止服用CT。基于两个时间点,该受试者的CT半衰期极长,为95小时。该受试者CT谷浓度的S/R比值为1.0,与快代谢De/慢代谢Me组的S/R CT谷浓度平均比值相似,但高于快代谢De/快代谢Me组(0.56;95%CI 0.49 - 0.63)和慢代谢De/快代谢Me组(0.44;95%CI 0.31 - 0.57)。因此,后两种表型通过CYP2C19更快地消除S-CT。三个受试者组中各有一名受试者报告有一种被描述为“宿醉”感的不良反应。这些个体的两种CT对映体浓度均最高。
与快代谢者相比,美芬妥英慢代谢者中S-(而非R-)CT的AUC显著更高,慢代谢者可能需要较低剂量的CT。
