Lötsch Jörn, Skarke Carsten, Wieting Johannes, Oertel Bruno Georg, Schmidt Helmut, Brockmöller Jürgen, Geisslinger Gerd
Pharmazentrum frankfurt/ZAFES, Institute of Clinical Pharmacology, Johann Wolfgang Goethe-University, Frankfurt am Main, Germany.
Clin Pharmacol Ther. 2006 Jan;79(1):72-89. doi: 10.1016/j.clpt.2005.09.010.
Our aim was to judge the importance of candidate pharmacogenetic modulators of the central nervous effects of levomethadone by both magnitude of the modulatory effect and frequency of the mutation to assess the utility of genotyping for clinical levomethadone therapy in a random sample of subjects that, by distribution of genotypes, resembled the clinical setting.
Candidate pharmacogenetic modulators were polymorphisms reported to be of functional consequence and therefore potentially important for metabolism, distribution, or pharmacodynamic action of levomethadone, consisting of genes coding for cytochrome P450 (CYP) 2B6 and 3A, as well as 1A2, 2C8, 2C9, 2C19, and 2D6, for P-glycoprotein (ABCB1), and for mu-opioid receptors (OPRM1). The central nervous effects of levomethadone were investigated by means of measuring pupil size in a random sample of 51 healthy volunteers for 9 hours after oral administration of 0.075 mg/kg levomethadone. Plasma concentrations of levomethadone and its metabolites were assessed concomitantly, and to judge the role of metabolites, the affinities of levomethadone and its metabolites at mu-opioid receptors were estimated by use of displacement of the selective mu-opioid receptor agonist [(3)H]-DAMGO ((3)H-[D-Ala(2),N-MePhe(4),Gly-ol(5)]-enkephalin).
Pupil size decreased to -41.8% +/- 9.6% from baseline at 3.5 +/- 1.1 hours after levomethadone administration. Miosis was still manifest to a lower degree (-25.1% +/- 12.3%) at the end of the observation period. In carriers of the variant 118G allele (118A>G single-nucleotide polymorphism) of the mu-opioid receptor gene (OPRM1), levomethadone had a 1.74 times (95% confidence interval, 1.4-2.2 times) lower miotic potency (P < .001) as compared with noncarriers (concentration at half-maximum effects, 52.3 nmol/L; 95% confidence interval, 36.7-66.2 nmol/L). The maximum percent decrease in pupil diameter from baseline was 44.9% +/- 7.6%, 33% +/- 6.5%, and 24% +/- 6.9% for carriers of the OPRM1 118AA, AG, and GG genotypes, respectively (P < .001 for AG and GG versus wild type, without significant differences between AG and GG). Other candidate polymorphisms in the ABCB1 or in CYP genes had no significant influence on the effects of levomethadone, either because of lack of functional consequences or because of their low allelic frequency. The metabolites of levomethadone did not contribute to the effects as indicated by low metabolite plasma concentrations and their 120- to 1300-fold lower affinities at mu-opioid receptors as compared with levomethadone.
Among polymorphisms in OPRM1, ABCB1, and CYP genes previously associated with functional consequences in a different context, the most important pharmacogenetic factor modulating the short-term effects of levomethadone is a polymorphism (OPRM1 118A>G) affecting mu-opioid receptors.
我们的目的是通过调节效应的大小和突变频率来判断左美沙酮中枢神经效应的候选药物遗传学调节因子的重要性,以评估基因分型在左美沙酮临床治疗中的效用,研究对象为一个随机样本,其基因型分布类似于临床情况。
候选药物遗传学调节因子是据报道具有功能影响、因此可能对左美沙酮的代谢、分布或药效学作用具有重要意义的多态性,包括编码细胞色素P450(CYP)2B6、3A以及1A2、2C8、2C9、2C19和2D6的基因,P-糖蛋白(ABCB1)基因,以及μ-阿片受体(OPRM1)基因。通过在51名健康志愿者的随机样本中口服0.075 mg/kg左美沙酮后9小时测量瞳孔大小,研究左美沙酮的中枢神经效应。同时评估左美沙酮及其代谢物的血浆浓度,为判断代谢物的作用,通过选择性μ-阿片受体激动剂[(3)H]-DAMGO((3)H-[D-Ala(2),N-MePhe(4),Gly-ol(5)]-脑啡肽)的置换来估计左美沙酮及其代谢物对μ-阿片受体的亲和力。
左美沙酮给药后3.5±1.1小时,瞳孔大小从基线下降至-41.8%±9.6%。在观察期结束时,瞳孔缩小仍有较低程度的表现(-25.1%±12.3%)。与非携带者相比,μ-阿片受体基因(OPRM1)118G等位基因变异(118A>G单核苷酸多态性)的携带者中,左美沙酮的缩瞳效力降低了1.74倍(95%置信区间,1.4 - 2.2倍)(P <.001)(半数最大效应浓度为52.3 nmol/L;95%置信区间,36.7 - 66.2 nmol/L)。OPRM1 118AA、AG和GG基因型的携带者,瞳孔直径相对于基线的最大百分比下降分别为44.9%±7.6%、33%±6.5%和24%±6.9%(AG和GG与野生型相比P <.001,AG和GG之间无显著差异)。ABCB1或CYP基因中的其他候选多态性对左美沙酮的效应没有显著影响,要么是因为缺乏功能影响,要么是因为它们的等位基因频率较低。左美沙酮的代谢物对效应没有贡献,这表现为代谢物血浆浓度较低,且与左美沙酮相比,它们对μ-阿片受体的亲和力低120至1300倍。
在先前在不同背景下与功能影响相关的OPRM1、ABCB1和CYP基因的多态性中,调节左美沙酮短期效应的最重要药物遗传学因素是影响μ-阿片受体的一种多态性(OPRM1 118A>G)。
