Cox E H, Kerbusch T, Van der Graaf P H, Danhof M
Leiden/Amsterdam Center for Drug Research, Division of Pharmacology, University of Leiden, Sylvius Laboratory, The Netherlands.
J Pharmacol Exp Ther. 1998 Mar;284(3):1095-103.
The purpose of our investigation was to characterize the relationships between the pharmacodynamics of synthetic opioids in vivo and the interaction at the mu-opioid receptor. The pharmacokinetics and pharmacodynamics were determined in vivo after a single i.v. infusion of 3.14 mg/kg alfentanil (A), 0.15 mg/kg fentanyl (F) or 0.030 mg/kg sufentanil (S) in rats. Amplitudes in the 0.5 to 4.5 Hz frequency band of the electroencephalogram (EEG) was used as pharmacodynamic endpoint. The EEG effect intensity was related to the (free) concentration in blood (A) or in a hypothetical effect compartment (F, S) on basis of the sigmoidal Emax pharmacodynamic model. The interaction at the mu-opioid receptor was determined in vitro on basis of the displacement of [3H]-naloxone binding in washed rat brain membranes. The value of the sodium shift was used as a measure of in vitro intrinsic efficacy. For the EEG effect the in vivo potencies based on free drug concentrations (EC50,u) were 4.62 +/- 0.66 ng/ml (A), 0.69 +/- 0.05 ng/ml (F) and 0.29 +/- 0.06 ng/ml (S). In the receptor binding studies the affinities at the mu-opioid receptor (Kl) were 47.4 +/- 6.6 nM (A), 8.6 +/- 4.1 nM (F) and 2.8 +/- 0.2 nM (S). For each opioid the ratio between EC50,u and Kl was the same with a value of 0.23-0.25, indicating the existence of receptor reserve for the EEG effect. The intrinsic activity (Emax) of the three opioids in vivo was similar with values of 111 +/- 10 microV (A), 89 +/- 11 microV (F) and 104 +/- 4 microV (S). However, the values of the sodium shift varied between 2.8 (S) and 19.1 (A). Further analysis of the in vivo pharmacodynamic data on basis of an operational model of agonism provided evidence for a large receptor reserve, which explains why compounds with different values of the sodium shift all behave as full agonists in vivo.
我们研究的目的是描述合成阿片类药物在体内的药效学与μ-阿片受体相互作用之间的关系。在大鼠单次静脉输注3.14mg/kg阿芬太尼(A)、0.15mg/kg芬太尼(F)或0.030mg/kg舒芬太尼(S)后,测定其药代动力学和药效学。脑电图(EEG)0.5至4.5Hz频段的振幅用作药效学终点。根据S形Emax药效学模型,EEG效应强度与血液中(游离)浓度(A)或假设效应室中(F、S)的浓度相关。基于[3H]-纳洛酮在洗涤大鼠脑膜中的结合位移,在体外测定μ-阿片受体的相互作用。钠移位值用作体外内在效能的指标。对于EEG效应,基于游离药物浓度(EC50,u)的体内效价分别为4.62±0.66ng/ml(A)、0.69±0.05ng/ml(F)和0.29±0.06ng/ml(S)。在受体结合研究中,μ-阿片受体(Kl)的亲和力分别为47.4±6.6nM(A)、8.6±4.1nM(F)和2.8±0.2nM(S)。对于每种阿片类药物,EC50,u与Kl的比值相同,为0.23 - 0.25,表明存在EEG效应的受体储备。三种阿片类药物在体内的内在活性(Emax)相似,分别为111±10μV(A)、89±11μV(F)和104±4μV(S)。然而,钠移位值在2.8(S)和19.1(A)之间变化。基于激动作用的操作模型对体内药效学数据的进一步分析提供了存在大量受体储备的证据,这解释了为什么钠移位值不同的化合物在体内均表现为完全激动剂。
