Emery M G, Jubert C, Thummel K E, Kharasch E D
Department of Pharmaceutics, Anesthesiology Service, Puget Sound Veterans Affairs Medical Center, Seattle, Washington, USA.
J Pharmacol Exp Ther. 1999 Oct;291(1):213-9.
Disulfiram (DSF) is a mechanism-based inhibitor of cytochrome P-450 2E1 (CYP2E1), resulting in loss of CYP2E1 protein and activity, which may be useful in preventing CYP2E1-mediated xenobiotic toxicity. The duration of inhibition after a single DSF dose is, however, unknown. The purpose of this investigation was to determine this duration, and CYP2E1 formation and degradation rates, in humans. Oral chlorzoxazone (CLZ) was used as the selective in vivo probe for CYP2E1. Healthy subjects received CLZ to determine baseline CYP2E1 activity (CLZ plasma clearance and 6-hydroxychlorzoxazone fractional metabolic clearance). One week later, DSF (500 mg orally) was administered at bedtime, and CLZ administered the following morning and 3, 6, 8, 10, and 13 days after DSF. A terminal DSF metabolite, 2-thiothiazolidine-4 carboxylic acid, was also measured in each 24-h urine sample. The mean CLZ clearance and 6-hydroxychlorzoxazone fractional metabolic clearance on the first day declined to 10.2 and 5.5% of baseline values, indicating rapid and profound CYP2E1 inhibition. CYP2E1 activity returned to half that of control on day 3, and to baseline values on day 8. Assuming zero-order synthesis and first-order degradation, the in vivo CYP2E1 synthesis rate and degradation half-life was estimated to be 11 +/- 5 nmol/h and 50 +/- 19 h, respectively. Significant amounts of 2-thiothiazolidine-4 carboxylic acid were present only on day 1, suggesting that the return of in vivo CYP2E1 activity was not caused by inhibitor washout, but by enzyme resynthesis. Results regarding CYP2E1 disposition may be useful for modeling the effects of CYP2E1 inducers and inhibitors. For prevention of CYP2E1-mediated bioactivation, depending on protoxicant disposition, a second DSF dose might be necessary to completely prevent toxicity.
双硫仑(DSF)是一种基于机制的细胞色素P-450 2E1(CYP2E1)抑制剂,可导致CYP2E1蛋白和活性丧失,这可能有助于预防CYP2E1介导的外源性物质毒性。然而,单次服用DSF后的抑制持续时间尚不清楚。本研究的目的是确定人类体内的这种持续时间以及CYP2E1的生成和降解速率。口服氯唑沙宗(CLZ)被用作CYP2E1的选择性体内探针。健康受试者服用CLZ以确定基线CYP2E1活性(CLZ血浆清除率和6-羟基氯唑沙宗分数代谢清除率)。一周后,于睡前口服DSF(500 mg),并于次日早晨以及DSF给药后的第3、6、8、10和13天给予CLZ。在每份24小时尿液样本中还检测了一种终末DSF代谢产物,即2-硫代噻唑烷-4-羧酸。第一天的平均CLZ清除率和6-羟基氯唑沙宗分数代谢清除率分别降至基线值的10.2%和5.5%,表明CYP2E1受到快速且显著的抑制。CYP2E1活性在第3天降至对照值的一半,并在第8天恢复到基线值。假设为零级合成和一级降解,体内CYP2E1的合成速率和降解半衰期估计分别为11±5 nmol/h和50±19 h。仅在第1天检测到大量的2-硫代噻唑烷-4-羧酸,这表明体内CYP2E1活性的恢复不是由抑制剂清除引起的,而是由酶的重新合成所致。关于CYP2E1处置的结果可能有助于模拟CYP2E1诱导剂和抑制剂的作用。为预防CYP2E1介导的生物活化,根据原毒物的处置情况,可能需要第二次服用DSF以完全预防毒性。
