Nation R L, Evans A M, Milne R W
School of Pharmacy, South Australian Institute of Technology, Adelaide, Australia.
Clin Pharmacokinet. 1990 Jan;18(1):37-60. doi: 10.2165/00003088-199018010-00003.
Phenytoin, which is used primarily as an anticonvulsant agent, has a relatively low therapeutic index, and monitoring of plasma phenytoin concentration is often used to help guide therapy. It has properties which predispose it to an involvement in pharmacokinetic interactions, a large number of which have been reported. These properties include: low aqueous solubility and slow rate of gastrointestinal absorption; a relatively high degree of plasma protein binding; a clearance that is non-linear due to saturable oxidative biotransformation; and the ability to induce hepatic microsomal enzymes. Because of its narrow therapeutic range, drug interactions leading to alterations in plasma phenytoin concentration may be clinically important. Such interactions have often been reported initially as either cases of phenytoin intoxication or of decreased effectiveness. Drugs may modify the pharmacokinetics of phenytoin by altering its absorption, plasma protein binding, or hepatic biotransformation; alterations in the absorption and/or biotransformation may lead to changes in both the unbound plasma phenytoin concentration and, as a result, the clinical effect. Preparations which may decrease the gastrointestinal absorption of phenytoin include nutritional formulae and charcoal. There are many reports of drugs which may increase (e.g. folic acid, dexamethasone and rifampicin) or decrease (e.g. valproic acid, sulthiame, isoniazid, cimetidine, phenylbutazone, chloramphenicol and some sulphonamides) the metabolism of phenytoin. It is important to bear in mind that, as a result of its non-linear clearance, changes in phenytoin absorption and/or biotransformation will lead to more than proportionate changes in plasma drug concentration. Drugs which may displace phenytoin from plasma albumin include valproic acid, salicylic acid, phenylbutazone and some sulphonamides. Although an alteration in the unbound fraction of phenytoin in plasma would not, in itself, be expected to alter the unbound plasma phenytoin concentration, the interpretation of total plasma concentrations for therapeutic drug monitoring may be confounded. Some drugs appear to alter phenytoin pharmacokinetics via dual mechanisms (e.g. valproic acid and phenylbutazone), while for other compounds the mechanism of interaction has not been fully elucidated. Phenytoin has been reported to alter the pharmacokinetics of a large number of drugs. The majority of these interactions arise because phenytoin is a potent inducer of cytochrome P450 microsomal enzymes, and therefore may increase the clearance of drugs which are extensively metabolised; drugs affected include carbamazepine, theophylline, methadone, prednisolone, dexamethasone, metyrapone and several cardiac antiarrhythmic agents. With all of these, the resultant decrease in plasma concentrations may be clinically important.(ABSTRACT TRUNCATED AT 400 WORDS)
苯妥英主要用作抗惊厥药,其治疗指数相对较低,常通过监测血浆苯妥英浓度来指导治疗。它具有一些特性,易引发药代动力学相互作用,此类相互作用已有大量报道。这些特性包括:水溶性低且胃肠道吸收速率慢;血浆蛋白结合程度较高;由于可饱和的氧化生物转化,清除率呈非线性;以及具有诱导肝微粒体酶的能力。因其治疗范围狭窄,导致血浆苯妥英浓度改变的药物相互作用可能具有临床重要性。此类相互作用最初常被报道为苯妥英中毒或疗效降低的病例。药物可通过改变苯妥英的吸收、血浆蛋白结合或肝生物转化来改变其药代动力学;吸收和/或生物转化的改变可能导致游离血浆苯妥英浓度变化,进而影响临床疗效。可能降低苯妥英胃肠道吸收的制剂包括营养配方和活性炭。有许多关于药物可增加(如叶酸、地塞米松和利福平)或降低(如丙戊酸、舒噻美、异烟肼、西咪替丁、保泰松、氯霉素和一些磺胺类药物)苯妥英代谢的报道。必须牢记,由于其清除率呈非线性,苯妥英吸收和/或生物转化的变化将导致血浆药物浓度出现超过比例的变化。可将苯妥英从血浆白蛋白上置换下来的药物包括丙戊酸、水杨酸、保泰松和一些磺胺类药物。尽管血浆中苯妥英游离分数的改变本身预计不会改变游离血浆苯妥英浓度,但用于治疗药物监测的总血浆浓度的解读可能会受到干扰。一些药物似乎通过双重机制改变苯妥英的药代动力学(如丙戊酸和保泰松),而对于其他化合物,相互作用机制尚未完全阐明。据报道,苯妥英可改变大量药物的药代动力学。这些相互作用大多是因为苯妥英是细胞色素P450微粒体酶的强效诱导剂,因此可能增加广泛代谢药物的清除率;受影响的药物包括卡马西平、茶碱、美沙酮、泼尼松龙、地塞米松、甲吡酮和几种心脏抗心律失常药。对于所有这些药物,血浆浓度的降低可能具有临床重要性。(摘要截选至400字)
