Lin Chun-Jung, Yen Ming-Fang, Hu Oliver Yoa-Pu, Lin Min-Shung, Hsiong Cheng-Huei, Hung Chin-Chuan, Liou Horng-Huei
School of Pharmacy and Graduate Institute of Clinical Pharmacy, National Taiwan University, Taipei, Taiwan.
Pharmacotherapy. 2008 Jan;28(1):35-41. doi: 10.1592/phco.28.1.35.
To evaluate whether the occurrence or severity of gingival hyperplasia is associated with liver function test results or phenytoin metabolism.
Prospective analysis.
University-affiliated medical center in Taipei, Taiwan.
Sixty-six patients (mean age 37.9 yrs) with epilepsy who were receiving phenytoin for more than 1 year. Intervention. Four blood samples were drawn from each patient for liver function testing, concentrations of phenytoin and its metabolites R-5-(4'-hydroxyphenyl)-5-phenylhydantoin (R-HPPH) and S-HPPH, and genotyping of cytochrome P450 (CYP) 2C9 and 2C19.
Plasma concentrations of phenytoin and its metabolites were determined by a high-performance liquid chromatography method. The CYP2C9 and CYP2C19 genotypes were analyzed by polymerase chain reaction-restriction fragment length polymorphism analysis. Conventional liver function assays and a quantitative liver function test--galactose single-point (GSP) measurement--were performed. Statistical analyses were performed to evaluate the association between liver function test results as well as metabolic phenotype and the occurrence and severity of gingival hyperplasia. Among liver function tests, only GSP levels showed a significant difference between patients with and those without gingival hyperplasia. Patients with an elevated GSP level (> or = 280 microg/ml) had a significantly higher odds ratio (OR 4.51) for the occurrence of gingival hyperplasia. In addition, increased R-HPPH (OR 1.02) and phenytoin (OR 1.09) concentrations were associated with an increased occurrence of gingival hyperplasia. However, only increased GSP and R-HPPH concentrations had significantly higher ORs (2.84 and 1.02, respectively) associated with the severity of gingival hyperplasia. Although mean +/- SD plasma R-HPPH concentration was significantly lower in CYP2C19 poor metabolizers compared with CYP2C9 and CYP2C19 extensive metabolizers and CYP2C9 poor metabolizers (30.38 +/- 16.73 vs 68.22 +/- 44.75 and 78.95 +/- 51.67 microg/ml, respectively), no significant association between genotype and gingival hyperplasia was found.
Increased GSP, phenytoin, and R-HPPH concentrations were associated with increased occurrence of phenytoin-induced gingival hyperplasia; only increased GSP and R-HPPH concentrations were associated with increased severity of this adverse effect.
评估牙龈增生的发生或严重程度是否与肝功能测试结果或苯妥英代谢有关。
前瞻性分析。
台湾台北的大学附属医院。
66例癫痫患者(平均年龄37.9岁),接受苯妥英治疗超过1年。干预措施:从每位患者采集4份血样,进行肝功能测试、苯妥英及其代谢产物R-5-(4'-羟基苯基)-5-苯基乙内酰脲(R-HPPH)和S-HPPH的浓度测定,以及细胞色素P450(CYP)2C9和2C19的基因分型。
采用高效液相色谱法测定血浆中苯妥英及其代谢产物的浓度。通过聚合酶链反应-限制性片段长度多态性分析对CYP2C9和CYP2C19基因型进行分析。进行常规肝功能检测和定量肝功能测试——半乳糖单点(GSP)测量。进行统计学分析以评估肝功能测试结果以及代谢表型与牙龈增生的发生和严重程度之间的关联。在肝功能测试中,只有GSP水平在有牙龈增生和无牙龈增生的患者之间存在显著差异。GSP水平升高(≥280μg/ml)的患者发生牙龈增生的优势比(OR)显著更高(OR为4.51)。此外,R-HPPH(OR为1.02)和苯妥英(OR为1.09)浓度升高与牙龈增生的发生率增加有关。然而,只有GSP和R-HPPH浓度升高与牙龈增生的严重程度相关的OR显著更高(分别为2.84和1.02)。尽管与CYP2C9和CYP2C19广泛代谢者以及CYP2C9代谢不良者相比,CYP2C19代谢不良者的血浆R-HPPH平均浓度显著更低(分别为30.38±16.73 vs 68.22±44.75和78.95±51.67μg/ml),但未发现基因型与牙龈增生之间存在显著关联。
GSP、苯妥英和R-HPPH浓度升高与苯妥英诱导的牙龈增生发生率增加有关;只有GSP和R-HPPH浓度升高与这种不良反应的严重程度增加有关。
