Caffeic acid 及其酯類化合物在家兔體內之藥物動力學研究

Caffeic acid 及其酯類化合物在家兔體內之藥物動力學研究

 Caffeic acid 為一多酚類化合物 , 廣泛存於植物界中 , methyl

 caffeate ethyl caffeate 為 caffeic acid 之酯類衍生物 , 三者皆具有

 抑制 5-lipoxygenase 及 12-lipoxygenase 的活性 , 故可抑制過敏反

 應 , 並且亦可抑制血小板的凝集作用。本實驗利用高效液相層析法定量 ,

 對 caffeic acid, methyl caffeate 及 ethyl caffeate 進行安定性試

 驗 , 再以雄性家兔為實驗動物 , 分別靜脈注射與口服投予等莫耳數 (

 0.056 mmole/kg ) 之 caffeic acid, methyl caffeate 及 ethyl

 caffeate, 建立三者在家兔體內的藥物動力學。實驗結果顯示 , 於不同

 pH 值下 caffeic acid,methyl caffeate 及 ethyl caffeate 於 pH 值

 2-5 具有較好之安定性 . 在 0℃ 下 , caffeic acid, methyl caffeate 及

 ethyl caffeate 於全血中之安定性較於 25℃ 好 . 在 25℃ 下 caffeic

 acid, methyl caffeate 及 ethyl caffeate 於酸化的血漿中 , 具有較好之

 安定性。靜脈投予家兔每公斤體重 7.5, 10 或 15 毫克 caffeic acid,

 此劑量範圍內 caffeic acid 藥物動力學呈 dose independent 。口服投

 予家兔每公斤體重 0.056 毫莫耳 caffeic acid, 其藥物動力學呈現

 "flip-flop" 的現象 . 另外 caffeic acid 口服之生體可用率為

 0.34±0.10. 靜脈投予 methyl caffeate 或 ethyl caffeate, 代謝生成

 caffeic acid 之比例分別為 0.18±0.09 及 0.63±0.12. 口服投予

 methyl caffeate 或 ethyl caffeate, 代謝生成 caffeic acid 之比例

 為 0.16±0.02 及 0.20±0.08 . 由此可知 , 口服投予 methyl caffeate

 及 ethyl caffeate 並無法增加 caffeic acid 之生成 , 而以靜脈投予 ,

 ethyl caffeate 水解生成 caffeic acid 比例比 methyl caffeate 多。

Pharmacokinetic study of caffeic acid and its esters in rabbits

 Caffeic acid(3,4-dihydroxycinnamic acid), a natural phenolic

 compound, is widely distributed in vegetable and coffee

 products. Methyl caffeate and ethyl caffeate are caffeic acid

 derivatives by esterification of caffeic acid These three

 compounds can inhibit the platelet aggregation and thromboxane

 biosynthesis. The stability of caffeic acid, methyl caffeate

 and ethyl caffeate was investigated. The result shows that

 caffeic acid, methyl caffeate and ethyl caffeate are stable in

 pH range 2-5. These three compound in whole blood are more

 stable at 0 than at 25 . In addition, these compounds are ℃ ℃

 more stable in acidified plasma than in unacidified plasma at

 25 . After i.v. bolus 7.5, 10 and 15 mg/kg of caffeic acid to ℃

 rabbits, the pharmacokinetic parameters, systemic clearance,

 elimination rate constant, and volume of distribution, in the

 dose range show dose independent. The concentration-time curve

 can be fitted by two compartment model for caffeic acid, methyl

 caffeate and ethyl caffeate after i.v. bolus of 0.056 mmole/kg

 of these three compounds (equivalence to 10 mg/kg of caffeic

 acid) to rabbits respectively. It shows that caffeic acid after

 oral administration follows flip-flop pharmacokinetics. The

 bioavailability of caffeic acid after oral administration is

 0.39±0.24. The formation fraction of caffeic acid after i.v.

 bolus of methyl caffeate and ethyl caffeate are 0.18±0.09 and

 0.63±0.12. After oral administration of methyl caffeate and

 ethyl caffeate, respectively, the formation fraction of caffeic

 acid are 0.16±0.02 and 0.20±0.08. It shows that methyl

 caffeate and ethyl caffeate can't improve caffeic acid

 bioavailability after oral administration. After i.v. bolus,

 ethyl caffeate hydrolyzed to formation of caffeic acid is

 larger than that of methyl caffeate.