臺灣博碩士論文加值系統

糖尿病一直高居國人十大死亡病因之列，目前全世界之罹病率仍日漸增加中。香茹草 (Glossogyne tenuifolia (Labill) Cass.) 分布於澎湖地區，當地居民常做為青草茶飲用。近期研究發現香茹草中主要活性成分有抑制α-葡萄糖苷酶活性之潛力，故本研究欲探討香茹草對第2型糖尿病是否具有改善效果。先將香茹草以95 %、50 %乙醇及熱水萃取，比較在體外抑制α-葡萄糖苷酶活性之能力，經綜合評估後發現熱水萃取物之抑制效果較佳。選擇香茹草熱水萃取物進行動物實驗，將八週齡雄性Wistar大鼠，以皮下注射Streptozotocin (STZ, 65 mg/kg) 結合菸鹼醯胺 (230 mg/kg) (STZ–NA) 合併高脂飲食誘發糖尿病高血糖模式，實驗組經飲水給予低劑量 (50 mg/kg)、高劑量 (150 mg/kg) 香茹草萃取物及口服降血糖藥Acarbose飼養四週。結果顯示香茹草水萃物的組別可顯著降低第一、二週空腹血糖值和第二週空腹胰島素濃度，並且於第23天降低給予澱粉後的餐後一小時血糖濃度，以及在第25天降低口服葡萄糖耐受測試 (OGTT) 第60分鐘的血糖值。此外，給予香茹草水萃物四週後能顯著降低血清、肝臟和腎臟中脂質過氧化之TBARS值，並顯著降低血清中總膽固醇、空腹胰島素濃度和改善HOMA-IR值。綜合上述，香茹草水萃物在體外對α-葡萄糖苷酶活性有抑制能力，於動物實驗中可改善STZ–NA所誘發大鼠之糖尿病情形，並減少體內氧化壓力的產生。

The global prevalence of diabetes mellitus (DM) is increasing rapidly in recent years, and disease ranked among the top ten leading causes of death in Taiwan. Glossogyne tenuifolia (GT), a native plant of Penghu, Taiwan, is usually used as an herbal tea. Recent researches have been shown that the active components in GT are potential inhibitors of α-glucosidase. The present study investigated that whether or not GT could improve the status of type 2 DM. The effects of GT extracts derived from various solvents (95% ethanol, 50% ethanol and hot water) on the inhibition of α-glucosidase activity in vitro were compared. The results showed that hot water extracts of GT possessed the best inhibitive capacities and therefore which was chosen for the following animal experiment. Male Wistar rats aged eight weeks were induced to be hyperglycemic by subcutaneous injection of streptozotocin (STZ, 65 mg/kg) –nicotinamide (NA, 230 mg/kg) (STZ–NA) and combination of high-fat diet (HFD). The animals were given GT extracts at low dose (50 mg/kg) or high dose (150 mg/kg), or the anti-diabetic drug (acarbose) in drinking water for 4 weeks. The results showed that hot water extracts from GT resulted in significantly decreased fasting blood glucose at the 1st and 2nd weeks, fasting insulin levels at the 2nd week, 1 hour postprandial blood glucose after starch loading test on the day 23 and blood glucose levels after oral glucose tolerance test (OGTT) at the 60th minute on the day 25. In addition, diabetic rats treated with GT extracts from hot water for 4 weeks displayed significantly decreased thiobarbituric acid reactive substances (TBARS) in the serum, liver and kidney, serum total cholesterol, fasting insulin levels and homeostasis model assessment for insulin resistance (HOMA-IR). In conclusion, the hot water extracts of GT exhibited α-glucosidase activity in vitro, and might improve the progression of diabetes and decreased oxidative stress in STZ–NA-induced diabetic rats.

中文摘要-------------------------------------------I
英文摘要-------------------------------------------II
致謝---------------------------------------------III
目錄----------------------------------------------IV
表目錄--------------------------------------------VII
圖目錄-------------------------------------------VIII
附表目錄--------------------------------------------X
附圖目錄--------------------------------------------XI
壹、緒言---------------------------------------------1
貳、文獻回顧------------------------------------------3
一、香茹草--------------------------------------------3
(一) 香茹草之簡介--------------------------------------3
(二) 香茹草之生理活性-----------------------------------4
(三) 香茹草中成分與糖尿病關係之探討------------------------5
二、糖尿病---------------------------------------------7
(一) 定義與分類-----------------------------------------7
(二) 糖尿病流行病學現況-----------------------------------9
(三) 高血糖誘發氧化壓力-----------------------------------10
(四) 臨床診斷標準----------------------------------------14
(五) 餐後高血糖與第2型糖尿病之關係--------------------------15
三、抑制餐後高血糖與糖尿病之臨床治療-------------------------17
(一) α-葡萄糖苷酶抑制劑 (AGI)-----------------------------17
(二) 二肽基胜肽酶-4 (DPP-4) 抑制劑-------------------------19
四、鏈佐黴素 (STZ) 誘發糖尿病動物模式------------------------20
(一) STZ誘發糖尿病之作用原理--------------------------------20
(二) STZ結合菸鹼醯胺之誘發模式-------------------------------22
參、材料與方法---------------------------------------------24
一、實驗目的-----------------------------------------------24
二、設計架構-----------------------------------------------24
三、材料與器材----------------------------------------------27
四、實驗方法------------------------------------------------30
(一) 實驗I：香茹草之不同溶劑萃取物對糖苷酶與二肽基胜肽酶-4之抑制能力及
酵素動力學測定-----------------------------------------------30
(二) 實驗II：單次管餵香茹草水萃物對STZ–NA所誘發糖尿病大鼠之影響----34
(三) 實驗III：飲水中給予不同劑量之香茹草水萃物持續四週對STZ–NA所誘發
糖尿病大鼠之影響----------------------------------------------38
五、統計分析-------------------------------------------------43
肆、結果----------------------------------------------------44
一、實驗I
(一) 香茹草經由不同溶劑萃取之萃取率比較--------------------------44
(二) 香茹草不同溶劑萃取物對α-葡萄糖苷酶及α-澱粉酶抑制能力之比較------44
(三) 香茹草不同溶劑萃取物對二肽基胜肽酶-4抑制能力之比較-------------44
(四) 香茹草熱水萃取物抑制大鼠小腸來源 α-葡萄糖苷酶之酵素動力學分析----45
二、實驗II
(一) 經單次管餵一小時後之血糖濃度-------------------------------45
(二) 小腸蔗糖酶與麥芽糖酶之活性---------------------------------45
三、實驗III
(一) 體重及飲水量之變化---------------------------------------46
(二) 空腹、餐後血糖與胰島素及HOMA-IR值之影響---------------------46
(三) 口服耐糖試驗 (OGTT) 之血糖濃度變化-------------------------48
(四) 小腸蔗糖酶與麥芽糖酶之活性---------------------------------49
(五) 血清中果糖胺及總膽固醇濃度之影響----------------------------49
(六) 組織臟器重量及小腸長度之比較--------------------------------50
(七) 血清、肝臟、腎臟及胰臟之脂質過氧化程度------------------------50
伍、討論------------------------------------------------------52
陸、結論------------------------------------------------------66
柒、參考文獻---------------------------------------------------88

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