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研究生: 郭力禎
Kuo, Li-Chen
論文名稱: 中草藥純物質TR及AG透過麩胺酸接受器減緩Aβ誘導之神經病變
Pure compounds TR and AG within Chinese herbal medicines mediate glutamate receptors to attenuate Aβ-induced neuronal pathophysiology.
指導教授: 林炎壽
Lin, Yenshou
學位類別: 碩士
Master
系所名稱: 生命科學系
Department of Life Science
論文出版年: 2016
畢業學年度: 104
語文別: 中文
論文頁數: 53
中文關鍵詞: 阿茲海默症β類澱粉蛋白麩胺酸接受器中草藥DiBAC4(3)
英文關鍵詞: Alzheimer’s disease, amyloid beta, DiBAC4(3), glutamate receptor, Chinese herbal medicines
DOI URL: https://doi.org/10.6345/NTNU202204497
論文種類: 學術論文
相關次數: 點閱:202下載:1
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  • 阿茲海默症(Alzheimer’s disease, AD)是常見的神經退化性疾病,導致病患逐漸喪失記憶並產生認知功能的障礙,本研究探討可以減緩Aβ誘導神經病變的中草藥及其機轉。研究指出Aβ 寡聚體會過度活化麩胺酸接受器,包括AMPA receptor、NMDA receptor、Kainate receptor及mGluR1/5,進而造成神經細胞不正常去極化、導致細胞死亡。利用DiBAC4(3)膜電位螢光染劑做為藥物篩選平台,可以觀察到Aβ寡聚體誘導神經細胞不正常去極化的現象,於之前利用此平台篩選所得的幾種有效中草藥物中,目前針對其中兩種純物質進行進一步研究,暫時分別命名為TR及AG,發現TR及AG會調節NMDA接受器或AMPA接受器來減緩神經不正常去極化。在藥理機轉方面,我們推測AG可能參與未在本研究探討的訊息傳遞分子範圍,因此尚未找到其有效機轉,然而AG具有類似NMDA接受器拮抗劑及AMPA接受器拮抗劑的特性,提供未來臨床阿茲海默症患者一個具潛力性的治療及解決方案。

    Alzheimer’s disease (AD), a progressive neurodegenerative disease leads to memory impairment and other cognitive problems. Recent studies have indicated that the synaptic dysfunction induced by Aβ oligomer is dependent on overstimulation of glutamate receptors such as N-methyl-D-aspartate receptors (NMDARs), AMPA receptors (AMPARs), kainite receptors, and mGluR1/5. Utilizing DiBAC4(3), a slow response voltage-sensitive fluorescent dye, we have established a drug screening platform. After screening for ~12 herbal medicines, we focus on two pure compounds, named TR and AG, which are able to ameliorate Aβ-induced depolarization. We found that these two pure compounds mediate NMDA receptors and AMPA receptors to execute such effects. Currently, we have not revealed more molecular/signaling mechanism regarding of AG. Overall, the finding that AG can be used as NMDA receptor antagonist and AMPA receptor antagonist offers a great potential for developing a new therapeutic drug for treatment of AD patients.

    目錄 i 圖目錄 iii 摘要 iv ABSTRACT v 第一章 緒論 1 一、 阿茲海默症 1 二、 β類澱粉蛋白之形成 2 三、 β類澱粉蛋白之神經毒性 3 四、 β類澱粉蛋白對麩胺酸傳遞系統影響 4 五、 β類澱粉蛋白媒介訊息傳遞導致神經死亡 4 六、 現今治療阿茲海默症之臨床藥物 7 第二章 研究動機與目的 9 第三章 材料與實驗方法 10 一、 藥品 10 二、 小鼠大腦皮質神經元初級培養 11 三、 細胞免疫螢光染色法 12 四、 細胞存活檢測 12 五、 β類澱粉蛋白寡聚體製備 13 六、 蛋白質斑點印漬分析(Dot blot assay) 13 七、 DiBAC4(3)膜電位螢光染劑篩藥平台 14 八、 西方墨點法 15 九、 統計分析 16 第四章 結果 17 一、 檢驗大腦皮質初級培養神經元中麩胺酸神經元之純度 17 二、 篩選藥物平台的建立以及以臨床用藥Memantine確認效能 18 三、 純物質TR及AG對神經細胞之毒性測試 20 四、 TR及AG能減緩Aβ寡聚體誘導的神經不正常去極化 21 五、 TR可透過抑制NMDAR,但不是抑制AMPAR來減緩神經不正常去極化 22 六、 AG能透過NMDAR及AMPAR改善神經不正常去極化 23 七、 AG無法改善Aβ寡聚體對Erk及caspase 3訊息傳遞分子的影響 24 第五章 討論 26 參考文獻 30 附圖 37 附錄 50

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