臺灣博碩士論文加值系統

懸浮微粒PM2.5毒性的主要機制為增加人體內活性氧 (Reactive oxygen species,ROS)導致氧化壓力上升、細胞受損，引起全身性炎症，甚至具有遺傳毒性不論是長期或是短期吸入PM2.5皆會造成身體局部炎症或呼吸道不適，有研究指出，PM2.5會導致慢性阻塞肺病 (Chronic Obstructive Pulmonary Disease, COPD)、肺癌、哮喘。COPD是常見的慢性呼吸道疾病，目前是世界第三大死亡原因，PM2.5促使COPD加劇、提高嚴重程度 、 發病率、 死亡率 。近年來， 健康食品、機能性食品於全世界日益盛興，「預防重於治療」，不僅能 減少醫療成本， 更能使身體維持健康，本研究我們探討多種蜂蜜對於 PM2.5 誘發人類肺部支氣管上皮細胞損傷的保護效果，進而減少罹患慢性阻塞肺病的風險 結果中發現預防組的支氣管上皮細胞於PM2.5的損害提高了細胞的存活率，並且和治療組皆顯著降低了 IL-8 細胞發炎因子的分泌量，達到良好的抗發炎效果，藉由西方墨點法測定慢性阻塞肺病發病病理相關的指標物 α 1 antitrypsin 與肺部上皮細胞受損造成緊密連結蛋白降低 Zonula occludens 為早期慢性阻塞肺病的徵兆，結果發現 十種蜂蜜中，以 Kaliandia 蜂蜜、 Dorsata 蜂蜜、 Itama 蜂蜜能明顯降低 PM2.5對於抗胰蛋白酶 α 1 antitrypsin 、緊密連結蛋白 Zonula occludens ) 的損害達到良好的保護效果 ，可作為保肺的功能性食品

PM2.5 have the characteristics of causing systemic inflammation in humans, oxidative stress and cell damage caused by the increase of reactive oxygen species in the human body,and even have the characteristics of genotoxicity, etc. PM2.5 toxicity is caused by the generation of reactive oxygen species, resulting in increased oxidative pres sure, leading to inflammation as the main mechanism, whether long term or short term inhalation of PM2.5 will cause local inflammation or respiratory discomfort. Some studies have pointed out that PM2.5 can cause chronic obstructive pulmonary disease (Chro nic Obstructive Pulmonary Disease, COPD), lung cancer, asthma COPD is a common chronic respiratory disease and is currently the third leading cause of death in the world. PM2.5 can exacerbate COPD, increase its severity, morbidity, and mortality. In recen t years, health foods and functional foods have become increasingly prosperous all over the world. "Prevention is more important than
treatment." The purpose of this study is to investigate whether the use of natural honey can
reduce the damage of PM2.5 to bronchial epithelial cells in the lungs, there by reducing the risk of chronic obstructive pulmonary disease and achieving the protective effect. The research results can be found that the cells in the prevention group can improve the survival rate of the cells in the environment of PM2.5; both the cells in the prevention group and the treatment group have significantly reduced the content of Interleukin 8 to achieve good resistance Inflammation effect. The Western blot method was used to determine the ind ex of pathologically related indicators of chronic obstructive pulmonary disease α-1-antitrypsin and the damage of lung epithelial cells caused by the decrease of tight junction protein (Zonula occludens) is a sign of early chronic obstructive pulmonary d isease. As a result, Kaliandia honey, Dorsata honey, Itama honey, Binghami honey and Lavicep honey achieve good protection and can be used as functional food for lung protection.

摘要... i
Abstract... ii
誌謝... iii
專利分析報告... iv
目錄... v
表目錄... viii
圖目錄... ix
第一章 緒論... 1
第二章 文獻探討... 3
2.1 蜜蜂之介紹... 3
2.1.1 蜂蜜之介紹... 4
2.1.2 蜂蜜之藥理活性... 5
2.2 細懸浮微粒 (Particulate Matter, PM2.5)... 之介紹 7
2.2.1 PM2.5誘導之發炎反應... 8
2.2.2 慢性阻塞肺病 (Chronic Obstructive Pulmonary Disease, COPD) 之介紹... 8
第三章 材料與方法... 10
3.1 實驗材料-蜂蜜樣品... 10
3.2 實驗材料-細懸浮微粒樣品... 10
3.2 蜂蜜理化特性分析... 10
3.2.1 糖度測定... 10
3.2.2 酸價測定... 10
3.2.3 蜂蜜澱粉酶活性... 11
3.2.4 過氧化氫含量分析... 11
3.2.5 蜂蜜醣類成分分析... 12
3.2.6 蜂蜜有機酸成分分析... 12
3.2.7 羥甲基糠醛 (Hydroxymethylfurfural, HMF) 含量分析... 13
3.2.8 蜂蜜總蛋白質含量分析... 13
3.2.9 蜂蜜總酚類含量分析... 14
3.2.10 蜂蜜類黃酮含量分析... 14
3.3 測定蜂蜜抗氧化能力分析... 15
3.3.1 樣品製備方法... 15
3.3.2 2,2-Diphenyl-1-picrylhydrazyl (DPPH) 自由基清除能力分析... 15
3.3.3 還原力測定... 15
3.3.4 Ferric ion reducing antioxidant power , FRAP分析... 15
3.4 蜂蜜之抗菌活性... 16
3.4.1 樣品製備方法... 16
3.4.2 試驗之菌株... 16
3.4.3 活化菌株... 16
3.4.4 菌株培養... 16
3.4.5 抑菌圖譜測定... 17
3.4.6 抑菌圖譜測定-調整蜂蜜 pH值... 17
3.5 蜂蜜對於細胞存活率與抗發炎能力測定... 17
3.5.1 樣品製備方法... 17
3.5.2 人類肺部支氣管上皮細胞株培養... 17
3.5.3 3-(4,5- Dimethylthiazol -2- yl)-2,5- diphenyltetrazolium bromide (MTT) 細胞存活率測定... 18
3.5.4 利用酵素免疫連結分析法 (Enzyme-linked immunoadsorbent assay, ELISA) 測定 BEAS-2B 細胞株 IL-8分泌量... 18
3.6.9 BEAS-2B細胞株蛋白質萃取與分析... 19
1. 蛋白質樣品收集與裂解... 19
2. 二辛可寧酸測定法 (Bicinchoninic acid method, BCA) 蛋白質含量測定... 19
3. 十二烷基硫酸鈉聚丙烯醯胺凝膠電泳 (Sodium dodecyl sulfate polyacrylamide gel electrophoresis, SDS-PAGE)... 19
4. 西方墨點法 (Western blot) 分析 ZO-1, ZO-2 and AAT 蛋白質含量... 20
第四章 結果與討論... 21
4.1 蜂蜜理化特性分析... 21
4.2 蜂蜜總蛋白質含量分析... 22
4.3 蜂蜜總酚類與類黃酮含量分析... 22
4.4 蜂蜜之抗氧化能力分析... 23
4.5 蜂蜜之抗菌活性... 23
4.6 蜂蜜對於細胞存活率與抗發炎能力測定... 25
4.6.1 細胞存活率分析 – MTT assay... 25
4.6.2 BEAS-2B 細胞株 IL8 分泌含量... 25
4.6.3西方墨點法 (Western blot) 分析 ZO-1, ZO-2 and AAT 蛋白質含量... 26
第五章 結論... 28
參考文獻 ...29
附錄一... 62
附錄二... 63
附錄三... 64
附錄四... 65
附錄五... 66
附錄六... 67
附錄七... 68
附錄八... 69
附錄九... 70
附錄十... 71
附錄十一... 72
附錄十二 ...73
附錄十三 ...74
附錄十四 ...75
附錄十五 ...76
附錄十六 ...77
附錄十七 ...78
附錄十八 ...79

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