二價鎳離子增強lumino-Mn(II)-KIO4化學發光系統性質研究與其應用

Wen-Yang Hsiao; 蕭文揚

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/38440

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林萬寅(Wann-Yin Lin)
dc.contributor.author	Wen-Yang Hsiao	en
dc.contributor.author	蕭文揚	zh_TW
dc.date.accessioned	2021-06-13T16:33:38Z	-
dc.date.available	2011-07-27
dc.date.copyright	2011-07-27
dc.date.issued	2011
dc.date.submitted	2011-07-18
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/38440	-
dc.description.abstract	化學發光是藉由化學反應產生的發光現象。本研究利用流動注入分析法探討Ni2+ 增強 luminol - KIO4 - Mn2+ 系統化學發光的機制。實驗結果顯示在 pH = 13 的鹼性溶液下，添加 400 μM Ni2+於 luminol - Mn2+ - KIO4 系統可使其化學發光強度增加 2 倍左右。在研究的過程中同時對 pH 值、流速、反應物 (luminol、Mn2+、Ni2+、KIO4) 的濃度對化學發光的強度的影響做探討並找出最佳化條件。由放射光譜中，可以看到只在 425 nm 附近有最大的放光強度，可以確認本系統的放光是由 luminol 所造成的。為了瞭解化學發光的反應機制，加入消滅自由基的試劑進行測試，由結果得知，針對 1O2、O2•－、OH• 的自由基消滅劑，如 DMF、ascorbic acid、DMSO 都會抑制訊號的強度。此外，將試劑除氧後化學發光訊號減弱 80 %，表示此化學發光與溶氧有很大的關係。推測 Mn2+、Ni2+ 可以催化 KIO4 與溶氧在強鹼溶液中反應產生活性含氧物質(O2•－、1O2、OH•)來幫助 luminol 的氧化而增強放光效率，所以加入這些專一性的自由基消滅劑都會讓化學發光訊號降低。而Ni2+之所以能增強化學發光度，推測原因可能是當 luminol - Mn2+ - KIO4 系統產生化學發光反應後，在Ni2+的存在下可以幫助luminol 經氧化產生的中間產物 (X*) 將能量傳遞給 3-aminophthalate ion (3-AP)，而產生化學發光現象而讓化學發光強度增強，此現象稱為post-chemiluminescence。運用luminol - Mn2+ - Ni2+ - KIO4 之化學發光系統可以檢測不同的生化分子如胺基酸、維生素、抗氧化劑等。測試的結果顯示，常見的抗氧化劑，如 bezenediol 與polyphenol類的chlorogenic acid以及兒茶酚胺 (catecholamines) 的多巴胺 (dopamine) 等，對此系統有很好抑制的效果，推測可能是因為這些抗氧化劑能捕捉活性含氧自由基而使化學發光訊號降低。最後我們對抑制效果最好的hydroquinone做一系列的抑制最佳化，改變Mn2+、Ni2+、KIO4的濃度及pH 值，使得hydroquinone有更好的靈敏度，能夠檢測更低的濃度。經抑制最佳化後，hydroquinone的偵測極限可達到0.089 nM。	zh_TW
dc.description.abstract	Chemiluminescence (CL) is produced by the exothermic reaction. We have studied the enhancement in CL for luminol - KIO4 - Mn2+ system caused by nickel (II) ion using flow injection analysis. About 2-fold increase in CL intensity was observed upon addition of 400 μM Ni2+ to the CL system at pH 13.0. The effects of pH, concentrations of reagents (luminol, Mn2+, Ni2+, KIO4) were optimized. In CL emission spectrum, the CL maximum signal occurred at 425 nm, indicating that the CL is caused by luminol in luminol - KIO4 - Mn2+ - Ni2+ system. In order to know the mechanism of the chemiluminescence of luminol - KIO4 - Mn2+ - Ni2+ system, we tested a series of free radical scanvengers for their effect on CL emission. In the presence of 1O2, O2•－and OH˙ scanvengers like DMF, ascorbic acid, DMSO, the CL emission was inhibited. In addition, deoxydenation of sample solutions by purging with nitrogen reduced the CL intensity by 80 %, indicating that oxygen is involved in this CL reaction. The CL-enhancement may result from the reaction of KIO4 and dissolved oxygen in strong alkaline solution to produce reactive oxygen species (ROS) in the prescence of catalytic Mn2+, Ni2+. Radical scavengers inhibited CL emission by their ability to destroy ROS. Experiments also found that when Ni2+ was injected into the mixture of the luminol - Mn2+ - potassium periodate reaction, chemiluminescence signals were produced once again. This phenomenon has been named as post-chemiluminescence (PCL). It was proposed that the intermediate (X) formed during the luminol - Mn2+ - potassium periodate reaction was excited to X* under the action of Ni2+, then the energy of X* was transferred to 3-AP, and 3-AP* emits light at 425 nm. By using the CL system, we tested 45 compounds including amino acids, vitamins, antioxidant for their effect on the CL emission. We found that common antioxidants such as catecholamines and benzenediols showed inhibiting effect on our CL system, The CL-inhibition may result from scanvenging ROS by antioxidants. Finally we did a series of optimization for the best inhibitory effect of hydroquinone, the detection limits for hydroquinone was 8.9×10-11 mol L-1.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T16:33:38Z (GMT). No. of bitstreams: 1 ntu-100-R98223181-1.pdf: 1376744 bytes, checksum: 6bb00fb2d3692dec01449b89057f7341 (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	目錄摘要 I Abstract II 目錄 IV 圖目錄 VI 表目錄 IX 第一章序論 1 1-1 化學發光的發展 1 1-2 化學發光原理 3 1-3 Luminol 化學發光系統簡介 4 1-4 以IO4－為氧化劑之化學發光系統介紹 6 1-5 金屬對luminol的化學發光影響 7 1-6 活性含氧物質對化學發光影響 9 1-7 研究動機 11 第二章實驗部份 12 2-1 實驗藥品 12 2-2 實驗儀器 15 2-3 儀器架設 15 2-3-1 FIA-CL原理 15 2-3-1 FIA-CL儀器架設 20 第三章結果與討論 24 3-1 訊號再現性 24 3-1-1 幫浦脈衝的問題 24 3-1-2 流速的影響 26 3-1-3 樣品注入的影響 26 3-1-4 樣品與試劑混合的影響 28 3-1-5 偵測器的影響 29 3-2 Luminol-Mn2+-Ni2+-KIO4發光系統 30 3-2-1 試劑組成與流路/注射配置 30 3-2-2 流速對訊號強度的影響 34 3-2-3 各種試劑濃度對化學發光的影響 35 3-2-4 溶氧對化學發光的影響 41 3-2-5 添加EDTA對化學發光的影響 42 3-3 自由基消滅劑對化學發光的影響 45 3-3-1 超氧離子消滅劑測試 45 3-3-2 氫氧自由基消滅劑測試 49 3-3-1 單態氧自由基消滅劑測試 53 3-4 Luminol-Mn2+-Ni2+-KIO4發光系統機制之探討 57 3-5 Luminol-Mn2+-Ni2+-KIO4發光系統的應用 64 3-5-1 抗氧化劑與生化分子檢測 64 3-5-2 抗氧化劑的細部檢測 69 3-5-2-1 四-甲基苯酚 (p-cresol) 69 3-5-2-2 高香草酸 (homovanillic acid) 71 3-5-2-3 Normetanephrine 73 3-5-2-4 Chlorlgenic acid 75 3-5-2-5 Catechin 77 3-5-2-6 多巴胺 (dopamine) 79 3-5-2-7 Trolox 81 3-5-2-8 Sesamol 83 3-5-2-9 間二苯胺 (o-phenylenediamine) 85 3-5-2-10 Benzenediols 87 第四章結論 106 第五章參考文獻 107
dc.language.iso	zh-TW
dc.title	二價鎳離子增強lumino-Mn(II)-KIO4化學發光系統性質研究與其應用	zh_TW
dc.title	Enhancement of Chemiluminescence of the Lumino-Mn(II)-KIO4 System by Ni(II) and Its Applications	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	劉春櫻(Chuen-Ying Liu),何國榮(Guor-Rong Her)
dc.subject.keyword	化學發光,流動注入分析,過點酸鉀,鎳離子,二次化學發光,苯二酚,	zh_TW
dc.subject.keyword	chemiluminescnece,flow injection analysis,potassium periodate,nickel (II) ion,post-chemiluminescence,benzenediol,	en
dc.relation.page	109
dc.rights.note	有償授權
dc.date.accepted	2011-07-19
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	化學研究所	zh_TW
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