經修飾過竹炭作為多功能免疫分析材料應用於人類血清之研究

Chin-Hui Weng; 翁欽暉

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/43881

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林?輝(Feng-Huei Lin)
dc.contributor.author	Chin-Hui Weng	en
dc.contributor.author	翁欽暉	zh_TW
dc.date.accessioned	2021-06-15T02:31:30Z	-
dc.date.available	2011-08-20
dc.date.copyright	2009-08-20
dc.date.issued	2009
dc.date.submitted	2009-08-15
dc.identifier.citation	[1] Glenn Dranoff. Cytokines in cancer pathogenesis and cancer therapy, 2004. [2] Janeway, Jr. C. A. and R. Medzhitov.Innate immune recognition. Annu.Rev.Immunol2002; 20: 197-16. [3] Rus H, Cudrici C, Niculescu F. The role of the complement system in innate immunity.Immunol Res 2005; 33(2): 103-12. [4] Mayer. Gene Immunology. Chapter Two: Complement Microbiology and Immunology 2006. [5] 白禮源等，1996，甘龍醫用生理學，軒圖書出版社。 [6] Takeda, K. and S. Akira. Toll-like receptors in innate immunity. Int. Immunol 2005; 17(1):1-14. [7] M. Ferencik. Handbook of immunochemistry, 1993. [8] 'Immunity.' Online . Britannica Student Encyclopædia. <http://student.britannica.com/ebi/art.66068> [9] 許元勳總校閱，2003，免疫學第四版，高立圖書有限公司。 [10] Immunobiology, 6/e.(Garland Science 2005) [11] Ibrahim A. Darwish. Immunoassay Methods and their Applications in Pharmaceutical Analysis: Basic Methodology and Recent Advances, IJBC. 2006; 2(3): 217-235. [12] Alan Johnstone and Robin Thorpe. Immunochemistry in practice 2/e, 1987. [13] 郭雅音編著，2002，臨床血清免疫學，藝軒圖書出版社。 [14] A.G. Richard, J.K. Thomas, A.O. Barbara. Kuby immunology, W.H. freeman and company, New York, 2002. [15] J.P. Gosling. A decade of development in immunoassay methodology. Clinical Chemistry 1990; 36: 1408－427. [16] John R. Crowther. ELISA Theory and Practice 1995. [17] Els Parton, Randy De Palma, Gustaaf Borghs. IMEC, Leuven, Belgium. Biomedical applications using magnetic nanoparticles. Solid State Technology 2007. [18] 石原茂久，新しい機能性炭素材料素材としての木炭の利用(Ⅰ)。木材工業2002; 5(1)：2-7。 [19] 石原茂久，木質系炭素材料素材開発の新しい展開。木材学会誌1996; 42（8）：717-23。 [20] 張文理，孟宗竹炭化後的性質及顯微結構的分析，台北科技大學材料及資源工程系。 [21] IUPAC Mannal of Symbols and terminology, Appendix 2, Pt. 1,Colloid and Surface Chemistry , Pure Appl. Chem, 1972; 31: 578. [22] Radovic, L. R. and F. Rodriguez.Reinoso Carbon materials in catalysis. Chem.Phys. Carbon 1997; 25: 243-359. [23] M. Krzesin’ ska, J. Zachariasz, A.I. Lachowski. Development of monolithic eco-composites from carbonized blocks of solid iron bamboo (Dendrocalamus strictus) by impregnation with furfuryl alcohol. Bioresour Technol, 2009;100: 1274-278. [24] 謝榮生，孟宗竹及麻竹解剖構造與滲透性之研究，台大森林系博士論文，1992。 [25] E. pelde, C. Menachem, D. Bar. Tow, and A.Melman, Improved Graphite Anode For Lithium-Ion Batteries, J. Electrochem. Soc, 1996;1431. [26] Lin, C. C. Application of granular activated carbon for water andwastewater purification. Ph. D. Dissertation. University of Taxas at Dallas. USA. 1982;15-36. [27] Wu, F. C, R. L. Tseng, R. S. Juang Preparation of activated carbon from bamboo and their adsorption abilities for dyes and phenol. Journal of environmental science and health 1999; 34(9): 1753-775. [28] 張金海，1994，非均勻反應觸媒特性與實效應用，臺灣復文興業。 [29] B. D. Ratner, A. S. Hoffman, F. J. Schoen, J. E. Lemons, Biomaterials Science: An Introduction to Materials in Medicine, Florida: Academic Press, 1996; 124-130. [30] G. T. Hermanson, Bioconjugate Techniques, Rockford: Pierce Chemical Company, 1996; 4-13. [31] B. D. Ratner, Surface modification of polymers: chemical, biological and surface analytical challenges, Biosensors & Bioelectronics, 1995; 10, 797-804. [32] Kuiyang Jiang, Linda S. Schadler, Richard W. Siegel, Xinjie Zhang, Haifeng Zhang and Mauricio Terrones, Protein immobilization on carbon nanotubes via a two-step process of diimide-activated amidation. Journal of Materials Chemistry 2004; 14: 37-39. [33] Y. Zhang and J. Zhang. Surface modification of monodisperse magnetite nanoparticles for improved intracellular uptake to breast cancer cells. Journal of colloid and interface science, 2005; 283: 352-357. [34] M. Zhang, T. Desai and M. Ferrari, Protein and cells on PEG immobilized silicon.Biomaterials1998; 19: 953-960. [35] M. Zhang and M. Ferrari. Hemocompatible polyethylene glycol film on silcon. Biomed Microdevices. 1998;1 :81. [36] M. Zhang and M. Ferrari. Reduction of protein adsorption on silcon coated with a self-assembled polyethylene glycol and monomethoxypolyethylene glycol. Gourley PL, ed.Proceedings of SPIE. 1998; 3258: 15-9. [37] H. J. Griesser. Poly(L-lysine)-g-poly(ethylene glycol) as a model protein-resistant coating:mechanical properties and the role of bound water. Surface Science and Technology 2005. [38] G. T. Hermanson, Bioconjugate Techniques, Rockford: Pierce Chemical Company, 1996; 213-233. [39] J.V. Staros, R.W. Wright, D.M. Swingle. Anal. Biochem. 1986; 156: 220. [40] J. F. Shackelford. Magnetic materials. Introduction to Materials Science for Engineerings.5thed, 2001; 144-146. [41] D. B. Williams and C. B. Carter. The energy-dispersive spectrometer. Transmission electron microscopy. 1995; 58: 634 6. [42] Geology & Geophysics , 13th Apr. 2007, X-ray crystallography, <http://www.geology.wisc.edu/~pbrown/g360/xray992.html> [43] http://www.fisk.edu/~aburger/Published03_06/Measurement_/Thermal/DSC_TGA [44] JCPDS.ICDD Copyright© (1995) PDF.2 Sets 1.45 database [45] Barbara H. Stuart. Infrared spectroscopy:fundamentals and applications, 2004.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/43881	-
dc.description.abstract	免疫分析乃是利用抗原與抗體之間具有特異性的親和力，來偵測與定量出檢體中特定物質的濃度。免疫分析已被廣泛地運用在許多醫藥分析領域，如疾病的診斷、血液中藥物濃度的監測及臨床藥動學研究等等，利用放射性、螢光或是酵素顯色來測定抗原或是抗體的濃度。然而，免疫分析不但需要特殊的設備與儀器來測定訊號的強度，因此費用昂貴與耗時，並且容易產生非專一性結合殘留(Non-specific binding)，影響檢驗的準確性。因此，本研究之目的著眼於降低免疫分析的實驗費用與非專一性結合。利用竹炭表面多孔隙且方便改質的特性，將其修飾成為能夠降低非專一性結合的的免疫分析材料，並且設計一套免疫分析裝置(Immunoassay device)，以減低實驗的繁雜度並降低實驗的費用。本研究選用竹炭與聚氧乙烯二胺(Polyoxyethylene bis-amine，PEGBA)當做主要材料，乃由於竹炭為多孔性之炭化材料，能夠增加表面積，而且竹炭結構具有豐富的碳雙鍵(C=C)，方便進行表面改質。竹炭利用酸處理使得表面帶有羧基(Carboxyl group)，可與帶有胺基(Amino group)的高分子以穩定的醯胺鍵(Amide bond)接枝。本研究將聚氧乙烯二胺接枝在竹炭的表面後，聚氧乙烯二胺另外一端未鍵結的胺基可以與抗體的C端進行結合，並且不影響抗體與抗原結合的N端，能夠保持抗體與抗原間的專一性與親合力。此外，此高分子的結構更能夠造成極大的空間結構障礙，產生表面泳動效應，使得非專一性的結合或吸附降至最低，增加免疫分析的準確效率。竹炭經由酸處理並與高分子接枝進行表面修飾後，進一步能夠結合抗體，成為多功能免疫分析的材料。本研究利用設計出的免疫分析裝置，以經過表面修飾的竹炭做為多功能免疫分析的材料，與市售的磁性奈米粒子比較，具有減少非專一性結合並降低實驗費用與時間的功用。	zh_TW
dc.description.abstract	Immunoassays are bioanalytical methods which detect and quantify the concentration of a certain analyte through the specific affinity between an antigen (analyte) and an antibody. Immunoassays have been widely used in many important areas of pharmaceutical analysis, such as diagnosis of diseases, therapeutic drug monitoring, clinical pharmaco¬kinetic, etc. Immunoassays are achieved by measuring the label activity (e.g. radiation, fluorescence, or enzyme) of antigens or antibodies. However, immunoassays often require special apparatus and instruments, which are expensive and time-consuming. Furthermore, signal detection of immunoassays is also easily disturbed by non-specific bindings. Therefore, the purpose of this study focuses on reducing experimental expenses and non-specific bindings of immunoassays. Utilizing its porous structure and the easily modifiable surface, bamboo charcoal can be modified to become a suitable material for immunoassays. In addition, we designed a new immunoassay device in order to reduce the complexity and expenses of the experiment. There are many advantages with using bamboo charcoal and polyoxyethylene bis-amine (PEGBA) as the main experimental materials. First, the porous surface of bamboo charcoal gives rise to a large surface area. Also, the abundant carbon double bonds on surface of bamboo charcoal are easy to be modified. By treating bamboo charcoal with acid, the surface will become full of carboxyl groups, which then can bind with the amino groups of PEGBA through amide bonds. While one end of PEGBA is grafted on the surface of bamboo charcoal, the other end is able to bind with the C-terminus of antibodies, leaving the N-terminus available to antigens. Moreover, the special structure of PEGBA can lead to a waving effect, which can cause steric repulsion and reduce non-specific bindings. This method can improve the accuracy of immunoassays. In conclusion, bamboo charcoal can be modified through carboxylation and PEGBA grafting. Modified bamboo charcoal can then be successfully conjugated with antibodies and become a multiplexed immunoassay material. Comparing with commercial magnetic nanoparticles, our device is more effective in reducing non-specific bindings and saving experimental expenses and time.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T02:31:30Z (GMT). No. of bitstreams: 1 ntu-98-R96548052-1.pdf: 480655 bytes, checksum: 307f5afbeadc8e68e3af4529e1e4569b (MD5) Previous issue date: 2009	en
dc.description.tableofcontents	目錄口試委員會審定書…………………………………………I 誌謝…………………………………………………………II 中文摘要……………………………………………………III Abstract……………………………………………………IV 目錄…………………………………………………………Ⅵ 圖索引………………………………………………………Ⅸ 表索引………………………………………………………XII 第一章導論…………………………………………………1 1.1 前言……………………………………………………1 1.2 免疫反應………………………………………………1 1.2.1 非專一性免疫反應…………………………………2 1.2.2 專一性免疫反應……………………………………3 1.2.3 抗原…………………………………………………5 1.2.4 抗體…………………………………………………6 1.2.5 抗體與抗原間結合作用力…………………………8 1.3 免疫分析………………………………………………9 1.3.1 放射免疫分析法……………………………………13 1.3.2免疫放射分析法……………………………………14 1.3.3螢光免疫分析法……………………………………15 1.3.4免疫螢光分析法……………………………………16 1.3.5酵素免疫分析法……………………………………17 1.3.6磁性奈米粒子………………………………………18 1.4 材料鍵結概念…………………………………………18 1.5 研究目的………………………………………………19 第二章理論基礎………………………………………20 2.1竹炭……………………………………………………20 2.1.1 竹炭製備……………………………………………20 2.1.2 竹炭性質……………………………………………22 2.2比表面積計算…………………………………………24 2.2.1 Langmuir 等溫吸附理論…………………………24 2.2.2 BET 等溫吸附理論…………………………………24 2.2.3 炭材比表面積………………………………………26 2.3 分子結合交互作用……………………………………26 2.3.1 羧基…………………………………………………26 2.4 材料表面修飾…………………………………………29 2.4.1 表面修飾方法………………………………………29 2.4.2 竹炭表面……………………………………………30 2.4.3 竹炭表面改質………………………………………30 2.4.4 聚二乙醇接枝………………………………………31 2.4.5生物分子結合…………………………………………32 第三章材料與方法………………………………………34 3.1實驗儀器…………………………………………………34 3.2實驗藥品…………………………………………………35 3.3實驗流程…………………………………………………37 3.4材料製備…………………………………………………38 3.4.1竹炭顆粒………………………………………………38 3.4.2表面改質………………………………………………38 3.4.3表面接枝聚氧乙烯二胺………………………………39 3.4.4表面結合抗體…………………………………………39 3.5免疫分析裝置……………………………………………40 3.6分析方法…………………………………………………42 3.6.1掃描式電子顯微鏡分析與能量散佈光譜分析………42 3.6.2 X光繞射儀分析………………………………………43 3.6.3傅立葉轉換紅外線光譜儀分析………………………44 3.6.4熱重量分析儀…………………………………………45 3.6.5十二烷基磺酸鈉聚丙烯醯胺膠體電泳分析…………46 3.6.6西方墨點法分析………………………………………52 3.6.7液態層析偶合串聯式質譜儀分析……………………55 第四章結果與討論………………………………………57 4.1掃描式電子顯微鏡分析與能量散佈光譜分析…………57 4.1.1能量散佈光譜分析……………………………………57 4.1.2掃描式電子顯微鏡分析………………………………58 4.2 X光繞射儀分析…………………………………………59 4.3傅立葉轉換紅外線光譜儀分析…………………………60 4.4熱重量分析………………………………………………62 4.5十二烷基磺酸鈉聚丙烯醯胺膠體電泳分析……………64 4.6液態層析偶合串聯式質譜儀分析………………………67 第五章結論………………………………………………69 參考文獻……………………………………………………70 圖索引圖1.1免疫反應………………………………………………1 圖1.2專一性免疫反應………………………………………5 圖1.3抗原決定………………………………………………6 圖1.4抗體結構………………………………………………7 圖1.5直接型免疫分析………………………………………10 圖1.6間接型免疫分析法……………………………………11 圖1.7競爭型免疫分析法……………………………………12 圖1.8免疫放射分析法………………………………………14 圖1.9放射免疫分析法………………………………………14 圖1.10酵素免疫分析法………………………………………17 圖1.11磁性奈米粒子…………………………………………18 圖2.1木質材料之炭化模式圖 ………………………………21 圖2.2孔隙之孔徑結構 ………………………………………22 圖2.3竹炭之電子顯微鏡圖 …………………………………23 圖2.4 BET吸附理論模式圖 …………………………………25 圖2.5 Derivative of carboxylic acids by means of active intermediates………………………………………28 圖2.6奈米碳管藉由EDC及NHS與蛋白質鍵結………………30 圖2.7 PEG induce repulsive forces repel serum absorption with increase of surface PEG density…31 圖2.8 PEG化學結構…………………………………………32 圖2.9 PEGBA化學結構………………………………………32 圖2.10 EDC交聯反應………………………………………33 圖2.11利用 EDC與NHS進行交聯反應………………………33 圖3.1竹炭接枝抗體流程圖 ………………………………37 圖3.2竹炭免疫分析流程圖…………………………………38 圖3.3竹炭表面接枝高分子示意圖…………………………39 圖3.4免疫分析裝置示意圖…………………………………40 圖3.5免疫分析裝置實際圖…………………………………40 圖3.6免疫裝置操作步驟……………………………………41 圖3.7掃描式電子顯微鏡……………………………………43 圖3.8 Bragg’s law………………………………………44 圖3.9 RIGAKU Geigerflex XRD……………………………44 圖3.10熱重量分析儀………………………………………46 圖4.1竹炭(BC)之電子顯微鏡圖……………………………57 圖4.2竹炭(BC)之電子顯微鏡圖……………………………57 圖4.3竹炭(BC)之電子顯微鏡圖……………………………57 圖4.4竹炭(BC－COOH)之電子顯微鏡圖……………………57 圖4.5竹炭之XRD繞射分析圖………………………………58 圖4.6竹炭之XRD繞射分析圖………………………………59 圖4.7竹炭之FTIR分析圖……………………………………60 圖4.8竹炭(BC)熱重分析曲線圖……………………………62 圖4.9竹炭(BC－COOH)熱重分析曲線圖……………………62 圖4.10竹炭(BC－PEG－NH2)熱重分析曲線圖……………63 圖4.11抗體結合電泳圖……………………………………65 圖4.12免疫分析電泳圖……………………………………65 圖4.13竹炭與磁珠免疫分析比較電泳圖…………………66 圖4.14西方墨點法分析圖…………………………………66 圖4.15 LC-MS/MS分析結果…………………………………67 圖4.16 LC-MS/MS分析之質譜圖……………………………68 圖4.17 LC-MS/MS分析結果…………………………………68 圖4.18 LC-MS/MS分析結果…………………………………68 表索引表1.1抗體與抗原間結合作用力……………………………9 表2.1各種炭材的比表面積…………………………………26 表2.2用於生物分子結合的官能基…………………………27 表2.3表面修飾方法…………………………………………29 表3.1 10X PBS buffer配方………………………………36 表3.2 0.1M MES buffer配方………………………………36 表3.3膠體組成配製溶液……………………………………48 表3.4各比例膠體成份………………………………………49 表3.5 protein sample buffer……………………………49 表3.6 Protein Marker成分…………………………………50 表3.7硝酸銀染色試劑成分…………………………………51 表3.8 Fast green染劑成分………………………………53 表4.1竹炭EDS分析…………………………………………56
dc.language.iso	zh-TW
dc.subject	免疫分析法	zh_TW
dc.subject	聚氧乙烯二胺	zh_TW
dc.subject	竹炭	zh_TW
dc.subject	表面修飾	zh_TW
dc.subject	非專一性結合	zh_TW
dc.subject	non-specific binding	en
dc.subject	Polyoxyethylene bis-amine( PEGBA)	en
dc.subject	bamboo charcoal	en
dc.subject	surface modification	en
dc.subject	immunoassay	en
dc.title	經修飾過竹炭作為多功能免疫分析材料應用於人類血清之研究	zh_TW
dc.title	Modified bamboo charcoal as a multiplexed immunoassay material in human serum	en
dc.type	Thesis
dc.date.schoolyear	97-2
dc.description.degree	碩士
dc.contributor.coadvisor	周綠蘋(Lu-Ping Chow)
dc.contributor.oralexamcommittee	郭士民(Shyh-Ming Kuo),張淑真(Shwu-Jen Chang)
dc.subject.keyword	免疫分析法,非專一性結合,表面修飾,竹炭,聚氧乙烯二胺,	zh_TW
dc.subject.keyword	immunoassay,non-specific binding,surface modification,bamboo charcoal,Polyoxyethylene bis-amine( PEGBA),	en
dc.relation.page	73
dc.rights.note	有償授權
dc.date.accepted	2009-08-17
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	醫學工程學研究所	zh_TW
顯示於系所單位：	醫學工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-98-1.pdf 未授權公開取用	469.39 kB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。