披覆醋酸纖維薄膜之電容式感測系統應用於土壤碳源酵素活性之檢測

吳鈺琳; Yu-Lin Wu

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/89188

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	鄭宗記	zh_TW
dc.contributor.advisor	Tzong-Jih Cheng	en
dc.contributor.author	吳鈺琳	zh_TW
dc.contributor.author	Yu-Lin Wu	en
dc.date.accessioned	2023-08-30T16:15:06Z	-
dc.date.available	2025-08-01	-
dc.date.copyright	2023-08-30	-
dc.date.issued	2023	-
dc.date.submitted	2023-07-20	-
dc.identifier.citation	王明光, 汪碧涵, 賴朝明, & 田志仁. (2008). 台灣土壤微生物多樣性監測規劃建議書. 國家科學委員會永續會生物多樣性組行動計畫(NSC 96-2621-B-002-017). 王明光, 汪碧涵, 賴朝明, 趙維良, & 田志仁. (2009). 土壤微生物多樣性監測. 台灣大學農業化學系與東海大學生態與生物多樣性研究中心. 邱燕欣, 蘇士閔, 張勝智, 文紀鑾, & 林詩舜. (2018). 次世代定序. 陳涵葳, 林美君, 林素禎, 曾清山, & 杜元凱. (2022). 土壤微生物擴增子定序物種分類指派策略之研究. Ali, Q., Ahmar, S., Sohail, M. A., Kamran, M., Ali, M., Saleem, M. H., Rizwan, M., Ahmed, A. M., Mora-Poblete, F., do Amaral Junior, A. T., Mubeen, M., & Ali, S. (2021). Research advances and applications of biosensing technology for the diagnosis of pathogens in sustainable agriculture. Environ Sci Pollut Res Int, 28(8), 9002-9019. Amat, D., Thakur, J. K., Mandal, A., Patra, A. K., & Reddy, K. K. K. (2020). Microbial Indicator of Soil Health: Conventional to Modern Approaches. In Rhizosphere Microbes (pp. 213-233). Anderson, J. P. E., & Domsch, K. H. (1980). Quantities of plant nutrients in the microbial biomass of selected soils. Berggren, C., & Joghansson, G. (1997). Capacitance Measurements of Antibody-Antigen Interactions in a Flow System. Boltovets, P. M., Boyko, V. R., Kostikov, I. Y., Dyachenko, N. S., Snopok, B. A., & Shirshov, Y. M. (2002). Simple method for plant virus detection: effect of antibody immobilization technique. Chang, C.-Y., & Chang, H.-C. (2006). Micro/Nano Biosensing System and Its Application on Biomedicine. Chen, J.-H., Hui-FangTsai, & Lin, Y.-W. (2003). Evaluation of the Suitability of Three Analvis Methods for Determining Organic Matter Contents in Fertilizers. Cheng, C.-H., Chien, S.-Y., Lee, Y.-C., & Chang, A.-H. (2000). Relationships Between Total Organic Carbon, Oxidable Carbon, and Organic Matter in Compost. Cheng, T.-J., Hsiao, H.-Y., Tsai, P.-C., & Chen, R. L. C. (2023). Redoxless Electrochemical Capacitance Spectroscopy for Investigating Surfactant Adsorption on Screen-Printed Carbon Electrodes. Chemosensors, 11(6). Colas, F., Woodward, G., Burdon, F. J., Guérold, F., Chauvet, E., Cornut, J., Cébron, A., Clivot, H., Danger, M., Danner, M. C., Pagnout, C., & Tiegs, S. D. (2019). Towards a simple global-standard bioassay for a key ecosystem process: organic-matter decomposition using cotton strips. Ecological Indicators, 106. Cosgrove, L., McGeechan, P. L., Handley, P. S., & Robson, G. D. (2010). Effect of biostimulation and bioaugmentation on degradation of polyurethane buried in soil. Appl Environ Microbiol, 76(3), 810-819. Eun, A. J.-C., Huang, L., Chew, F.-T., Li, S. F.-Y., & a, S.-M. W. (2001). Detection of two orchid viruses using quartz crystal microbalance (QCM) immunosensors. Fischer, S., Thümmler, K., Volkert, B., Hettrich, K., Schmidt, I., & Fischer, K. (2008). Properties and Applications of Cellulose Acetate. Macromolecular Symposia, 262(1), 89-96. Jabiol, J., Colas, F., & Guerold, F. (2020). Cotton-strip assays: Let's move on to eco-friendly biomonitoring! Water Res, 170, 115295 Kee, C. M., & Idris, A. (2010). Permeability performance of different molecular weight cellulose acetate hemodialysis membrane. Separation and Purification Technology, 75(2), 102-113. Khater, M., de la Escosura-Muniz, A., & Merkoci, A. (2017). Biosensors for plant pathogen detection. Biosens Bioelectron, 93, 72-86. Kung, Y., Chen, H.-J., Chen, R. R. L., & Cheng, T.-J. (2014). Analysis of Capacitive Biosensors. Laguerre, G., Bardin, M., & Amarger, N. (1993). Isolation from soil of symbiotic and nonsymbiotic Rhizobium leguminosarum by DNA hybridization. Latter, P. M. (1988). Technical Aspects of the Cotton Strip Assay in Soils. Lin, C.-Y., Tsai, Y.-Z., & Lin, L.-L. (2009). Comparison of the soil particle size analysis experiment method. Mazlan, N. S., Ramli, M. M., Abdullah, M. M. A. B., Halin, D. S. C., Isa, S. S. M., Talip, L. F. A., Danial, N. S., & Murad, S. A. Z. (2017). Interdigitated electrodes as impedance and capacitance biosensors: A review McAuley, Wildgoose, G. G., & Compton, R. G. (2009). The physicochemical aspects of DNA sensing using electrochemical methods. Biosens Bioelectron, 24(11), 3183-3190. Nielsen, M. N., & Winding, A. (2002). Microorganisms as Indicators of Soil Health. Parr, J. F., Papendick, R. I., Hornick, S. B., & Meyer, R. E. (1992). Soil quality: Attributes and relationship to alternative and sustainable agriculture. Paternolli, C., Antonini, M., Ghisellini, P., & Nicolini, C. (2004). Recombinant Cytochrome P450 Immobilization for Biosensor Applications. Patle, P. N., Navnage, N. P., & Barange, P. K. (2018). Fluorescein Diacetate (FDA): Measure of Total Microbial Activity and as Indicator of Soil Quality. International Journal of Current Microbiology and Applied Sciences, 7(06), 2103-2107. Puls, J., Wilson, S. A., & Hölter, D. (2010). Degradation of Cellulose Acetate-Based Materials: A Review. Journal of Polymers and the Environment, 19(1), 152-165. Ros, S. D., Aliev, A. E., del Gaudio, I., King, R., Pokorska, A., Kearney, M., & Curran, K. (2021). Characterising plasticised cellulose acetate-based historic artefacts by NMR spectroscopy: A new approach for quantifying the degree of substitution and diethyl phthalate contents. Polymer Degradation and Stability, 183. Simon, C., & Daniel, R. (2011). Metagenomic analyses: past and future trends. Appl Environ Microbiol, 77(4), 1153-1161. Slocum, M. G., Roberts, J., & Mendelssohn, I. A. (2009). Artist canvas as a new standard for the cotton‐strip assay. Journal of Plant Nutrition and Soil Science, 172(1), 71-74. Smith, M. s., & Tiedje, J. M. (1979). The effect of roots on soil denitrification. Smith, V. R., Steenkamp, M., & French, D. D. (1993). SOIL DECOMPOSITION POTENTIAL IN RELATION TO ENVIRONMENTAL FACTORS ON MARION ISLAND. Su, S. (2012). Microbiological Resistance Properties of Geosynthetics and a Jute Fabric. Tiegs, S. D., Clapcott, J. E., Griffiths, N. A., & Boulton, A. J. (2013). A standardized cotton-strip assay for measuring organic-matter decomposition in streams. Ecological Indicators, 32, 131-139. Tulos, N., Harbottle, D., Hebden, A., Goswami, P., & Blackburn, R. S. (2019). Kinetic Analysis of Cellulose Acetate/Cellulose II Hybrid Fiber Formation by Alkaline Hydrolysis. ACS Omega, 4(3), 4936-4942. Velasco-Garcia, M. N., & Mottram, T. (2003). Biosensor Technology addressing Agricultural Problems. Biosystems Engineering, 84(1), 1-12 Vischetti, C., Casucci, C., De Bernardi, A., Monaci, E., Tiano, L., Marcheggiani, F., Ciani, M., Comitini, F., Marini, E., Taskin, E., & Puglisi, E. (2020). Sub-Lethal Effects of Pesticides on the DNA of Soil Organisms as Early Ecotoxicological Biomarkers. Front Microbiol, 11, 1892. Voicu, S. I., Condruz, R. M., Mitran, V., Cimpean, A., Miculescu, F., Andronescu, C., Miculescu, M., & Thakur, V. K. (2016). Sericin Covalent Immobilization onto Cellulose Acetate Membrane for Biomedical Applications. ACS Sustainable Chemistry & Engineering, 4(3), 1765-1774. VOS, K. D., O.BURRIS, F., JR., & RILEY, R. L. (1966). Kinetic Study of the Hydrolysis of Cellulose Acetate in the pH Range of 2-10. Wang, Y.-C. (2007). Effect of Surface Modification on the Electrochemical Properties of Screen-printed Carbon Paste Electrode. Wardle, D. A., & Ghan, A. (1995). CRITIQUE OF THE MICROBIAL METABOLIC QUOTIENT (qC02) AS A BIOINDICATOR OF DISTURBANCE AND ECOSYSTEM DEVELOPMENT. Webb, J. R., Pearce, N. J. T., Painter, K. J., & Yates, A. G. (2019). Hierarchical variation in cellulose decomposition in least-disturbed reference streams: a multi-season study using the cotton strip assay. Landscape Ecology, 34(10), 2353-2369. Weninger, T., Kamptner, E., Dostal, T., Spiegel, A., & Strauss, P. (2020). Detection of physical hazards in soil profiles using quantitative soil physical quality assessment in the Pannonian basin, Eastern Austria. International Agrophysics, 34(4), 463-471. West, N. M. (2000). Kodak and the Lens of Nostalgia. University of virginia Press. Wisniak, J. (2015). Paul Schützenberger. Educación Química, 26(1), 57-65. Wodsedalek, J. E., Andres, A. H., Makino, S., & Lande, O. (1964). Ammonium production in soil under waterlogged conditions as an index of nitrogen availability. Wongkaew, P., & Poosittisak, S. (2014). Diagnosis of Sugarcane White Leaf Disease Using the Highly Sensitive DNA Based Voltammetric Electrochemical Determination. American Journal of Plant Sciences, 05(15), 2256-2268. Yamazaki, S., Isoyama, K., & Shimizu, D. (2020). Visualization of ultraviolet irradiation using WO3-cellulose derivatives composite film. Optical Materials, 106. Zou, Y., Mason, M. G., Wang, Y., Wee, E., Turni, C., Blackall, P. J., Trau, M., & Botella, J. R. (2017). Nucleic acid purification from plants, animals and microbes in under 30 seconds. PLoS Biol, 15(11), e2003916.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/89188	-
dc.description.abstract	電容式感測器是電化學感測的方法之一，基於電極與液面之間的界面形成電容性質。電容式感測器具有成本低廉、反應快速、非侵入式、靈活性高的優點，但「絕緣性」極重要，若反應介面的絕緣不佳，將導致離子通透使感測系統短路或不穩定。網版印刷碳膠電極經常使用在電化學生物感測器系統中，其電路設計上彈性高，優點為成本低、製程簡單、一次性。現行土壤綜合能力檢測之研究利用綿狀條織物、木材、混合纖維、天然纖維等可降解材料，埋入土壤中進行長期性的降解試驗，透過機械應力的拉伸強度以及重量損失等，定義土壤的總體微生物量。為了簡化檢測土壤總體微生物量之量測方法，並且產生更有效率的量測模式，可以應用在各式理想實驗室條件下調配之溶液中，我們使用了電容式感測器並且結合網版印刷碳膠電極，藉由披覆醋酸纖維薄膜在量測點上作為降解材料，透過化學、酵素、化學加酵素的溶液中降解，並且實際在不同菌量的土壤中降解，得到電容響應和時間的關係，研究化學條件、碳循環酵素降解醋酸纖維薄膜的趨勢、速率等，研究薄膜降解後之電容響應與土壤碳源酵素的關聯性。我們提出了成熟的單層披覆薄膜製程，能夠維持一定的絕緣度，證實薄膜厚度53±2.23 μm 在Cap-sensor電容量測系統量測有效範圍內，且研究披覆薄膜的製程，藉由薄膜品質管理驗證披覆薄膜的穩定度高，經長期浸泡中性緩衝液中，薄膜在第35天電容值變化量0.04±0.03 %。後續在單純化學條件、化學加上酵素條件，將披覆醋酸纖維薄膜的網版印刷碳膠電極浸泡在溶液中，依時間間隔量測其電容響應。使用全反射傅立葉紅外光譜分析醋酸纖維薄膜經過時間的降解，C=O與C-O化性變化以及薄膜粗略性之厚度變化與電容響應的關係。最終展示在實際土壤中，先使用成熟的土壤微生物含量測定方法（二乙酸螢光素方法）驗證，且將披覆薄膜的網版印刷碳膠電極埋入不同菌量的土壤中，該電容式生物感測器測得的電容響應反應曲線有顯著差異，定義土壤總微生物量指標。本研究提出利用電容式感測器檢測土壤總微生物量，深入研究碳源酵素降解醋酸纖維薄膜的效力，相比於傳統有機質分解的檢測手法：使用拉伸應力、重量損失等方法測定分解袋、棉織物或木材，電容式感測器結合網版印刷碳膠電極披覆薄膜整合人機介面操作，使用者可以透過特定應用場景，切換適當的量測模組，並且即時讀取資料和匯出整理。因而達成即時、有效、快速且操作容易之感測器架構，對於土壤品質的評估和其他生物學方面具有研究潛力，不論是農業、環境監測或是生醫應用後續都是此項技術可以切入的場域。	zh_TW
dc.description.abstract	The capacitive sensor is one of the methods of electrochemical sensing, based on the capacitive nature of the interface between the electrode and the liquid surface. Capacitive sensors have the advantages of low cost, fast response time, non-intrusive, and high flexibility. However, insulation is crucial that poor insulation of the response interface can lead to ion penetration, short circuit, or instability of the sensing system. Screen-printed carbon electrode are commonly used in electrochemical biosensor systems due to their high flexibility in circuit design and the advantages of low cost, simple and disposable process. In the current study, degradable materials such as cotton, wood, mixed fibers, and natural fibers are buried in the soil and subjected to long-term degradation tests to determine the total microbial load of the soil through mechanical stress, tensile strength, and weight loss. In order to simplify the method of measuring the microbial load of soil and to produce a more efficient measurement model that can be applied to various solutions prepared under ideal laboratory conditions. We used a capacitive sensor combined with screen-printed carbon electrode to study the relationship between capacitive response and time by coating cellulose acetate film as degradation material at the measurement points, degradation by chemical, enzymatic, and chemical plus enzymatic solutions, and actual degradation in soil with different amounts of bacteria to study the chemical conditions, the trend and the rate of degradation of cellulose acetate film by carbon cycle enzymes, and the relationship between capacitive response and soil carbon cycle enzymes after cellulose acetate film degradation. The correlation between the capacitive response and soil carbon source enzymes was studied. We propose a mature single-layer cellulose acetate film process that can maintain a certain degree of insulation and confirm that the film thickness of 53±2.23 μm is within the effective range of measurement by the Cap-sensor capacitance measurement system. 0.03 % at day 35 after long term immersion in neutral buffer solution. Subsequently, the screen-printing carbon electrode coated with cellulose acetate film were immersed in the solution under pure chemical conditions and chemical plus enzymatic conditions, and the capacitive response was measured according to the time interval, and the relationship between the degradation of cellulose acetate film over time. Attenuated total reflectance fourier transform infrared spectroscopy was used to analyze the relationship between the degradation of acetate films over time, changes in C=O and C-O chemical properties, and changes in thickness of film roughness and capacitive response. The capacitive biosensor measured significant differences in the response curves of capacitive response to define the total microbial load of the soil, which was verified in real soil using a well-established method for soil microbial content determination (fluorescein diacetate method), and the screen-printed carbon electrodes coated with cellulose acetate films were buried in soil with different bacterial load. This study proposes the use of capacitive sensors to detect the total microbial load of soil and to investigate the effectiveness of carbon source enzymes in degrading cellulose acetate films. Compared with the traditional methods of organic decomposition: using tensile stress, weight loss, etc. to determine the decomposition of bags, cotton fabrics or wood. The capacitive sensors combined with screen-printed carbon electrode coated cellulose acetate film integrate human-machine interface operation, allowing users to switch between the appropriate measurement modules, and to read and export data in real time. This results in a real-time, effective, fast and easy-to-use sensor architecture with research potential for soil quality assessment and other biology applications, whether in agriculture, environmental monitoring or biomedical applications.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-08-30T16:15:06Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2023-08-30T16:15:06Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	國立台灣大學碩士學位論文口試委員會審定書..........................................................i 誌謝 ii 摘要 iii Abstract v 圖目錄 xii 表目錄 xv 第ㄧ章緒論 1 1.1 研究背景 1 1.2 研究目的 2 1.3研究架構 3 第二章文獻探討 5 2.1 土壤檢測 5 2.1.1 物理和化學檢測 7 2.1.1.1物理檢測 7 2.1.1.2化學檢測 7 2.1.2 微生物之檢測 9 2.1.2.1 有機質分解檢測微生物之活性 9 2.1.2.2 基礎呼吸率和土壤之代謝商數 11 2.1.2.3 土壤生態系中之土壤酵素 12 2.1.2.4 土壤微生物多樣性監測指標－特定量測方法 14 2.1.2.5 次世代定序 16 2.1.3 土壤生態系統指標對應之環境終端意義 17 2.2 醋酸纖維素 18 2.2.1 醋酸纖維素之歷史 18 2.2.2 醋酸纖維素之物理、化學特性 19 2.2.2.1溶解度、濁度、莫耳質量 19 2.2.2.2取代度 20 2.2.4 醋酸纖維素之降解 21 2.3 感測器 23 2.3.1感測器之定義 23 2.3.3電容式感測器 25 2.4 生物感測器應用於農業 28 2.4.2.1 基於DNA的生物感測器 29 2.4.2.2 基於伏安法的DNA雜交檢測 30 2.4.2.3基於酵素的生物感測器 30 2.4.2.4基於石英晶體微量天秤的生物感測器 30 2.4.2.5表面等離子共振技術 31 第三章研究方法 32 3.1 測量儀器軟體及披覆製程 32 3.1.1電化學分析方法簡介 32 3.1.2 電容式感測器工作原理 32 3.1.3 電容式感測器之架構 35 3.1.4 電容式量測模組－CIN1 EXCB & CIN2 EXCA 36 3.1.5 LabView人機介面設定 38 3.1.6 旋轉塗布之披覆製程 40 3.1.7 浸潤式披覆製程 40 3.2 實驗材料與溶液配置 41 3.2.1 實驗藥品 41 3.2.2 實驗儀器 42 3.2.3 實驗原理與方法 42 3.2.4 實驗量測步驟 43 3.3 網版印刷碳膠電極披覆薄膜製備 45 3.3.1 網版印刷碳膠電極 45 3.3.2 旋轉塗布披覆醋酸纖維薄膜 46 3.3.2 浸潤式披覆醋酸纖維薄膜 50 3.4 披覆薄膜之可行性評估 51 3.4.1 披覆薄膜之品質管理 51 3.4.2 披覆醋酸纖維薄膜之網版印刷碳膠電極的穩定性 52 3.5 醋酸纖維薄膜之物性與化性 52 3.5.1 醋酸纖維薄膜之物性分析 52 3.5.2 醋酸纖維薄膜之化性分析 53 3.6 披覆醋酸纖維薄膜的網版印刷碳膠電極之降解 54 3.6.1化學降解 54 3.6.2 酵素降解 54 3.6.3 土壤樣本降解 55 3.6.4 二乙酸螢光素方法分析土壤中微生物含量 57 3.6.5 包埋網版印刷碳膠電極之機構設計 58 第四章結果與討論 61 4.1 電容式量測模組 61 4.1.1 CIN1 EXCB模組系統校正 61 4.1.2 CIN2 EXCA 模組系統校正 62 4.2 披覆製程之選擇 64 4.2.1 旋轉塗布披覆 64 4.2.2 浸潤式披覆 66 4.2.3 醋酸纖維薄膜在中性溶液中的穩定性 68 4.3 化學降解 69 4.4 醋酸纖維薄膜降解過程的物性、化性分析 71 4.4.1 物性分析：醋酸纖維薄膜厚度與電容值響應的關係 71 4.4.2 物性分析：表面型態量測與醋酸纖維薄膜厚度測定 73 4.4.3 化性分析：醋酸纖維薄膜降解的全反射傅立葉紅外光譜儀分析 76 4.5 酵素降解 78 4.5.1 影響纖維酵素活性之pH探討 78 4.5.2 特定酵素的選擇性降解 81 4.5.3 纖維酵素、澱粉酵素、葡萄醣苷酵素之降解 83 4.5.4 模擬土壤環境pH值的酵素降解 87 4.6 披覆醋酸纖維薄膜的網版印刷碳膠電極在土壤環境之降解 93 4.6.1 二乙酸螢光素分析土壤總微生物量 93 4.6.2 土壤內披覆醋酸纖維薄膜之降解 96 第五章結論 100 5.1 結論 100 5.2 未來工作 102 參考文獻 103	-
dc.language.iso	zh_TW	-
dc.subject	電容式感測器	zh_TW
dc.subject	二乙酸螢光素方法	zh_TW
dc.subject	全反射傅立葉紅外光分析	zh_TW
dc.subject	土壤碳源酵素檢測	zh_TW
dc.subject	薄膜披覆製程	zh_TW
dc.subject	網版印刷碳膠電極	zh_TW
dc.subject	Capacitive sensor	en
dc.subject	Screen-printed carbon electrode	en
dc.subject	Coating film process	en
dc.subject	Soil carbon decomposition enzyme activity	en
dc.subject	ATR-FTIR	en
dc.subject	Fluorescein diacetate method	en
dc.title	披覆醋酸纖維薄膜之電容式感測系統應用於土壤碳源酵素活性之檢測	zh_TW
dc.title	A capacitive sensing system coated with cellulose acetate to detect the soil carbon decomposition enzyme activity	en
dc.type	Thesis	-
dc.date.schoolyear	111-2	-
dc.description.degree	碩士	-
dc.contributor.coadvisor	侯詠徳	zh_TW
dc.contributor.coadvisor	Yung-Te Hou	en
dc.contributor.oralexamcommittee	陳林祈;李達源;吳靖宙	zh_TW
dc.contributor.oralexamcommittee	Lin-Chi Chen;Dar-Yuan Lee;Ching-Chou Wu	en
dc.subject.keyword	電容式感測器,網版印刷碳膠電極,薄膜披覆製程,土壤碳源酵素檢測,全反射傅立葉紅外光分析,二乙酸螢光素方法,	zh_TW
dc.subject.keyword	Capacitive sensor,Screen-printed carbon electrode,Coating film process,Soil carbon decomposition enzyme activity,ATR-FTIR,Fluorescein diacetate method,	en
dc.relation.page	110	-
dc.identifier.doi	10.6342/NTU202301523	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2023-07-21	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	生物機電工程學系	-
dc.date.embargo-lift	2025-08-01	-
顯示於系所單位：	生物機電工程學系

文件中的檔案：

檔案	大小	格式
ntu-111-2.pdf	20.05 MB	Adobe PDF	檢視/開啟

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。