利用數位微流體平台進行聚合酶鏈鎖反應及數位聚合酶鏈鎖反應

Kai-Mao Cheng; 鄭凱懋

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/73452

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	范士岡(Shih-Kang Fan)
dc.contributor.author	Kai-Mao Cheng	en
dc.contributor.author	鄭凱懋	zh_TW
dc.date.accessioned	2021-06-17T07:35:42Z	-
dc.date.available	2024-05-10
dc.date.copyright	2019-05-10
dc.date.issued	2019
dc.date.submitted	2019-04-25
dc.identifier.citation	[1]J. F. Huggett, C. A. Foy, V. Benes, K. Emslie, J. A. Garson, R. Haynes, J. Hellemans, M. Kubista, R. D. Mueller, T. Nolan, M. W. Pfaffl, G. L. Shipley, J. Vandesompele, C. T. Wittwer and S. A. Bustin. “The Digital MIQE Guidelines: Minimum Information for Publication of Quantitative Digital PCR Experiments.” Clin Chem., vol. 59, pp. 892-902, 2013. [2]G. Lippmann. “Relations entre les phénomènes électriques et capillaires.” Annales de Chimie et de Physique, pp. 494-549, 1875. [3]M. Gerovich and A. Frumkin. “Electrical Properties of Films of ω‐Bromo‐Hexadecanoic Acid.” J. Phys. Chem., vol. 4, pp. 624, 1936. [4]G. Beni and S. Hackwood. “Electro-wetting displays.” Appl. Phys. Lett., Vol. 38, pp. 207-209, 1981. [5]S. K. Cho, H. Moon, and C. J. Kim. “Creating, transporting, cutting, and merging liquid droplets by electrowetting-based actuation for digital microfluidic circuits.” J. Microelectromech. Syst., vol. 12, pp. 70-80, 2003. [6]K.F. Mullis, F. Faloona, S. Scharf, R. Saiki, G. Horn and H. Erlich. “Specific enzymatic amplification of DNA in vitro: The polymerase chain reaction.” cold spring harb symp quant biol, vol. 51, pp. 263–273, 1986. [7]C. Zhang, D. Xing. “Miniaturized PCR chips for nucleic acid amplification and analysis: latest advances and future trends.” Nucleic Acids Res., vol. 35, pp. 4223- 4237, 2007. [8]M. U. Kopp, A. J. de Mello and A. Manz. “Chemical Amplification: Continuous-Flow PCR on a Chip.” sci., vol. 280, pp. 1046-1048, 1998. [9]D. Moschou, N. Vourdas, G. Kokkoris, G. Papadakis, J. Parthenios, S. Chatzandroulis and A. Tserepi. “All-plastic, low-power, disposable, continuous-flow PCR chip with integrated microheaters for rapid DNA amplification.” Sens. Actuators. B, vol. 199, pp. 470-478, 2014. [10]S. Li, D. Y. Fozdar, M. F. Ali, H. Li, D. Shao, D. M. Vykoukal, J. Vykoukal, P. N. Floriano, M. Olsen, J. T. Mcdevitt, P. R. C. Gascoyne and S. Chen. ” A Continuous- Flow Polymerase Chain Reaction Microchip With Regional Velocity Control.” J. Microelectromech. Syst., vol. 15, pp. 223-236, 2006. [11]K. Sun, A. Yamaguchi, Y. Ishida, S. Matsuo and H. Misawa. “A heater-integrated transparent microchannel chip for continuous-flow PCR.” Sens. actuators. B Chem., vol. 84, pp. 283-289, 2002. [12]Z. X. Guo, X. Wu, W. Chen, F. Cui, W. Zhang and W. Liu. “Polymerase chain reaction chip with microchannel of glass capillaries embedded” Electron. Lett., vol. 51, pp. 1748-1750, 2015. [13]L. T. L. Trinh, H. Zhang, D. J. Kang, S. H. Kahng, B. D. Tall, N. Y. Lee. “Fabrication of Polymerase Chain Reaction Plastic Lab-on-a-Chip Device for Rapid Molecular Diagnoses.” Int. Neurourol J., vol. 20, pp. 38-48, 2016. [14]Y. H. Chang, G. B. Lee, F. C. Huang, Y. Y. Chen and J. L. Lin. “Integrated polymerase chain reaction chips utilizing digital microfluidics.” Biomed. Microdevices, vol. 8, pp. 215-225, 2006. [15]Z. S. Hua, J. L. Rouse, A. E. Eckhardt, V. Srinivasan, V. K. Pamula, W. A. Schell, J. L. Benton, T. G. Mitchell and M. G. Pollack. “Multiplexed Real-Time Polymerase Chain Reaction on a Digital Microfluidic Platform.” Anal. Chem., vol. 82, pp. 2310-2316, 2010. [16]A. Rival, D. Jary, C. Delattre, Y. Fouillet, G. Castellan, A. Bellemin-Comte and X. Gidrol. “An EWOD-based microfluidic chip for single-cell isolation, mRNA purification and subsequent multiplex qPCR.” Lab Chip, vol. 14, pp. 3739-3749, 2014. [17]R. Prakash, K. Pabbaraju, S. Wong, A. Wong, R. Tellier and K. V. I. S. Kaler. “Droplet microfluidic chip based nucleic acid amplification and real-time detection of influenza viruses.” J. Electrochem. Soc., 161, 3083–3093, 2014. [18]陳安得，DNA萃取和即時聚合酶鏈鎖反應於數位微流體晶片，國立臺灣大學工學院機械工程學系碩士論文，民國105年。 [19]X. J. Bian, F. X. Jing, G. Li, X. Y. Fan, C. P. Jia, H. B. Zhou, Q. H. Jin and J. L. Zhao. “A microfluidic droplet digital PCR for simultaneous detection of pathogenic Escherichia coli O157 and Listeria monocytogenes.” Biosens. Bioelectron., vol. 74, pp. 770-777, 2015. [20]T. D. Rane, L. Chen, H. C. Zec and T. H. Wang. “Microfluidic continuous flow digital loop-mediated isothermal amplification (LAMP).” Lab Chip, vol. 15, pp. 776-782, 2015. [21]F. Schuler, F. Schwemmer, M. Trotter, S. Wadle, R. Zengerle, F. V. Stetten and N. Paust. “Centrifugal step emulsification applied for absolute quantification of nucleic acids by digital droplet RPA.” Lab Chip, vol. 15, pp. 2759-2766, 2015. [22]W. W. Liu, Y. Zhu, Y. M. Feng, J. Fang and Q. Fang. “Droplet-Based Multivolume Digital Polymerase Chain Reaction by a Surface-Assisted Multifactor Fluid Segmentation Approach.” Anal Chem, vol. 89, pp. 822-829, 2017. [23]F. Shen, W. Du, J. E Kreutz, A. Fok and F. Ismagilov. “Digital PCR on a SlipChip” Lab Chip, vol. 10, pp. 2666-2672, 2010. [24]F. Shen, E. K. Davydova, W. Du, J. E. Kreutz, O. Piepenburg, and R. F. Ismagilov. “Digital Isothermal Quantification of Nucleic Acids via Simultaneous Chemical Initiation of Recombinase Polymerase Amplification Reactions on SlipChip.” Anal. Chem., vol. 83, pp. 3533-3540, 2011. [25]S. O. Sundberg, C. T. Wittwer, L. Zhou, R. Palais, Z. Dwight and B. K. Gale. “Quasidigital PCR: Enrichment and quantification of rare DNA variants.” Biomed. Microdevices, vol. 16, pp. 639-644, 2014. [26]S. O. Sundberg, C. T. Witter, C. Gao and B. K. Gale. “Spinning Disk Platform for Microfluidic Digital Polymerase Chain Reaction.” Anal. Chem., vol. 82, pp. 1546-1550, 2010. [27]Q. Zhu, Y. Gao, B. Yu, H. Ren, L. Qiu, S. Han, W. Jin, Q. Jin and Y. Mu. “Self-priming compartmentalization digital LAMP for point-of-care.” Lab Chip, vol. 12, pp. 4755-4763, 2012. [28]A. Ganson, A. M. Herrick, I. K. Dimov, L. P. Lee and D. T. Chiu. “Digital LAMP in a sample self-digitization (SD) chip.” Lab Chip, vol. 12, pp. 2247-2254, 2012. [29]T. Schneider, G. S. Yen, A. M. Thomson, D. R. Burnham and D. T. Chiu. “Self-Digitization of Samples into a High-Density Microfluidic Bottom-Well Array.” Anal. Chem., vol. 85, pp. 10417-10423, 2013. [30]D. E. Cohen, T. Schneider, M. Wang and D. T. Chiu. “Self-Digitization of Sample Volumes.” Anal. Chem., vol. 82, pp. 5707-5717, 2010. [31]Q. Zhu, L. Qiu, B. Yu, Y. Xu, Y. Gao, T. Pan, Q. Tian, Q. Song, W. Jin, Q. Jin and Y. Mu. “Digital PCR on an integrated self-priming compartmentalization chip.” Lab Chip, vol. 14, pp. 1176-1185, 2014. [32]A. Ganson, A. M. Herrick, I. K. Dimov, L. P. Lee and D. T. Chiu. “Digital LAMP in a sample self-digitization (SD) chip.” Lab Chip, vol. 12, pp. 2247-2254, 2012. [33]J. Heikenfeld, K. Zhou, E. Kreit, B. Raj, S. Yang, B. Sun, A. Milarcik, L. Clapp and R. Schwartz “Electrofluidic displays using Young–Laplace transposition of brilliant pigment dispersions.” Nat. Photonics, vol. 26, pp. 292-296, 2009. [34]Q. Zhu, Y. Xu, L. Qiu, C. Ma, B. Yu, Q. Song, W. Jin, Q. Jin, J. Liu and Y. Mu. “A scalable self-priming fractal branching microchannel net chip for digital PCR.” Lab Chip, vol. 17, pp. 1655-1665, 2017. [35]Y. Matsubara, K. Kerman, M. Kobayashi, S. Yamamura, Y. Morita and E. Tamiya. “Microchamber array based DNA quantification and specific sequence detection from a single copy via PCR in nanoliter volumes.” Biosens. Bioelectron., vol. 20, pp. 1482-1490, 2005. [36]Y. Zhang, Y. Zhu, B. Yao and Q. Fang. “Nanolitre droplet array for real time reverse transcription polymerase chain reaction.” Lab Chip, vol. 11, pp. 1545-1549, 2011. [37]L. Z. Chen, X. G. Fan and J. M. Gao. “Detection of HBsAg, HBcAg, and HBV DNA in ovarian tissues from patients with HBV infection.” World J. Gastroenterol., vol. 11, pp. 5565-5567, 2005. [38]J. T. Huang, Y. J. Liu, J. Wang, Z. G. Xu, Y. Yang, F. Shen, X. H. Liu, X. Zhou and S. M. Liu. “Next Generation Digital PCR Measurement of Hepatitis B Virus Copy Number in Formalin-Fixed Paraffin-Embedded Hepatocellular Carcinoma Tissue.” Clin. Chem., vol. 61, pp. 290-296, 2015. [39]K. S. Thress, R. Brant, T. H. Carr, S. Dearden, S. Jenkins, H. Brown, T. Hammett, M. Cantarini and J. C. Barrett. “EGFR mutation detection in ctDNA from NSCLC patient plasma: A cross platform comparison of leading technologies to support the clinical development of AZD9291.” Lung cancer, vol. 90, pp. 509-515, 2015. [40]Q. Yu, F. Huang, M. Zhang, H. Ji, S. Wu, Y. Zhao, C. Zhang, J. Wu, B. Wang, B. Pan, X. Zhang, W. Guo. “Multiplex picoliter-droplet digital PCR for quantitative assessment of EGFR mutations in circulating cell-free DNA derived from advanced non-small cell lung cancer patients.” Mol Med Rep., vol. 16, pp. 1157-1166, 2017. [41]C. J. Elkin, S. B. Brown, S. N. Nasarabadi, R. G. Langlois, F. P. Milanovich, and B. W. Colston Jr. “A Reusable Flow-Through Polymerase Chain Reaction Instrument for the Continuous Monitoring of Infectious Biological Agents.” Anal. Chem., vol. 75, pp. 3446-3450, 2003. [42]J. Waggoner, D.Y. Ho, P. Libiran, B.A. Pinsky. “Clinical significance of low cytomegalovirus DNA levels in human plasma.” J. Clin. Microbiol., vol. 50, pp. 2378-2383, 2012. [43]Y. Cao, M. R. Raith, J. F. Griffith. “Droplet digital PCR for simultaneous quantification of general and human-associated fecal indicators for water quality assessment.” Water Res., vol. 70, pp. 337-349, 2014. [44]W. Adamson. “Physical Chemistry of Surface, Sixth ed, John Wiley & Son” pp. 354, 1967. [45]S. K. Fan, P. W. Huang, T. T. Wang and Y. H. Peng. “Cross-scale electric manipulations of cells and droplets by frequency-modulated dielectrophoresis and electrowetting.” Lab Chip, vol. 8, pp. 1325-1331, 2008. [46]D. Gennes, P. Gilles, F. B. Wyart and D. Quere. “Capillarity and Wetting Phenomena. Springer” pp. 7–8, 2004. [47]S. K. Fan, Y. W. Hsu and C. H. Chen. “Encapsulated droplets with metered and removable oil shells by electrowetting and dielectrophoresis.” Lab Chip, vol. 11, pp. 2500-2508, 2011. [48]C. Lui, N. C. Cady and C. A. Batt. “Nucleic Acid-based Detection of Bacterial Pathogens Using Integrated Microfluidic Platform Systems.” Sensor, vol. 9, pp. 3713-3744, 2009. [49]N. A. Campbell, J. B. Reece and L. G. Mitchell. “Biology” Addison Wesley Longman Inc, 1999. [50]P. T. Cagle, T. C. Allen. “Basic Concepts of Molecular Pathology.” Arch. Pathol. Lab. Med., vol. 132, pp. 1551-1556, 2008. [51]A. S. Basu “Digital Assays Part I: Partitioning Statistics and Digital PCR” SLAS Technol, vol. 22, pp. 369-386, 2017. [52]S. Dube, J. Qin, R. Ramakrishnan. “Mathematical Analysis of Copy Number Variation in a DNA Sample Using Digital PCR on a Nanofluidic Device.” PLoS One, vol. 3, pp. 1-9, 2008. [53]Bio-Rad Corporation. “Droplet Digital PCR Applications Guide.” pp. 94-96, 2014. [54]A. S. Whale, J. F. Huggett, S. Cowen, V. Speir, J. Shaw, S. Ellison, C. A. Foy and D. J. Scott. “Comparison of microfluidic digital PCR and conventional quantitative PCR for measuring copy number variation.” Nucleic Acids Res., vol. 40, pp. 82-91, 2012. [55]T. Pfohl, J. H. Kim, M. Yasa, H. P. Miller, G. C. L. Wong, F. Bringezu, Z. Wen, L. Wilson, M. W. Kim, Y. Li, and C. R. Safinya. “Controlled Modification of Microstructured Silicon Surfaces for Confinement of Biological Macromolecules and Liquid Crystals.” Langmuir, vol. 17, pp. 5343-5351, 2001. [56]Y. W. Yi, H. G. Robinson, S. Knappe, J. E. Maclennan, C. D. Jones and C. Zhu, N. A. Clark and J. Kitching. “Method for characterizing self-assembled monolayers as antirelaxation wall coatings for alkali vapor cells.” J. APPL. PHYS., vol. 104, pp. 023534, 2008. [57]B. Boddinghaus, T. A. Wichelhaus, V. Brade and T. Bittner. “Removal of PCR Inhibitors by Silica Membranes: Evaluating the Amplicor Mycobacterium tuberculosisKit.” J. Clin. Microbiol., vol. 39, pp. 3750-3752, 2001.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/73452	-
dc.description.abstract	本研究希望可以利用數位微流體平台 (Digital microfluidic platform, DMF)操控含有B型肝炎病毒DNA (HBV DNA)的奈升等級試劑，進行聚合酶鏈鎖反應 (Polymerase chain reaction, PCR)。PCR，是一種利用人工的方式進行指定序列的DNA倍增技術。在實驗中，含有HBV DNA的PCR試劑將會被利用移液器加入到數位微流體晶片上。接著利用介電濕潤力 (Electrowetting on dielectric, EWOD)進行試劑的移動並且藉由黏附在晶片背部的加熱片形成晶片上不同的溫度區間。使試劑可以在不同的溫度區間內運動，並達成DNA指定序列放大之結果。其濃度會以螢光測量的方式進行實驗數據的驗證。在本次的實驗當中，PCR每圈所需時間為50秒並且僅需要100 nL的試劑體積即可完成，不論是在速度上及所需體積上都優於傳統PCR的表現。另外，本研究也期望可以操作另一項PCR的延伸應用，數位聚合酶鏈鎖反應 (Digital polymerase chain reaction, dPCR)。其可以利用大量分散的微小液滴進行DNA絕對濃度的估算，是一項相當具有潛力的技術。因此本研究期望可以藉由dPCR檢測因服用抗肺癌藥物所產生之突變基因T790M。本文是利用油水介面的表面張力進行大量且快速的液體分散，快速的在4秒內進行22500個微孔洞的液體分散後，利用加熱系統進行升降溫使每個獨立的分散液體進行dPCR，並在濃度為1818 copies/μL的DNA濃度下成功的進行PCR反應。但在未來，期望這項技術在未來可以與數位微流體平台進行結合發展出含有DNA萃取技術的dPCR的Point of care (POC)技術。	zh_TW
dc.description.abstract	In this research, we applied PCR on Digital microfluidic platform (DMF) by manipulating the droplet with HBV virus DNA in different temperature region. PCR is an artificial way to increase the special sequence in DNA structure. In this experiment the PCR reagent with HBV virus DNA was put on DMF platform by the pipetteman. Then the EWOD force moved the reagent in different temperature region which was generated from the heating film adhered on the back side of the chip and performed the PCR on EMF platform. The experimental results were confirmed by the fluorescence of the droplet. when the concentraction of the DNA solution got higher, the fluorescent of the solution became stronger. The reagent cost in this experiment was about 100 nL, and the cycle time was about 50 seconds. Both two parameters are better than traditional PCR. There were also another experiments in this research, Digital PCR (dPCR). It is an advanced version of the PCR. dPCR had ability to get the absolute concentraction of the DNA solution by analyzing lots of nano-droplets, therefore, it is a powerful technique. In this research, we applied the silicon chip with the microwell array on non-small cell lung cancer diagnosis. PCR solution was loaded in the reservoir then dispensed by injection method and dispensed in 4 seconds. After droplet dispensing, the chip will be put into the heating system to carry out the PCR process. Then the DNA concentration can be calculated by Poisson distribution. In this experiment DNA concentration detection limit can approach to 1818 copies/μL.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T07:35:42Z (GMT). No. of bitstreams: 1 ntu-108-R05522319-1.pdf: 4550116 bytes, checksum: 9b337bb5599f92ffd5797f958a794a22 (MD5) Previous issue date: 2019	en
dc.description.tableofcontents	致謝......................................i 中文摘要 ..................................ii ABSTRACT..................................iii 目錄.......................................iv 圖目錄.....................................viii 表目錄.....................................xii 第一章緒論...............................1 1.1 研究背景...............................1 1.2 文獻回顧...............................5 1.2.1 數位微流體平台........................5 1.2.2 聚合酶鏈鎖反應........................6 1.2.3 數位聚合酶鏈鎖反應....................10 1.2.4 利用矽晶圓微孔洞晶片進行聚合酶鏈鎖反應..18 1.2.5 利用PCR技術進行HBV檢測................20 1.2.6 利用dPCR技術進行NSCLC檢測.............21 1.2.7 技術比較..............................22 1.3 研究動機及目標..........................25 第二章理論介紹............................26 2.1 介電濕潤................................26 2.2聚合酶鏈鎖反應............................30 2.3 加熱片原理...............................34 2.4 數位聚合酶鏈鎖反應........................36 第三章實驗架設與材料介紹....................42 3.1 晶片製程.................................42 3.1.1數位微流體晶片..........................42 3.1.2 dPCR晶片..............................46 3.2 實驗架設.................................49 3.2.1 PCR實驗架設............................49 3.2.2數位聚合酶鏈鎖反應實驗架設................51 3.3 實驗材料介紹..............................56 第四章實驗結果與討論........................60 4.1 PCR......................................60 4.1.1 PCR試劑校正.............................60 4.1.2 PCR溫度控制.............................60 4.1.3 PCR油相環境選擇.........................63 4.1.4 PCR實驗結果.............................65 4.1.5利用核殼液滴結構進行PCR...................66 4.2 dPCR.....................................68 4.2.1 矽晶圓微孔洞陣列晶片.....................68 4.2.2數位聚合酶鏈鎖反應液滴分散.................69 4.2.2.1利用微流體幫浦進行液體分散...............69 4.2.2.2利用介電濕潤力在微孔洞陣列中進行液體分散..74 4.2.2.3利用介電濕潤力在SU-8微孔洞陣列中進行液體分散.76 4.2.3 dPCR測試結果............................77 4.2.3.1 溫度量測..............................77 4.2.3.2 孔洞表面積體積比過大...................78 4.2.3.3 dPCR試劑校正..........................79 4.2.3.4 dPCR測定DNA濃度.......................81 第五章結論與未來展望.........................83 5.1結論.......................................83 5.2未來計畫...................................83 參考文獻......................................85
dc.language.iso	zh-TW
dc.title	利用數位微流體平台進行聚合酶鏈鎖反應及數位聚合酶鏈鎖反應	zh_TW
dc.title	PCR and Digital PCR on Digital Microfluidic Platform	en
dc.type	Thesis
dc.date.schoolyear	107-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	張鈺(Yu Chang),盧彥文(Yen-Wen Lu)
dc.subject.keyword	數位微流體晶片,B型肝炎,非小細胞肺癌,介電濕潤,PCR,dPCR,微孔洞陣列,	zh_TW
dc.subject.keyword	Digital microfluidics,HBV,Non-small cell lung cancer,Electrowetting-on-dielectric,Polymerase chain reaction,Digital polymerase chain reaction,Micro-well array,	en
dc.relation.page	91
dc.identifier.doi	10.6342/NTU201900726
dc.rights.note	有償授權
dc.date.accepted	2019-04-26
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	機械工程學研究所	zh_TW
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