本研究對三維微流道無電極式介電泳晶片於微量蛋白質富集及快速偵測作系統化的數值模擬及實驗分析，首先利用多重物理量耦合軟體(COMSOL Multiphysics 5.3a)對三維微流道執行電動力學模擬，包括電場梯度、電滲流及介電泳力分析。模擬結果顯示在微流道中施予交流電240 Vpp/cm及10 kHz，流道隘口處的局部電場可高達107 V/m，可使鏈黴親和素蛋白質呈現正向介電泳力富集至流道隘口處。實驗晶片則利用微機電製程技術製作，晶片基板為載玻片(硼矽酸玻璃) 採用濕式玻璃蝕刻製作寬度500微米、深度1微米及隘口收縮間隙10微米之微流道，上蓋使用PDMS翻模製作寬度500微米及深度300微米流道，最後將玻璃基板與PDMS利用氧電漿清洗機進行表面改質接合完成晶片製作。此三維微流道比起傳統二維微流道有更大的樣品反應體積及高達15000倍之截面比。實驗結果顯示在交流電240 Vpp/cm及10 kHz條件下能將鏈黴親和素蛋白質在40秒內濃縮10^6倍。本研究提出之三維微流道無電極式介電泳晶片具有高電場濃縮倍率、低製作成本及樣品反應體積提升至mL優點可克服波生統計限制。

In this study, the numerical simulation and experimental analysis of enrichment and rapid detection of rare proteins in three-dimensional microchannel-based electrodeless dielectrophoresis chips were systematically performed. First, the commercial software (COMSOL Multiphysics 5.3a) was used to investigate the phenomena of electrokinetics, i.e., electric field gradient, electroosmotic flow and dielectrophoretic force. The simulation results indicate that the AC electric field set as 240 Vpp/cm and 10 kHz applied to the microchannel, the local electric field intensity at the insulating microconstriction structure could be as high as 107 V/m, which enabled the streptavidin protein to experience a positive dielectrophoretic force, and to be enriched to the microconstriction region. The chips were fabricated using MEMS technology, with a slide glass (borosilicate glass) used as the bottom substrate, where a wet glass etching technique was used to make the microchannel with a width of 500 microns, a depth of 1 micron, and a constriction gap of 10 microns. The PDMS layer structure by a replication process, a microchannel with a width of 500 microns and a depth of 300 microns was fabricated as the cover substrate. Finally, the glass substrate was bonded to a PDMS microchannel with two via holes with an oxygen plasma treatment to complete the chip. Compared to the conventional two-dimensional microchannel, the three-dimensional microchannel had a larger sample reaction volume and a cross-sectional ratio of up to 15,000 times. The experimental results show that at AC electric field set as 240 Vpp/cm and 10 kHz, the streptavidin protein could be concentrated to 10^6 times in 40 seconds. Overall, the proposed device provides a high local electric field intensity, a low-cost solution and overcomes the Poisson statistical limit owing to three-dimensional structure with a large capacity of a mL-scale sample volume.

摘要...i
Abstract...ii
誌謝...iv
目錄...v
表目錄...vi
圖目錄...vii
符號說明...ix
第一章 緒論...1
1.1前言...1
1.2研究動機與目的...1
1.3電動力學簡介...2
1.3.1電泳(Electrophoresis)...2
1.3.2電偶極化之誘發(Dipole)...3
1.3.3介電泳(Dielectrophoresis, DEP)...5
1.3.4電滲流((Electroosmosis flow, EOF)...7
1.4文獻回顧...8
第二章實驗設備與材料...14
2.1實驗設備...14
2.2 材料介紹...20
2.2.1 硼矽酸玻璃...20
2.2.2 聚二甲基矽氧烷 (Polydimethylsiloxane, PDMS)...20
2.2.3 鏈黴親和素蛋白質(Streptavidin)...20
第三章 晶片設計與製作...21
3.1晶片設計...21
3.2玻璃基板黃光微影製程...22
3.2.1 玻璃基板清洗...22
3.2.2旋塗HMDS及光阻S1813...23
3.2.3曝光...24
3.2.4顯影...24
3.3玻璃基板蝕刻及去光阻...24
3.3.1濕式蝕刻...24
3.3.2去光阻...24
3.4 PMMA加工及PDMS晶片製作...26
3.4.1 PMMA 壓克力加工...26
3.4.2 PDMS上蓋製作...27
3.5玻璃基板與PDMS改質接合...28
第四章 模擬分析...30
4.1建模...30
4.2電場數值模擬...32
4.3電滲流...34
4.4介電泳力...35
第五章實驗步驟與結果...38
5.1實驗步驟...38
5.2蝕刻載玻片玻璃基板...39
5.3蝕刻蓋玻片玻璃基板...41
5.4實驗架構...42
5.5利用介電泳晶片富集鏈黴親和素蛋白質...45
第六章結論...46
6.1結論...46
6.2未來展望...46
參考文獻...47
Extended Abstract...51

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