奈米力學建構之感測器應用於生物分子辨識之研究

Rong-Zhang Hwang; 黃榮章

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完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	邵耀華,黃榮山
dc.contributor.author	Rong-Zhang Hwang	en
dc.contributor.author	黃榮章	zh_TW
dc.date.accessioned	2021-06-13T05:58:41Z	-
dc.date.available	2006-07-05
dc.date.copyright	2006-07-05
dc.date.issued	2006
dc.date.submitted	2006-06-27
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34220	-
dc.description.abstract	生物分子之辨識(biomolecular recognition)是生命體之自然特性，存在於核酸雜交反應、蛋白質與蛋白質交互作用、核酸與蛋白質交互作用、脂質與蛋白質交互作用、酵素與基質反應、細胞與配體鍵結等過程中，探究生物分子間辨識之特性有助於促進新的藥物之研發、生物技術方法之提升、新的治療診斷技術之開發。本論文研究已成功地將抗原與抗體間分子辨識之特性轉換至微型懸臂梁之奈米力學響應，透過晶片表面之化學修飾與生物分子固定化技術，以及感測元件之微製造技術，由生物膜引入奈米力學之換能機制以建立了一個可即時、免螢光、可定量檢測之生物感測器平台，應用於生物分子辨識之分析與生物醫學之診斷上。本論文研究，係利用奈米力學建構之生物感測器，首先成功地應用於疾病標記C反應蛋白(C-reactive protein)之即時檢測，此微型生物感測晶片與系統可定量檢測C反應蛋白於具臨床意義之濃度範圍(1-500 µg/mL)，並且實驗之結果具有高度重複性(repeatability, 7%)，以使得本系統可潛在成為急性發炎(inflammatory)或心血管疾病(cardiovascular disease)之臨床診斷技術。再者，電場操控於抗原－抗體複合物之分離以使感測表面再生(sensing surface regeneration)之技術已首次成功地引入於奈米力學建構之生物檢測系統中，本研究係施加低頻之交替電場於晶片感測面上以取代傳統感測面暴露於極酸環境(pH 2.5)的方法，以使本系統達成可重複檢測且微型化之目的。同時，電場操控於感測表面再生之技術相較於傳統方法不但可以減低蛋白質活性之喪失，也能提供相對高的感測表面再生效率，而且將使整個檢測系統能進一步微小化，並可潛在地解決目前生物感測器轉為植入式晶片之關鍵瓶頸問題。運用純熟之半導體工業技術，本研究更進一步成功地將無線傳輸CMOS元件整合於奈米力學建構之生物感測器中，並用以C反應蛋白之遠端即時地定量檢測，整個生物檢測系統預期將可微小化至CD隨身聽的大小，達成可攜式的目的，而可望應用於災區，如颶風與海嘯，或疫區之就地診斷，並由於微懸臂梁感測器與無線CMOS元件於材料與製程上具有高度相容性，故將可預期使整個系統整合於單一晶片上(system-on-chip)，而達到更進一步地微小化。總結，本研究中奈米力學建構之生物感測器已展現其廣泛之可應用性，相容於微電子技術之高度整合性，以及未來將可望朝向無線感測網絡(wireless sensor networks)之發展性。	zh_TW
dc.description.abstract	Biomolecular recognition is a natural characteristic in DNA hybridization, protein-protein interaction, DNA-protein interaction, lipid-protein interaction, enzyme-substrate reaction, and cell-ligand binding. Exploring the biomolecular recognition event facilitates the discovery of new drugs, biotechnological methods, and materials for therapeutics and diagnostics. This work has shown antibody-antigen recognition into a direct nanomechanical response of microfabricated cantilever beams. With the bottom-up technology in chemical surface treatment and biomolecular functionality, and the top-down microfabrication on physical devices, the biofilm-induced nanomechanical transduction establishes a biosensor platform in real-time, label-free, and quantitative analysis on biomolecular recognition and thus diagnostics. First of all, this nanomechanics-based biosensor demonstrates the real-time and in-vitro quantitative detection of disease-related C-reactive protein (CRP). A wide range of clinically relevant CRP concentrations from 1 to 500 µg/mL have been successfully measured with the repeatability of within 7 %, making this biosensor a potential diagnostic technique for inflammatory events or cardiovascular disease. In addition to successful biosensing, sensing surface regeneration is a washing process prior to re-use of biosensors in dissociation of antigen molecules out of anchored antibody. To cater to portability and miniaturization of biosensors in point-of-care applications, the physically electrical regeneration in replacement of highly acidic washing with no additional, sizable containers has been proven on separation of antibody-antigen complexes for nanomechanics-based biosensors. The advantageous feature of the electrical technique over the conventional treatment is evident in long-standing protein activity, providing a relatively high efficiency in dissociation, and miniaturization in entire bioassay system. Leveraging the mature semiconductor industry technology, this work successfully integrates the microcantilever biosensor with a wireless CMOS device for C-reactive protein detection and electrical regeneration. The entire bioassay system is expected in miniaturization to a size as small as a commercial CD player, and thus to be portable. Therefore, the portable biosensor system allows to be applied for on-site diagnosis to a remote area beyond hospital, for instances, in cases of hurricane and Tsunami. Owing to high compatibility of the microcantilever and standard-CMOS wireless device in terms of process and materials, the System-On-Chip (SOC)-based biosensor is highly expected and potentially miniaturized to a grain size for future implanted health monitoring. In summary, the nanomechanics-based immunoassay biosensor exhibits its broad applicability, effectiveness, high microelectronics integration, promising wireless sensor networks as well.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T05:58:41Z (GMT). No. of bitstreams: 1 ntu-95-F89543016-1.pdf: 7515019 bytes, checksum: 02f1fa12daf4d6faf3459333dfb94ac9 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	Abstract (English) …………………………………………………i Abstract (Chinese) ………………………………………………iii Acknowledgments ……………………………………………………v List of Figures …………………………………………………viii List of Tables ……………………………………………………xi Chapter 1 Introduction ……………………………………………1 1.1 Motivation and Innovation ……………………………………3 1.1.1 Bioassay of Disease-related Proteins …………………3 1.1.2 Reusable Biosensor with Electrical Manipulation ……4 1.1.3 Wireless Biomedical Detection ……………………………5 1.2 Thesis Organization ……………………………………………6 1.3 References ………………………………………………………7 Chapter 2 Biosensor Technology …………………………………9 2.1 Basic Working Principles of Biosensors …………………9 2.2 Classification of Biosensors ………………………………12 2.3 Biomolecular Recognition ……………………………………18 2.4 Principle of Antigen-Antibody Recognition ……………20 2.4.1 Structure of a Typical Antibody ……………………20 2.4.2 Interaction of Antibody with Specific Antigen …24 2.4.3 Affinity Theory …………………………………………26 2.5 References ………………………………………………………27 Chapter 3 Nanomechanics-based Biosensors ……………………30 3.1 Microcantilever-based Transduction Principle …………30 3.2 Mechanism of Cantilever Bending …………………………32 3.3 Cantilever Deflection Detection Techniques ……………34 3.4 Biosensing Applications ……………………………………37 3.4.1 Biofilm-induced Surface Stress Experiments ……37 3.4.2 Application to Genetic Analysis ……………………40 3.4.3 Application to Protein Analysis ……………………41 3.4.4 Other Applications ……………………………………44 3.5 References ………………………………………………………46 Chapter 4 Design and Implementation of Nanomechanics-based Bioassay ……………………………………………………53 4.1 Bioassay Device Design and Fabrication ………………54 4.2 Nanomechanics-based Biosensor Platform Setup…………58 4.3 Relationship of Biofilm-induced Stress with Cantilever Deflection ……………………………………………61 4.4 Device Surface Functionalization and Regeneration …65 4.4.1 Use of Self-assembled Monolayers ………………66 4.4.2 Immobilization Strategies …………………………67 4.4.3 Sensing Surface Regeneration ……………………72 4.5 Experimental Procedure Summary …………………………73 4.6 References ……………………………………………………75 Chapter 5 Nanomechanics-based Bioassay of C-Reactive Protein ...79 5.1 Characteristics of C-Reactive Protein ………………79 5.2 Biomolecular Recognition-induced Deflection Response …………………………………………………………………………82 5.3 Characterization of Antigen-Antibody Surface Morphology Using an Atomic Force Microscopy ………………89 5.4 Antigen-Antibody Intramolecular Characteristics …91 5.5 References ……………………………………………………92 Chapter 6 Reusable Nanomechanics-based Bioassay with Electrical Manipulation …………………………………………96 6.1 Introduction to Reusable Biosensor with Electrical Manipulation …………………………………………………………97 6.2 Design and Fabrication of a Reusable Nanomechanics-based Bioassay device ……………………………………………100 6.3 Characteristics of Immunoglobulin G ……………………102 6.4 Complete Historic Nanomechanical Response ……………104 6.5 Effects of Electric Polarization on Separation of Antigen-Antibody Complexes ……………………………………108 6.6 Dynamic Fluorescence Microscopic Observation ………112 6.7 References ……………………………………………………116 Chapter 7 Wireless Nanomechanics-based Biosensor for C-Reactive Protein Detection and Electrical Regeneration…118 7.1 Introduction to Wireless Biotelemetry System ……119 7.2 Wireless Nanomechanics-based Bio-detection System Setup …………………………………………………………………121 7.3 Wireless Amplitude Shift Keying System Architecture…………………………………………………………123 7.4 Nanomechanical Response of Wireless C- Reactive Protein Detection …………………………………………………127 7.5 References …………………………………………………130 Chapter 8 Conclusions and Future Work ………………………132 8.1 Conclusions …………………………………………………132 8.2 Future Work …………………………………………………134 8.2.1 Sensitivity Improvement for Blood Sample Measurement ……………………………………………134 8.2.2 Sensor Array for High-throughput Analysis …135 8.2.3 Biomedical Wireless Sensor Networks …………………138 8.3 References …………………………………………………139
dc.language.iso	en
dc.subject	生物分子之辨識	zh_TW
dc.subject	微懸臂梁生物感測器	zh_TW
dc.subject	蛋白質	zh_TW
dc.subject	Biomolecular recognition	en
dc.subject	Microcantilever-based biosensor	en
dc.subject	Protein	en
dc.title	奈米力學建構之感測器應用於生物分子辨識之研究	zh_TW
dc.title	A Study on Analysis of Biomolecular Recogntion Using a Nanomechanics-based Biosensor	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	呂學士,李世元,張正憲,林世明,賴信志
dc.subject.keyword	微懸臂梁生物感測器,生物分子之辨識,蛋白質,	zh_TW
dc.subject.keyword	Microcantilever-based biosensor,Biomolecular recognition,Protein,	en
dc.relation.page	141
dc.rights.note	有償授權
dc.date.accepted	2006-06-28
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
顯示於系所單位：	應用力學研究所

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