Nanowire Sensor Arrays for Detection of Nucleic Acid Molecules

用于检测核酸分子的纳米线传感器阵列

• 批准号: 7230295
• 负责人: Rashid Bashir
• 金额: $ 17.75万
• 依托单位: PURDUE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-04-01 至 2009-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7230295
• 关键词: Address; Adsorption; All Sites; Antibodies; Antigens; Area; Arts; Autoimmune Diseases; Be++ element; Beds; Beryllium; Binding; Biological; Biological Models; Biological Process; Biology; Biosensor; Boxing; Caliber; Carbon; Cells; Charge; Chemicals; Chemistry; Complex; Condition; DNA; DNA Probes; DNA Sequence; Deoxyribonucleotides; Detection; Deterioration; Device Designs; Devices; Diagnostic; Dimensions; Discipline; Disease; Electrodes; Elements; Environment; Epigenetic Process; Equilibrium; Figs - dietary; Foundations; Generations; Genetic; Goals; Health; Heating; Individual; Ions; Kinetics; Label; Lasers; Lead; Length; Liquid substance; Malignant Neoplasms; Maps; Measurement; Measures; Mediating; Medical; Medicine; MicroRNAs; Microfluidic Microchips; Microfluidics; Modeling; Modification; Nanotechnology; Nucleic Acids; Nucleotides; Numbers; Oligonucleotides; Optics; Organism; Peptide Nucleic Acids; Placement; Polyethylene Glycols; Principal Investigator; Proteins; RNA; Range; Reaction; Reagent; Reporting; Research; Research Personnel; Scheme; Semiconductors; Sequence Determination; Signal Transduction; Silicon; Single-Stranded DNA; Site; Source; Surface; Surface Properties; System; Systems Integration; Techniques; Technology; Temperature; Testing; Thinking; Time; Work; Xenobiotics; base; biochip; chemical reaction; concept; cost; density; design; design and construction; detector; electron beam lithography; high throughput analysis; innovation; latent nuclear antigen; liquid crystal; microorganism; miniaturize; model development; nano; nanobiotechnology; nanofabrication; nanoparticle; nanoscale; nanoscale research; nanosensors; nanowire; new technology; novel; nucleic acid detection; oxidation; predictive modeling; programs; receptor; research study; scale up; sensor; simulation; small molecule; tool; Address; Adsorption; All Sites; Antibodies; Antigens; Area; Arts; Autoimmune Diseases; Be++ element; Beds; Beryllium; Binding; Biological; Biological Models; Biological Process; Biology; Biosensor; Boxing; Caliber; Carbon; Cells; Charge; Chemicals; Chemistry; Complex; Condition; DNA; DNA Probes; DNA Sequence; Deoxyribonucleotides; Detection; Deterioration; Device Designs; Devices; Diagnostic; Dimensions; Discipline; Disease; Electrodes; Elements; Environment; Epigenetic Process; Equilibrium; Figs - dietary; Foundations; Generations; Genetic; Goals; Health; Heating; Individual; Ions; Kinetics; Label; Lasers; Lead; Length; Liquid substance; Malignant Neoplasms; Maps; Measurement; Measures; Mediating; Medical; Medicine; MicroRNAs; Microfluidic Microchips; Microfluidics; Modeling; Modification; Nanotechnology; Nucleic Acids; Nucleotides; Numbers; Oligonucleotides; Optics; Organism; Peptide Nucleic Acids; Placement; Polyethylene Glycols; Principal Investigator; Proteins; RNA; Range; Reaction; Reagent; Reporting; Research; Research Personnel; Scheme; Semiconductors; Sequence Determination; Signal Transduction; Silicon; Single-Stranded DNA; Site; Source; Surface; Surface Properties; System; Systems Integration; Techniques; Technology; Temperature; Testing; Thinking; Time; Work; Xenobiotics; base; biochip; chemical reaction; concept; cost; density; design; design and construction; detector; electron beam lithography; high throughput analysis; innovation; latent nuclear antigen; liquid crystal; microorganism; miniaturize; model development; nano; nanobiotechnology; nanofabrication; nanoparticle; nanoscale; nanoscale research; nanosensors; nanowire; new technology; novel; nucleic acid detection; oxidation; predictive modeling; programs; receptor; research study; scale up; sensor; simulation; small molecule; tool

DESCRIPTION (provided by applicant): The recent advances in nanotechnology and nanofabrication of semiconductor materials present themselves with new opportunities for miniaturized, ultra-sensitive, label-free, and parallel sensors capable of rapid and highly accurate analysis of biological and chemical entities. Silicon nanowire sensors, based on field effect modulation of current upon binding of molecules on the nanowire surface, have been successfully demonstrated for the detection of DNA and proteins in fluids on individual devices. However, these devices are still to be realized in an array format, in a robust manner using top-down fabrication techniques, with detection of multiple molecules. In this R21 proposal, we have assembled an interdisciplinary team with the goal of designing, producing, functionalizing, and testing the silicon nanowire sensor array. Our work will be motivated by, (a) the need to detect single stranded DNA molecules for sensing and diagnostic applications, and (b) detect microRNA (miRNA) from cell lysates, which have been recently shown to be indicative of diseases such as cancer. These goals will be accomplished by our team of researchers with expertise in nano-scale computation (Ashraf Alam), novel linker design and surface chemistry (Donald Bergstrom), and micro/nano-fabrication (Rashid Bashir). The following are the specific aims of the project: (i) Use novel nanoscale computation approaches to guide the design and fabrication of the nano-wire sensor elements, (ii) Develop novel top-down silicon fabrication techniques to produce nano-wire arrays within microfluidic devices, (iii) Develop novel techniques to functionalize the individual sensors in an array using laser or electrically mediated thermal exchange reactions, and (iv) Perform the detection experiments in an array of nanowires within a microfluidic biochip and explore the use of nano-particle (dendrimer) based charge amplification schemes. Each specific aim includes novel and innovative state-of-the-art nanoscale research with broad applications in the area of Nanobiotechnology.

描述（由申请人提供）：半导体材料的纳米技术和纳米制作的最新进展，为您提供了新的机会，可以快速且高度准确地分析生物学和化学实体的微型，超敏感，无标签和并行传感器。基于分子在纳米线表面结合的电流的现场效应调制的硅纳米线传感器已成功地证明了在单个设备上流体中DNA和蛋白质的检测。但是，使用自上而下的制造技术，这些设备仍应以稳健的方式以阵列格式实现，并检测多个分子。在此R21提案中，我们组装了一个跨学科团队，其目标是设计，生产，功能化和测试硅纳米线传感器阵列。 （a）需要检测单链DNA分子进行感测和诊断应用的动机，以及（b）检测细胞裂解液的microRNA（miRNA），最近已证明这些疾病表明了癌症等疾病。这些目标将由我们的研究人员团队实现，具有纳米级计算方面的专业知识（ASHRAF ALAM），新颖的接头设计和表面化学（Donald Bergstrom）和微型/纳米制作（Rashid Bashir）。 The following are the specific aims of the project: (i) Use novel nanoscale computation approaches to guide the design and fabrication of the nano-wire sensor elements, (ii) Develop novel top-down silicon fabrication techniques to produce nano-wire arrays within microfluidic devices, (iii) Develop novel techniques to functionalize the individual sensors in an array using laser or electrically mediated thermal exchange reactions, and （iv）在微流体生物芯片内的一系列纳米线中执行检测实验，并探索基于纳米颗粒（Dendrrimer）的电荷放大方案的使用。每个具体目的包括新颖和创新的最先进的纳米级研究，并在纳米局技术领域进行了广泛的应用。