Nanowire Enhanced Substrates for Microarrays

用于微阵列的纳米线增强基底

• 批准号: 6896519
• 负责人: R HUGH DANIELS
• 金额: $ 15.2万
• 依托单位: NANOSYS, INC.
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-06-01 至 2006-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6896519
• 关键词: biotechnology; glass; method development; microarray technology; nanotechnology; nucleic acid hybridization; oligonucleotides; protein binding; silicon; surface coating; surface property

DESCRIPTION (provided by applicant): Existing substrates for fluorescent microarray applications have many limitations including poor sensitivity, low dynamic range, variable spot uniformity and large feature sizes on mechanically spotted arrays. Despite these limitations the fluorescent microarray has become a major tool for large-scale genomic analyses and the emerging proteomic industry. Thus far, attempts to introduce new substrates have been unsuccessful, largely because of reduced kinetic performance and the requirements for major changes to the basic array fabrication and analysis infrastructure. In this program we will develop a novel, nano-enabled microarray substrate that will overcome all the major limitations of existing microarray substrates and yet will be entirely incompatible with existing hybridization protocols, array fabrication and analysis infrastructure. This technology is based upon our ability to control and pattern the growth of SiO2 coated, nanometer diameter wires on the surface of a planar substrate. This novel material provides dramatic increases in effective surface area and yet retains the basic chemical characteristics required for surface functionalization and assay development. In Phase I we will optimize the material and develop methods for depositing and patterning it on planar surfaces compatible with conventional array fabrication and scanning instrumentation. We will link oligonucleotide probes to the enhanced surface using conventional chemistries and hybridize fluorescent targets to these probes using standard protocols. We will optimize the performance of the nanowire enhanced substrates to achieve a 100-fold increase in signal intensity per unit area with a concomitant increase in dynamic range. Furthermore, we will decrease feature sizes on spotted arrays to well below currently achievable levels and at the same time increase the uniformity of the spotted probe. Finally we will demonstrate the broad utility of this substrate by developing a protein binding assay on the nanowire enhanced surface. Preliminary experiments on non-optimized materials indicate that these milestones will be achievable. Our long term aims are to demonstrate the compatibility of this performance enhancing substrate with all array fabrication approaches, to increase the density of spotted arrays to those now achieved by lithographically synthesized formats and finally to manufacture well characterized high density DNA and protein arrays to carry out large scale genomic (proteomic) analyses on this substrate.

描述（由申请人提供）：用于荧光微阵列应用的现有基底具有许多局限性，包括差的灵敏度、低动态范围、可变斑点均匀性和机械斑点阵列上的大特征尺寸。尽管存在这些局限性，荧光微阵列已成为大规模基因组分析和新兴蛋白质组学产业的主要工具。到目前为止，引入新基底的尝试尚未成功，主要是因为动力学性能降低以及需要对基本阵列制造和分析基础设施进行重大改变。在这个项目中，我们将开发一种新型的纳米微阵列基板，它将克服现有微阵列基板的所有主要限制，但与现有的杂交协议，阵列制造和分析基础设施完全不兼容。这项技术是基于我们的能力，控制和图案的SiO2涂层，纳米直径的线在平面基板的表面上的生长。这种新型材料提供了显着增加的有效表面积，但仍保留了表面功能化和测定开发所需的基本化学特性。在第一阶段，我们将优化材料，并开发出在平面上沉积和图案化材料的方法，这些方法与传统的阵列制造和扫描仪器兼容。我们将使用常规化学方法将寡核苷酸探针连接到增强的表面，并使用标准方案将荧光靶标与这些探针杂交。我们将优化纳米线增强基板的性能，以实现每单位面积信号强度增加100倍，同时动态范围也随之增加。此外，我们将减少斑点阵列的特征尺寸远低于目前可实现的水平，并在同一时间增加斑点探针的均匀性。最后，我们将展示这种基板的广泛用途，通过开发一个蛋白质结合测定纳米线增强表面。对非优化材料的初步实验表明，这些里程碑是可以实现的。我们的长期目标是证明这种性能增强基板与所有阵列制造方法的兼容性，将点样阵列的密度增加到现在通过光刻合成格式实现的密度，并最终制造出特征良好的高密度DNA和蛋白质阵列，以在该基板上进行大规模基因组（蛋白质组学）分析。