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Integrated Optical Particle Trap for Biomolecule Analysis and Manipulation

用于生物分子分析和操作的集成光学粒子阱

基本信息

批准号：
7826787
负责人：
Holger Schmidt
金额：
$ 18.02万
依托单位：
UNIVERSITY OF CALIFORNIA SANTA CRUZ
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-06-01 至 2012-05-31
项目状态：
已结题

项目摘要

DESCRIPTION (provided by applicant): Miniaturization is a growing trend for bioanalytical instruments. Integration of sensing, detection, and manipulation functionalities in a small space promises a new generation of inexpensive, portable and highly sensitive equipment that can benefit public health in many, possibly disruptive ways such as point-of-care devices in homes and medical practices or as rugged detectors for prevalent infectious diseases in underdeveloped countries. The long-term goals of our research are, therefore, to develop a new generation of optofluidic instruments in which both microfluidic and optical components are integrated in the plane of a single chip, thus allowing for smaller, less expensive, and more robust instruments. In addition, these instruments should possess exquisite sensitivity on the single-particle level. In this application, the development and characterization of integrated optical particle traps for all-optical manipulation of particles on a chip is proposed. Trapping and manipulation of bioparticles with light using optical tweezers has already led to a dramatic increase in our understanding of cells and molecules. The translation of these capabilities to a chip using integrated optics in lieu of high-end microscopes will enable their application to disease detection and other public health issues. The proposed research has two specific aims: Aim 1: A new type of integrated optical particle trap will be introduced and characterized. A trapping principle based on intrinsic properties of integrated waveguides will be implemented in liquid-core ARROW waveguides as the model optofluidic platform. The relevant trap properties such as trap strength and unique features that take advantage of its integrated nature will be characterized using inorganic microspheres as test particles. These studies will be complemented by analytical and numeric modeling. Aim 2: New bio-analytical capabilities on a chip using optical particle control will be demonstrated. Functional capabilities including particle concentration, single particle fluorescence, optically controlled particle binding and reactions in microenvironments will be demonstrated using representative biological particles including liposomes, E.coli bacteria, and DNA molecules. This will be achieved through the combination of the new trap properties with established techniques for waveguide design and fabrication, and sensitive optical detection. At the end of this project, all-optical particle control using integrated waveguides will have been firmly established as a new tool in optofluidics and major step towards next generation bio- analysis on a chip.

描述(申请人提供)：小型化是生物分析仪器日益发展的趋势。在一个狭小的空间中集成传感、检测和操纵功能有望产生新一代廉价、便携和高度敏感的设备，这些设备可以通过许多可能具有破坏性的方式造福公众健康，例如家庭和医疗实践中的看护点设备，或者作为不发达国家流行传染病的坚固检测器。因此，我们研究的长期目标是开发新一代光流控仪器，其中微流控和光学组件都集成在单个芯片的平面上，从而实现更小、更便宜和更坚固的仪器。此外，这些仪器应该在单粒子水平上具有精致的灵敏度。在这一应用中，提出了用于芯片上粒子的全光学操纵的集成光学粒子陷阱的开发和表征。使用光学镊子用光捕获和操纵生物粒子已经大大增加了我们对细胞和分子的理解。将这些能力转化为使用集成光学器件取代高端显微镜的芯片，将使它们能够应用于疾病检测和其他公共卫生问题。提出的研究有两个具体目标：目标1：介绍一种新型的集成光学粒子陷阱，并对其进行表征。基于集成光波导本征特性的捕获原理将在液芯箭头光波导中实现，作为模型光流控平台。将使用无机微球作为测试粒子来表征相关的捕集特性，例如捕集强度和利用其综合性质的独特特征。这些研究将得到分析和数值建模的补充。目标2：将展示使用光学粒子控制的芯片上的新生物分析功能。包括颗粒浓度、单颗粒荧光、光学控制颗粒结合和微环境中的反应在内的功能能力将使用包括脂质体、大肠杆菌和DNA分子在内的代表性生物颗粒来展示。这将通过将新的陷阱特性与现有的波导设计和制造技术以及灵敏的光学检测相结合来实现。在本项目结束时，利用集成波导的全光粒子控制将成为光流变学中的一种新工具，并朝着在芯片上进行下一代生物分析迈出了重要一步。