Adaptive Miniature Microscopy Platform for High Throughput Biological Imaging
用于高通量生物成像的自适应微型显微镜平台
基本信息
- 批准号:8638575
- 负责人:
- 金额:$ 22.77万
- 依托单位:
- 依托单位国家:美国
- 项目类别:
- 财政年份:2014
- 资助国家:美国
- 起止时间:2014-05-01 至 2016-04-30
- 项目状态:已结题
- 来源:
- 关键词:AgingAllyBiochemical ProcessBiologicalBiological AssayCaliberCategoriesClinicalCollaborationsCryingCustomDetectionDevelopmentDiagnosticDiagnostic ImagingDiseaseEducationElectrodesElectroplatingElementsFluorescenceFutureHandHealthHospitalsImageImage CytometryImaging TechniquesIndividualLettersLightLiquid substanceMalariaManualsMethodist ChurchMicrofluidicsMicroscopeMicroscopicMicroscopyMonitorOpticsPerformancePharmaceutical PreparationsPredispositionProceduresResearchResolutionRoentgen RaysSamplingShapesSlideSourceSpeedSurfaceSystemTechniquesTechnologyTextilesTranslationsTuberculosisTunaVisionVisualWorkbasecopingcostdesigndetectordigitalevaluation/testingimprovedinstrumentkinematicslenslithographymeetingsmillimeternovel strategiesperformance testspoint-of-care diagnosticsprototyperesearch studyscreeningstemtool
项目摘要
DESCRIPTION (provided by applicant): We propose the development of a new Adaptive Microscopy Platform (AMP) for Bio-Imaging. The AMP is a miniature array of tunable digital microscopes capable of working in multiple modes such as bright field, dark field, and fluorescence. This new platform will revolutionize the way high throughput and high-resolution imaging techniques are being applied, increasing screening/detection speed and lowering experimental costs. For example, the miniature platform can be used for inexpensive disease diagnostics, image cytometry, or be integrated with microfluidic systems to simultaneously monitor biochemical processes in multiple chambers. The AMP concept relies on embedding crucial microscope components in stackable tunable layers. Individual plates can contain an array of elements such as light sources, lenses, filters, and detectors. The focus of this project will be on the development of an array of tunable high-performance microscopes which will allow the user to easily adjust imaging parameters including magnification, field of view, resolution, and imaged region at the sample. This capability will be accomplished by controlling lens power and surface shape in layers of tunable optics. These changes can be applied individually for different microscopes and re-optimized to provide the highest optical performance. The individual AMP layers will be assembled using micro-fabricated, embedded kinematic mounts so no manual alignment will be necessary, while the design and stacking of AMP modules will be accommodated within fabrication tolerances. The system tunability will be based on building arrays of multi-electrode electrowetted lenses. The research will focus on two directions. (1) First the integrated array of a 1x4 microscope array will be built to use with TB slides and with a TB MODS culture assay. The system will combine custom static and commercial active components and will allow defocus, magnification change and optimization of system performance. Components of this adaptive array will provide 0.5 NA (Numerical Aperture) with an average FOV (Field of View) of 0.5 mm, focusing range of +/-100 microns (in object space) and approximately 2 fold magnification change (allowing adjusting further FOV). The system will be evaluated with a number of standard evaluation tests (resolution targets, slanted edge technique etc.), as well as through imaging of TB (smear) slides and MODS culture assays. (2) In parallel we will work on a multi-electrode tunable lens to enable a demonstrator objective with high > 0.8 NA.
描述(由申请人提供):我们提出了一种新的自适应显微镜平台(AMP)的生物成像的发展。AMP是一种微型可调数字显微镜阵列,能够在亮场、暗场和荧光等多种模式下工作。 这个新平台将彻底改变高通量和高分辨率成像技术的应用方式,提高筛查/检测速度,降低实验成本。 例如,微型平台可用于廉价的疾病诊断、图像细胞术,或与微流体系统集成以同时监测多个腔室中的生化过程。AMP概念依赖于在可堆叠的可调层中嵌入关键的显微镜组件。单个板可以包含一系列元件,如光源、透镜、滤光器和检测器。该项目的重点将是开发一系列可调高性能显微镜,使用户能够轻松调整成像参数,包括放大率,视场,分辨率和样品处的成像区域。这种能力将通过控制透镜功率和可调光学器件层中的表面形状来实现。这些变化可以单独应用于不同的显微镜,并重新优化,以提供最高的光学性能。各个AMP层将使用微制造的嵌入式运动支架组装,因此不需要手动对齐,而AMP模块的设计和堆叠将在制造公差范围内进行调整。 系统的可调谐性将基于构建多电极电润湿透镜阵列。 研究将集中在两个方向。(1)首先,将构建1x 4显微镜阵列的集成阵列,以与TB载玻片和TB MODS培养测定一起使用。该系统将结合联合收割机定制的静态和商业活动组件,并将允许散焦,放大倍率的变化和系统性能的优化。 该自适应阵列的组件将提供0.5 NA(数值孔径),平均FOV(视场)为0.5 mm,聚焦范围为+/-100微米(物方),放大率变化约为2倍(允许进一步调整FOV)。 该系统将通过一系列标准评估测试(分辨率目标、倾斜边缘技术等)进行评估,以及通过TB(涂片)载玻片成像和MODS培养测定。(2)与此同时,我们将研究一种多电极可调透镜,以实现NA> 0.8的演示物镜。
项目成果
期刊论文数量(0)
专著数量(0)
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会议论文数量(0)
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