Fundamental studies in the temporal changes of light and sound scattering and absorption to generate new forms of biological and biomaterial contrast

对光和声音散射和吸收的时间变化进行基础研究，以产生新形式的生物和生物材料对比

• 批准号: RGPIN-2017-06496
• 负责人: Kolios, Michael
• 金额: $ 3.35万
• 依托单位: Ryerson University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=655828
• 关键词: Fundamental; studies; temporal; changes; light

The objective of the proposal is to develop techniques to characterise the structure and functional state of cells and tissues using optical, ultrasound and photoacoustic techniques. The investigator's work to date has focused on using optical and ultrasound scattering as a means to characterize cells and tissues, with a particular emphasis on the non-invasive detection of cell death. In the proposed work these techniques will be refined based on new knowledge generated from recent theoretical and experimental findings. Part of the proposed work would represent incremental, but important, improvements to these ultrasound and optical techniques. Based on our recent exciting findings related to the sound produced by cells absorbing light, the main novelty will be extending the techniques to include photoacoustic tissue characterization. To generate new contrast (producing images with new information), we will develop ultrasound and optical scattering measurements that include dynamic scattering measurements (fluctuations of scattering intensity as a function of time). For photoacoustics, fundamental questions as to the origin of the photoacoustic signal and how to characterize the signal when blood vessels are unresolved remain unanswered. For most clinically relevant ultrasound frequencies blood vessels of interest cannot be resolved. A new technique is required to analyze the photoacoustic signals that contain information about blood vessels and their integrity. New photoacoustic techniques will be developed which rely of the analysis of the frequency content of the photoacoustic waves. Techniques will be also developed based on the fluctuations of (optical / ultrasound/photoacoustic) signal intensity as a function of time, in a manner similar to classical dynamic light scattering techniques. We recently discovered that dying cells exhibit significantly shorter optical coherence tomography speckle decorrelation times (as well as ultrasound speckle decorrelation times), and that this can be used to assess intracellular motion of the dominant scattering sources in the cells / tissues. While the most common application relates to blood flow measurements, in these new techniques signals from blood are supressed to assess motion in tissues and cells alone. Advanced mathematical techniques will be used to extract relevant parameters for the characterization of this motion. We will investigate as to whether the same techniques can be applied to photoacoustic signals (not produced by scattering, but by optically absorbing tissue structures). The development of these of techniques will aid in the non-invasive and continuous monitoring of the functional states of cells and tissues, with potential applications in medicine.

该提案的目的是开发利用光学、超声和光声技术来表征细胞和组织的结构和功能状态的技术。迄今为止，研究人员的工作重点是使用光学和超声散射作为表征细胞和组织的手段，特别强调细胞死亡的非侵入性检测。在拟议的工作中，这些技术将根据最近的理论和实验发现产生的新知识进行改进。部分拟议的工作将代表增量，但重要的是，这些超声和光学技术的改进。基于我们最近与细胞吸收光产生的声音有关的令人兴奋的发现，主要的新奇将是将技术扩展到包括光声组织表征。为了生成新的对比度（生成具有新信息的图像），我们将开发包括动态散射测量（散射强度随时间变化的波动）的超声和光学散射测量。对于光声，光声信号的起源以及如何在血管未解决时表征信号的基本问题仍然没有答案。对于大多数临床相关的超声频率，无法分辨感兴趣的血管。需要一种新的技术来分析包含血管及其完整性信息的光声信号。将开发新的光声技术，其依赖于光声波的频率内容的分析。还将以类似于经典动态光散射技术的方式，基于（光学/超声/光声）信号强度随时间的波动来开发技术。 我们最近发现，垂死的细胞表现出显着更短的光学相干断层扫描散斑去相关时间（以及超声散斑去相关时间），这可以用来评估细胞/组织中的主要散射源的细胞内运动。虽然最常见的应用涉及血流测量，但在这些新技术中，来自血液的信号被抑制以单独评估组织和细胞中的运动。先进的数学技术将被用来提取相关的参数，这种运动的特性。我们将研究是否可以将相同的技术应用于光声信号（不是由散射产生的，而是由光学吸收组织结构产生的）。这些技术的发展将有助于非侵入性和连续监测细胞和组织的功能状态，在医学上具有潜在的应用。