Mapping Cancer Metabolism by Mid-infrared Photothermal Microscopy

通过中红外光热显微镜绘制癌症代谢图

基本信息

批准号：
10675665
负责人：
Ji-Xin Cheng
金额：
$ 39.08万
依托单位：
BOSTON UNIVERSITY (CHARLES RIVER CAMPUS)
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-09-20 至 2024-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10675665
关键词：
Address Amino Acids Amplifiers Area Atlas of Cancer Mortality in the United States Biopsy Carbohydrates Cells Cellular Metabolic Process Chemicals Cholesterol Cholesterol Esters Cisplatin Detection Development Diameter Digital Signal Processing Drug resistance Electronics Fatty Acids Fingerprint Frequencies Glucose Goals Image Imaging Device Lateral Lighting Lipids Lipoproteins Location Malignant Neoplasms Malignant neoplasm of brain Malignant neoplasm of ovary Malignant neoplasm of prostate Maps Mass Spectrum Analysis Measurement Measures Mediating Metabolic Metabolism Microscope Microscopy Molecular NMR Spectroscopy Noise Nucleic Acids Organism Pathogenesis Pattern Performance Photons Physiologic pulse Play Predisposition Proteins Pump Raman Spectrum Analysis Refractive Indices Renal carcinoma Research Resistance Resolution Role Sampling Scanning Scheme Semiconductors Serum Signal Transduction Spectroscopy, Fourier Transform Infrared Speed Subcellular structure System Technology Testing Tissue Extracts Tissues Universities absorption cancer cell detection limit drug resistance development glucose uptake high resolution imaging imaging platform imaging system improved indexing infrared spectroscopy innovation leukemia lipid biosynthesis malignant breast neoplasm malignant mouth neoplasm metabolic imaging metal oxide microscopic imaging nanoparticle neoplastic cell oxidation programs refractory cancer submicron success tool tumor metabolism uptake vibration

项目摘要

Program Summary While altered cell metabolism is emerging as a hallmark of cancer, there is an unmet need for new tools for quantitation of metabolites. NMR spectroscopy, mass spectrometry, FTIR, and Raman spectroscopy are widely used for molecular detection in tissue extracts or intact tissues. Yet, these tools do not indicate the spatial locations of the analytes inside the cell. We address this unmet need via development of a lock-in free, wide- field mid-infrared photothermal (MIP) microscope. Our technology will enable quantitative vibrational imaging of metabolites in live tumor cells and intact biopsies. In MIP microscopy recently developed in the PI lab (Sci Adv 2016), a visible beam probes the thermal effect (e.g. change of refractive index and thermal expansion) induced by a pulsed infrared beam. The MIP signal is then extracted through a lock-in amplifier. To match the IR/visible illumination area, the PI lab further developed a wide-field MIP microscope in which a complementary metal– oxide–semiconductor (CMOS) camera and synchronization electronics are harnessed for whole-field lock-in detection (Sci Adv 2019). Despite these initial successes, the sensitivity of MIP microscopy is limited by the detection schemes. First, the golden standard lock-in detection misses all the harmonic frequencies in the MIP signal. Second, the well-depth of a typical CMOS camera seriously limits the probe power to 0.01 mW at sample. Thus, many averages are needed to reach a reasonable signal to noise ratio. We overcome these difficulties through two innovations. The first one is to digitize the probe photons received by a fast photodiode. Then, in the frequency domain, a match filter is used to extract all MIP signals at fundamental and harmonic frequencies. The second one is to perform patterned probe illumination and collect photons with a photodiode which has a saturation threshold of tens of mW. Then, a MIP image is recovered by matrix inversion. In this “single-pixel camera” approach, the probe power can be increased by 1000 times, which indicates that the speed can be improved 30 times to reach the same signal to noise ratio of wide field MIP at the shot noise limit. The goal of this R33 proposal is to develop a digital signal processing, single pixel camera MIP microscope and validate its potential for high-content cancer metabolic imaging. In particular, we aim to validate a metabolic switch from glucose-mediated lipogenesis to fatty acids uptake/oxidation in ovarian cancers that become resistant to cisplatin. By accomplishing the proposed studies, we will generate a high-speed hyperspectral mid-infrared photothermal chemical imaging platform that is able to map the live cell metabolism at sub-micron spatial resolution. Metabolic imaging of live drug-resistant cancer cells by this platform opens new opportunities of unveiling hidden signatures that can potentially lead to adaptive therapies that inhibit the development of drug resistance in cancers.

计划概要虽然细胞代谢改变正在成为癌症的一个标志，但对新工具的需求尚未得到满足。代谢物的定量分析广泛采用 NMR 光谱、质谱、FTIR 和拉曼光谱。用于组织提取物或完整组织中的分子检测然而，这些工具并不指示空间。我们通过开发无锁定、宽范围的方法来解决这一未满足的需求。我们的技术将实现现场中红外光热 (MIP) 显微镜的定量振动成像。 PI 实验室最近开发的 MIP 显微镜中的活肿瘤细胞和完整活检中的代谢物（Sci Adv）。 2016），可见光束探测引起的热效应（例如折射率的变化和热膨胀）然后通过锁定放大器提取 MIP 信号以匹配红外/可见光。照明区域，PI实验室进一步开发了一种宽视场MIP显微镜，其中互补金属– 利用氧化物半导体 (CMOS) 相机和同步电子设备进行全场锁定尽管取得了这些初步成功，MIP 显微镜的灵敏度仍受到限制。首先，黄金标准锁定检测会错过 MIP 中的所有谐波频率。其次，典型 CMOS 相机的井深严重限制了样品处的探头功率为 0.01 mW。因此，需要多次平均值才能达到合理的信噪比，我们克服了这些困难。通过两项创新，第一个是将快速光电二极管接收到的探测光子数字化。在频域中，匹配滤波器用于提取基频和谐波频率的所有 MIP 信号。第二种是执行图案化探针照明并使用光电二极管收集光子，该光电二极管具有几十mW的饱和度阈值然后，通过矩阵求逆恢复MIP图像。相机”的方法，探针功率可以提高1000倍，这表明速度可以提高了30倍，在散粒噪声极限下达到了与宽视场MIP相同的信噪比的目标。这个R33提案是开发数字信号处理、单像素相机MIP显微镜并验证其特别是，我们的目标是验证高内涵癌症代谢成像的代谢转变。葡萄糖介导的脂肪生成到对顺铂耐药的卵巢癌中脂肪酸的摄取/氧化。通过完成拟议的研究，我们将产生高速高光谱中红外光热化学成像平台能够以亚微米空间分辨率绘制活细胞代谢图。通过该平台对活体耐药癌细胞进行成像为揭示隐藏特征提供了新的机会这可能会导致抑制癌症耐药性发展的适应性疗法。