MITOCHONDRIAL REDOX IMAGING FOR CANCER DIAGNOSTIC AND THERAPEUTIC STUDIES.

IF 2.3 3区 医学 Q2 OPTICS Journal of Innovative Optical Health Sciences Pub Date : 2009-10-01 DOI:10.1142/S1793545809000735
Lin Z Li, He N Xu, Mahsa Ranji, Shoko Nioka, Britton Chance
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Abstract

Mitochondrial redox states provide important information about energy-linked biological processes and signaling events in tissues for various disease phenotypes including cancer. The redox scanning method developed at the Chance laboratory about 30 years ago has allowed 3D high-resolution (~ 50 × 50 × 10 μm3) imaging of mitochondrial redox state in tissue on the basis of the fluorescence of NADH (reduced nicotinamide adenine dinucleotide) and Fp (oxidized flavoproteins including flavin adenine dinucleotide, i.e., FAD). In this review, we illustrate its basic principles, recent technical developments, and biomedical applications to cancer diagnostic and therapeutic studies in small animal models. Recently developed calibration procedures for the redox imaging using reference standards allow quantification of nominal NADH and Fp concentrations, and the concentration-based redox ratios, e.g., Fp/(Fp+NADH) and NADH/(Fp+NADH) in tissues. This calibration facilitates the comparison of redox imaging results acquired for different metabolic states at different times and/or with different instrumental settings. A redox imager using a CCD detector has been developed to acquire 3D images faster and with a higher in-plane resolution down to 10 μm. Ex vivo imaging and in vivo imaging of tissue mitochondrial redox status have been demonstrated with the CCD imager. Applications of tissue redox imaging in small animal cancer models include metabolic imaging of glioma and myc-induced mouse mammary tumors, predicting the metastatic potentials of human melanoma and breast cancer mouse xenografts, differentiating precancerous and normal tissues, and monitoring the tumor treatment response to photodynamic therapy. Possible future directions for the development of redox imaging are also discussed.

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线粒体氧化还原成像用于癌症诊断和治疗研究。
线粒体氧化还原状态为包括癌症在内的各种疾病表型提供了与能量相关的生物过程和组织中信号事件的重要信息。钱斯实验室在大约 30 年前开发的氧化还原扫描方法可根据 NADH(还原型烟酰胺腺嘌呤二核苷酸)和 Fp(氧化型黄素蛋白,包括黄素腺嘌呤二核苷酸,即 FAD)的荧光对组织中的线粒体氧化还原状态进行三维高分辨率(约 50 × 50 × 10 μm3)成像。在这篇综述中,我们将阐述其基本原理、最新技术发展以及在小动物模型癌症诊断和治疗研究中的生物医学应用。最近开发的利用参考标准进行氧化还原成像的校准程序可以量化组织中 NADH 和 Fp 的标称浓度以及基于浓度的氧化还原比率,例如 Fp/(Fp+NADH)和 NADH/(Fp+NADH)。这种校准便于比较不同时间和/或不同仪器设置下不同代谢状态下的氧化还原成像结果。目前已开发出一种使用 CCD 检测器的氧化还原成像仪,可更快地获取三维图像,平面分辨率更高,可达 10 μm。使用 CCD 成像仪对组织线粒体氧化还原状态进行了体内外成像和体内成像。组织氧化还原成像在小动物癌症模型中的应用包括胶质瘤和霉菌诱导的小鼠乳腺肿瘤的代谢成像、预测人类黑色素瘤和乳腺癌小鼠异种移植物的转移潜力、区分癌前病变和正常组织,以及监测肿瘤对光动力疗法的治疗反应。此外,还讨论了氧化还原成像未来可能的发展方向。
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来源期刊
Journal of Innovative Optical Health Sciences
Journal of Innovative Optical Health Sciences OPTICS-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
CiteScore
4.50
自引率
20.00%
发文量
69
审稿时长
>12 weeks
期刊介绍: JIOHS serves as an international forum for the publication of the latest developments in all areas of photonics in biology and medicine. JIOHS will consider for publication original papers in all disciplines of photonics in biology and medicine, including but not limited to: -Photonic therapeutics and diagnostics- Optical clinical technologies and systems- Tissue optics- Laser-tissue interaction and tissue engineering- Biomedical spectroscopy- Advanced microscopy and imaging- Nanobiophotonics and optical molecular imaging- Multimodal and hybrid biomedical imaging- Micro/nanofabrication- Medical microsystems- Optical coherence tomography- Photodynamic therapy. JIOHS provides a vehicle to help professionals, graduates, engineers, academics and researchers working in the field of intelligent photonics in biology and medicine to disseminate information on the state-of-the-art technique.
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