Abstract
A quantitative technique to detect cancer in single cells could transform cancer diagnosis. Current cancer diagnosis utilizes histopathology, which requires tissue acquisition, extensive processing and, in most cases, relies on the qualitative morphological analysis of tissues and cells. Molecular biomarkers are only available for a few specific tumor subtypes. We discovered that the fluorescence polarization (Fpol) of Methylene Blue (MB) is significantly higher in cancer than in normal human breast tissues and cells. We confirmed that fluorescence polarization imaging did not affect the viability of the cells and yielded highly significant differences between cancer and normal cells using MB concentrations as low as 0.05 and 0.01 mg/ml. To explain this phenomenon we examined intracellular localization of MB and its fluorescence lifetime. We determined that higher fluorescence polarization of MB occurs due to its increased accumulation in mitochondria of cancer cells, as well as shorter fluorescence lifetime in cancer relative to normal cells. As quantitative MB Fpol imaging can be performed in vivo and in real time, it holds the potential to provide an accurate quantitative marker of cancer at the cellular level.
Highlights
We developed an approach for detecting cancer at the cellular level by quantitative imaging of the fluorescence polarization (Fpol) of methylene blue (MB) in single cells
Our results indicate that MB Fpol imaging may be useful for the detection of several types of cancers
We have shown that increased MB Fpol can be explained by accumulation of positively charged MB in the negatively charged mitochondria in cancer cells
Summary
We developed an approach for detecting cancer at the cellular level by quantitative imaging of the fluorescence polarization (Fpol) of methylene blue (MB) in single cells. In the future, Fpol imaging could be used as in vivo, real-time quantitative method for detecting cancer at the cellular level. We have demonstrated that MB Fpol is higher in cancerous breast and skin tissues as compared to normal tissue[20,21,22,23,24,25,26]. Fluorescence polarization imaging of MB was used to distinguish cultured human breast cancer cells from normal human breast epithelial www.nature.com/scientificreports/. To validate our findings and explain this phenomenon, we examined the subcellular localization and fluorescence lifetime of MB in the live cells
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