High Resolution Imaging of Intracellular Oxygen Concentration by Phosphorescence Lifetime

Overview

Journal Sci Rep

Specialty Science

Date 2015 Jun 13

PMID 26065366

Citations 44

Authors

Hiromi Kurokawa

Hidehiro Ito

Mai Inoue

Kenji Tabata

Yoshifumi Sato

Kazuya Yamagata

Shinae Kizaka-Kondoh

Tetsuya Kadonosono

Shigenobu Yano

Masahiro Inoue

Toshiaki Kamachi

Affiliations

Soon will be listed here.

Abstract

Optical methods using phosphorescence quenching by oxygen are suitable for sequential monitoring and non-invasive measurements for oxygen concentration (OC) imaging within cells. Phosphorescence intensity measurement is widely used with phosphorescent dyes. These dyes are ubiquitously but heterogeneously distributed inside the whole cell. The distribution of phosphorescent dye is a major disadvantage in phosphorescence intensity measurement. We established OC imaging system for a single cell using phosphorescence lifetime and a laser scanning confocal microscope. This system had improved spatial resolution and reduced the measurement time with the high repetition rate of the laser. By the combination of ubiquitously distributed phosphorescent dye with this lifetime imaging microscope, we can visualize the OC inside the whole cell and spheroid. This system uses reversible phosphorescence quenching by oxygen, so it can measure successive OC changes from normoxia to anoxia. Lower regions of OC inside the cell colocalized with mitochondria. The time-dependent OC change in an insulin-producing cell line MIN6 by the glucose stimulation was successfully visualized. Assessing the detailed distribution and dynamics of OC inside cells achieved by the presented system will be useful to understanding a physiological and pathological oxygen metabolism.

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