Author: ["Marina K. Kuimova","Stanley W. Botchway","Anthony W. Parker","Milan Balaz","Hazel A. Collins","Harry L. Anderson","Klaus Suhling","Peter R. Ogilby"]
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Abstract
Diffusion-mediated cellular processes, such as metabolism, signalling and transport, depend on the hydrodynamic properties of the intracellular matrix. Photodynamic therapy, used in the treatment of cancer, relies on the generation of short-lived cytotoxic agents within a cell on irradiation of a drug. The efficacy of this treatment depends on the viscosity of the medium through which the cytotoxic agent must diffuse. Here, spectrally resolved fluorescence measurements of a porphyrin-dimer-based molecular rotor are used to quantify intracellular viscosity changes in single cells. We show that there is a dramatic increase in the viscosity of the immediate environment of the rotor on photoinduced cell death. The effect of this viscosity increase is observed directly in the diffusion-dependent kinetics of the photosensitized formation and decay of a key cytotoxic agent, singlet molecular oxygen. Using these tools, we provide insight into the dynamics of diffusion in cells, which is pertinent to drug delivery, cell signalling and intracellular mass transport. The spectrally resolved fluorescence of a zinc–porphyrin dimer is used to quantify intracellular viscosity. The porphyrin dimer also acts as a singlet-oxygen sensitizer, and enables real-time observation of a surprisingly large increase in intracellular viscosity that occurs on singlet-oxygen-mediated photoinduced cell death.
Cite this article
Kuimova, M., Botchway, S., Parker, A. et al. Imaging intracellular viscosity of a single cell during photoinduced cell death. Nature Chem 1, 69–73 (2009). https://doi.org/10.1038/nchem.120