Singlet Oxygen Detection and Imaging

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Singlet Oxygen, the lowest electronically excited state of molecular oxygen, is highly reactive and involved in many chemical and biological processes. It is one major mediator during photosensitization, which has been used by mankind since ancient times, even though the mechanisms behind it were understood only about half a century ago. The combination of high reactivity and very long natural lifetime allows for direct optical detection of singlet oxygen and its interactions using its characteristic phosphorescence at around 1270 nm. Since this emission is very weak, optical detection was technically very challenging for a long time. Therefore, even today, most laboratories only exploit the high reactivity to observe the interaction with sensor molecules, rather than singlet oxygen emission itself. However, in recent years highly sensitive optical detection was developed, the authors being major contributors. This book is dedicated to the detection of singlet oxygen, discussing possibilities, pitfalls and limits of the various methods with a special focus on time-resolved phosphorescence and the kinetics of singlet oxygen generation and decay including involved and related processes, discussing investigated systems with various complexity from solutions over in vitro to in vivo. The long-standing paradigm that singlet oxygen phosphorescence is a benchmark for detection systems rather than an option for process observation is still ubiquitous and this book hopes to contribute in overcoming this still prevailing bias.

List of contents

Introduction.- Detection Introduction.- Indirect Detection of Singlet Molecular Oxygen.- Direct Detection of Singlet Molecular Oxygen.- Time-Resolved Singlet Oxygen Luminescence in Cell Suspensions.- Time-Resolved Singlet Oxygen Luminescence Detection in Microorganisms on Surfaces.- Time-Resolved Singlet Oxygen Luminescence Ex Vivo and In Vivo.- Authors' Biographies .

About the author

Steffen Hackbarth received his Ph.D. degree in experimental physics from HU Berlin in 2000. Ever since, he has been working in the field of time-resolved spectroscopy in the time range ps to ms with a special focus at the triplet processes of photo sensitizers. He is head of the singlet oxygen lab and as such, recently became a faculty member of the mathematical and natural sciences faculty. Since 2011 he is leader of the advanced practical courses for the physics students at HU Berlin. His research focuses on molecular photobiophysics, especially on fundamental research in the field of photosensitization, passive drug delivery, and diffusion processes during Photodynamic Therapy. Technical developments focus on singlet oxygen luminescence detection in vivo and other heterogeneous environments at highest sensitivity toward real-time supervision of individualized medical tumor treatments. In 2012, he was awarded (together with his colleague, Jan Schlothauer) the innovation award of the SPIE Europe for the development of a compact time-resolved table-top singlet oxygen luminescence detection system, which since then was improved to in vivo capability.