Introduction.- Part 1. History of UPE research.- Mitogenetic rays.- Oxidation, free-radicals and ultraweak luminescence.- Biophotons and the International Institute of Biophysics (IIB).- Part 2. Physics of light and light research.- Physics of photon emission.- Chemiluminescence as a tool for free radical research.- Highly sensitive imaging and spectral analysis of UPE from biological systems and their application.- Part 3. Molecular mechnisms of UPE.- Free radicals in biology.- Ultraweak luminescence from aqueous systems.- Chemiluminescence in oxidation of hydrocarbons: mechanistic fundamentals.- Chemiluminescence in oxidation of fatty acids and lipids.- Chemiluminescence in protein oxidation.- Emitters of endogenous biological chemiluminescence: quantum chemical modeling insights.- Enzymatic sources of free radicals.- Part 4. UPE research in life science.- Luminescence of animal tissues and vegetable oils.- Ultraweak photon emission from human body in relation to anatomy and histology.- Chronobiological aspects of spontaneous ultra-weak photon emission in humans: Ultradian, circadian and infradian rhythms.- Autoluminescence in seedlings: applications.- Application potentiality of Delayed Luminescence in Medicine, Biology and Food Quality researches.- Part 5. Mitogenetic effect and related phenomena: unresolved problems of UPE.- Mitogenetic effect: preface.- Mitogenetic effect in biological systems.- Physical properties of mitogenetic radiation.- Secondary, degradation and necrobiotic radiation.- Mitogenetic research in medicine: radiation of blood and cancer diagnostics.- Part 6. Non-chemical distant interaction hypothesis - pro et contra.- Non-chemical distant interaction: preface.- The possible functions of electromagnetic cell communication.- Understanding of Fritz-Albert Popp’s biophoton theory from the viewpoint of a biologist.- Limits to the information transfer through UPE.- Quantum nonlocality and biological coherence.- Part 7. Perspectives.- Integrating ultraweak photon emission in mitochondrial research.- Selected biophysical methods for enhancing biological autoluminescence.- Upconverting nanoparticles as sources of singlet oxygen.- Upconverting nanoparticles as sources of singlet oxygen.- Delayed Luminescence as a tool to study the structures of systems of biological interest and their collective long-living excited states.- Index.

Ilya Volodyaev is a senior researcher at the Embryology Department, Faculty of Biology, Moscow State University, Russia. He earned his Master’s degree in biophysics (2004) and PhD in embryology (2007) at Moscow State University and continued research in embryo development biophysics, combining it with clinical work. The current book relates to his interests in the field of biophysical research: biological autoluminescence, free radical processes and the hypothesis of non-chemical biological interactions.

Eduard van Wijk is senior scientist and co-founder of MeLuNa Research, Wageningen, The Netherlands. He did his PhD at the Institute for Cognition and Information, Radboud University Nijmegen. Following completion of this degree he was affiliated as senior researcher at the International Institute of Biophysics and later at the Leiden University. His research is on the application of biophotonics in predicting organism quality both in human and agricultural issues.

Michal Cifra is a senior scientist and Bioelectrodynamics research team leader at the Institute of Photonics and Electronics of the Czech Academy of Sciences. With his team, he explores the interactions between electromagnetic field and biosystems, which includes also generation of electromagnetic field by biosystems.

This book addresses the phenomenon of biological autoluminescence (also known as ultraweak photon emission, UPE, biochemiluminescence, or biophotons) and deals with a very broad spectrum of subjects, ranging from basic observational studies to molecular mechanisms, free-radical processes, physics of electron excitation and photon emission, as well as detection techniques. The chapter topics include UPE in plants, animals, and the human body; microorganisms and subcellular structures; and model systems, illustrating its high prevalence. Several sections of the book provide some backstory, with emphasis on methodology, unresolved questions, and existing controversies. The authors raise and discuss complex, potentially divisive aspects: Are there any reasons to assume the existence of non-chemical interaction in biological systems? Can research results in the field of mitogenetic radiation, delayed luminescence, and oxychemiluminescence of model systems, be correctly interpreted? What does the future hold for this area of research? Altogether, this publication gives the reader a thorough overview of biological autoluminescence (UPE, biophotonics) research, making it ideal for students and researchers who are new to the area as well as those who are specializing in it.