The effects of low-level electromagnetic fields and ultraweak photon emission on biological systems.

Abstract

The functionality of biological organisms is a product of minute-invisible forces and structures, which together form a cohesive ensemble that initiate the processes of life. The electromagnetic and photonic nature of biological life and its basic unit the cell may be considered a viable option for communication, survival and senescence. The basis of this investigation considers the dynamic nature of low-level electromagnetic fields and ultraweak photon emission as a mechanism for intracellular and intercellular interactions, which work under the premise of only demanding small quanta of energy. Metastatic cancerous cells have been observed to emit specific frequencies of photon emission compared to healthy cells and increase this emission in unfavorable conditions. The application of a specific sequence of patterns (MuKarb) at a specific intensity, observed in the dissolution of planarian worms, when applied to cancerous cells produce complete death of the exposed metastatic cells but not healthy cells. When such patterns of light at specific wavelengths are pulsed into the aforementioned cells, the emitted light from the cells in the pulsed pattern is observed relative to the duration of the light exposure. These effects become critical to the specificity of the appropriate pattern and intensity of the field, which has been linked to the importance of appropriate equipment configuration. The smallest iv changes in the current/voltage flow within the circuitry of the digital to analogue converter and electromagnetic field devices can make drastic changes with respect to the elimination of cancerous cells being observed or not. This phenomenon reflects the Aharanov-Bohm phase shifts in voltage within the electromagnetic field equipment and its importance in producing effects as a result of low-level electromagnetic fields. The application of specificity within low-level electromagnetic generating equipment has also been shown through the process of non-locality (entanglement) where appropriate and tuned apparatus are required to produce specific non-local effects. Successful non-local effects were observed through observing decreases in growth of melanoma cells through nontangible means, comparable to the manipulate local melanoma cells. These results converge on the premise and importance of properly tuned equipment for successful low-level electromagnetic field and photon exposures. Furthermore the interaction between the use of low-level electromagnetic fields and photons at specific pattern has shown the importance of interfering with the propagation of metastatic cells.