Photon (Energy) Emission from Biological Systems: A Dynamic Approach to Biochemical Processes in Humans and Cell Cultures

Spontaneous biophoton emissions were measured from cells and human subjects in complete darkness under multiple experimental conditions. Metabolic activators like EGF conspicuously produced high peaks in emission followed by an obvious drop in energy output. This pattern in emission suggests that the photon source was quantitatively limited and discrete. These characteristics would be reflective of membrane potentials and implicate the plasma membrane as the primary source. An applied weak physiologically patterned time-varying magnetic field was also sufficient enough to produce a coherent state between two aggregate of complex cells (human or mouse). During the presentation of a shared field, increases in photon emission occurred in cell cultures and beside the heads of human volunteers if the second aggregate in another room received light flashes. Both cellular and human photon emissions during the light flashes did not occur when the shared magnetic fields were not present. The summed energy emissions from the dark location during light stimulation to others was about 10-11 W/m2 and calculated to be in the order of 10-20 J per cell which is coupled to membrane function. These results indicate that under specific conditions changes in photon emissions may reflect intercellular and interbrain communications with potential quantum-like properties.