Experimentally-Induced Inhibition of Growth in Melanoma Cell Cultures Separated by ~2 Kilometers When Both Share Excess Correlation Magnetic Fields: Macroscopic Evidence of Free-Space Quantum Teleportation?
In multiple experiments plates of melanoma
cells separated by either 3 m or 1.7 km were placed in the centers of toroids.
A specific protocol of changing, angular velocity, pulsed magnetic fields that
has been shown to produce excess correlation in photon durations and shift in
proton concentrations (pH) in spring water were generated around both plates
of cells. Serial injections of 50 μL of standard concentrations of hydrogen
peroxide into the “local” plates of cells during the 12 min of field activation
produced conspicuous cell death (reduction of viable cells by about 50%) with
comparable diminishments of cell numbers in the non-local plates of cells
within 24 hr but only if both loci separated by either 3 m or 1.7 km had shared
the “excess correlation” magnetic field sequence. The non-local effect did not
occur if the magnetic fields had not been present. Higher or lower
concentrations of peroxide or concentrations that eliminated all of the cells
or very few cells in the local dishes were associated with no significant
diminishment of non-local cell growth. The data indicate that there must be a critical
number of cells remaining viable following the local chemical reaction for the
excess correlation to be manifested in the non-local cells. We suggest that
this specific spatial-temporal pattern of fields generated within the paired
toroidal geometries promotes transposition of virtual chemical reactions as an
information field. Calculations of the energy available per cell and per volume
of the quantity of reactants injected into the local space from the intensity
of the changing velocity toroidal magnetic field support previous measurements
and derivations that the units of information transposition may involve
discrete quantities that represent equivalents of photons, electrons and
protons.
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