Abstract
The specific diameter of microtubules was shown to be a primary solution when magnetic energy was set equal to Casimir energy. To discern if this spatial containment could be foci for information photon emissions were measured from preparations of microtubules (MTs) while they were exposed in sequential 4 min intervals to various patterns of weak magnetic fields whose intensities ranged from 3 to 10 μT. Calculations from the median mass of a tubulin dimer, its summed charges and the applied magnetic field as well as the change in magnetic moment derived from the energy of the hydrogen line when applied to our experimental fields predicted a dynamic shift (Δf) between 0.03 and 0.21 Hz. Spectral power densities (SPD) indicated marked enhancements in photon numbers during periods of magnetic field exposures within the 7.6 to 7.8 Hz increment. The total SPD units for the shift were 10-18 to 10-17 J per s. Five of the eight patterns elicited a split spectrum of power within this range. Separate factor analyses of the SPDs of the serial values that composed the points of the actual field patterns indicated those that evoked the split-spectrum (Δf = 0.05 to 0.13 Hz) displayed significantly higher loadings on the same factor compared to those that did not. If this shift in photon energy reflects a phase modulation of the coherence frequency (8 MHz) of MTs, the increment of energy per MHz frequency would be within the energy of the neutral hydrogen line. These results suggest that the intrinsic structure or information from specific intensity magnetic fields when applied to MTs is reflected in photon energy densities vacillating around the fundamental Schumann Resonance that could be an interface between Casimir and magnetic sources.
Highlights
One of the fundamental challenges of biophysics has been to resolve or at least accommodate the probable artificial differentiation between phenomena that have been considered “non-physical” such as consciousness and phenomena with discrete properties such as action potentials or cellular electrodynamics
In addition we present results that strongly suggest that information relevant to cell function could be mediated through or strongly correlated with the configuration of the split in Schumann-like fundamentals in the spectral power density of the photon emissions from MTs during brief field exposures
A diagram of the experimental arrangement is shown in Figure 1 that was identical to those reported for other experiments in which photon emissions in response to weak patterned magnetic fields had been measured [6] [21]
Summary
One of the fundamental challenges of biophysics has been to resolve or at least accommodate the probable artificial (or in the very least arbitrary) differentiation between phenomena that have been considered “non-physical” such as consciousness and phenomena with discrete properties such as action potentials or cellular electrodynamics. The potency of the Hameroff and Penrose Orch OR (objective reduction) model [1] is contained within predictions that can be quantified. They have been supported across levels of discourse by Bandyopadhyay and colleagues [2]. If microtubules are central to this process they or their constituents should exhibit characteristics that reflect fundamental forces. We present quantitative solutions and experimental evidence for this proposition
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