What is CellularBioenergetics?
Cellular bioenergetics is a hot topic in the domain of biochemistry. As a field of study, bioenergetics concerns itself with the transmission and distribution of energy through living cells. This inquiry is about gaining insight into the manner in which living cells obtain energy and sustain vital activity on a cellular level through myriads of discrete metabolic and enzymatic processes.
CellularBioEnergetics solutions introduces new perspectives into processes of life and wellness. Join us in our observation of the miraculous innate processes that sustain life and optimum energy generation in the body electric. Learn and understand life on a cellular level and develop an appreciation of the human body as living organism.
The Blueprint of Life a Measurable Field
The fields of life or L-fields, as discovered by Harold Saxton Burr (Yale University), are shown to be present in organisms. It turns out the body electric churns out force fields that are the basic blueprints for terrestrial life. Burr set out to demonstrate the prevalence of these fields and was able to measure differences in electrical potential by attaching electrodes to trees. It has been demonstrated that changes in L-field potentials correlate with vital physiological phenomena.
The theoretical descriptions of basic physiological properties of living cells found in contemporary textbooks of life sciences are based on a steady-state cell model with the following main feature: An outer membrane endowed with energy-consuming pumps encloses a space in which the main cellular cation K+ and other components are freely dissolved in free cellular water. Pumps, responsible for active trans-membrane transport of ions and macromolecules are fueled by energy that is stored in ATP and is liberated during hydrolysis of ATP (Membrane Pump Theory MPT).
Theoretical explanations of cell physiological phenomena derived from an equilibrium- bulk phase cell model are presented in the Association Induction Hypothesis AIH of Ling. The AIH describes all cellular structures as highly organized protein-ion-water systems in which water, proteins, and ions are at equilibrium in an associated low-entropy state. E.g., the concentration of cell K+ is high because this alkali ion is selectively adsorbed at beta- and gamma- carboxyl groups of cell proteins (Fixed Charge Hypothesis FCH), the alkali ion Na+ is found at a puzzling low concentration in living cells because it is partially excluded (low partition coefficient) from the cell water that assumes a dynamic multilayer structure (Polarized-Oriented-Multilayer-Theory POMT). The proteins responsible forselective ion adsorption and responsible for structuring of cell water with exclusion properties are under the control of ATP adsorbed at key protein sites. ATP exercises its controlling influence through its strong inductive effects. The four main subjects of Cell Physiology solute distribution, permeability, swelling and shrinkage, and resting potentialare described in the AIH by equations with physical-chemical parameters defined in FCH and POMT, energy-consuming pumps are not considered. These phenomena are thus identified as static manifestations of the resting living cell.
Life alternates between activity and inactivity. Gilbert Ling was able to demonstrate that the structure of the cell interior is not merely an arbitrary arrangement. In fact, the cell is composed of structured water that can be restored to an undisturbed and restful state through treatment. MRI scans reveal that illness is the result of unstructured water within cells. Once restored to a resting state, the cell returns to a state of readiness where vital life-sustaining processes occur.