Results and effects

In general, all diseases related to an energetic weakness and/or limitations of the function of a body organ can be treated.

Therefore all medical fields can take advantage of this treatment method. In addition to chronic pain syndromes, this method is also suited for treating economically relevant diseases, like diabetes with or without complications, disorders of the lipometabolism, chronic liver diseases, auto-immune disease and allergies. Postulating, that an energy transfer in any form takes place between the blood cells and the organ cells, with the latter being subjected to regeneration, there are no limits for this therapy.

At the same time, the gap between complementary and school medicine is closed through laboratory-chemically provable effects.

Indications:

Diabetes mellitus
Chronic liver diseases
Lpiometabolism disorders
Chronic pain syndromes
Rheumatoid arthritis
Polyneuropathies
Chronic inflammatory intestinal diseases
Fibromyalgia
Hypertension
Tinnitus
Maculopathies
MS
Burn-out syndrome
Allergies and eczema

General effects

Significant improvement of the general performance
Improved sleep and vigilance
Positive impact on the general mood
Reduced medication

Special effects

Optimisation of the diabetic metabolism
Statine-comparable impact on hypercholesteremia
Substantial decrease of pathologically increased liver values
Reduction of shift frequency of chronic inflammators intestinal diseases
Improved general condition and mobility of MS patients
Positive impact on pain syndromes resistant to therapy
Tendency of positive impacts on tinnitus
Reduction of anti-hypertensive medication for aggravated hypertension
Tendency of positive impacts on maculopathia

ATP increase under laser irradiation (632nm) of a HeLa cell-culture

Mitochondria of human lymphocytes before
(top) and after
(bottom) irradiation with a He-Ne laser of 632nm.

Further biological effects:

Stimulation of the immune response, unspecifically and specifically,
Decrease of the CRP (C-reactive protein),
Increase of the immunoglobulin IgG, IgA and IgM,
Reduction of circulation damaging immune complexes,
Increase of the phagocytic activity of the macrophages,
Stimulation of blood formation,
Improvement of the erythrocytes’ plasticity,
Improvement of the antioxydative enzyme system, stabilisation of the lipid oxydase in the cell membranes,
Stimulation of DNA repair mechanisms,
General antitoxic effect,
Analgesia, improved micro-circulation,
Antiallergic, arrhythmic, antibacterial, spasmolytic and anti-inflammatory effect,
Improved effect of antibiotics,
Reduction of side-effects during chemotherapy and radiation (as secondary therapy),
Improved lymphocyte aggregation,
Improvement of the blood rheology with anti-thrombocytic effects,
Reduction of thrombocyte aggregation,
Improved blood viscosity,
Increased fibinolysis,
Opening of micro-capillars and promotion of collateral formation,
Improvement of tissue tropics,
Normalisation of nervous irritability through stabilisation of cell membranes,
Increased oxygen absorption and saturation of the blood,
Improvement of the artery-venous oxygen balance,
On the cellular level, improvement of the mitochondrial metabolism with development of “Giant” Mitochondria,
Increased activity of the respiratory chain,
Increased ATP production,
Stabilisation of the cell membranes,
Increased function of the hypothalamus and the limbic system.

How can these multiple positive effects be explained?

Currently, the reason for the manifold effects is supposed to be found in the respiratory chain of the mitochondria. The redux potential plays a decisive role for these effects. Cells with a low (acetous) pH value and hypoxia react better than normal cells. They absorb the light quants and thus stimulate the strongly reduced cell metabolism, finally leading to a stabilisation of the cell membrane by increasing the ATP synthesis.