Color is a brain trainer

 

Color helps intercellular communication reach a compromise for the organism as a whole. Miracle studies allow art therapists to understand the psychological impact of color on the brain.

Helps to calm down – green;

Stabilizes mood – light green;

Balancing emotions – turquoise;

Will give confidence and reliability – dark green;

Improve mood, relieve apathy, cheer – orange;

It will help to support oneself, to get out of the emotional impasse – yellow;

Creativity will stimulate – lemon;

Activates the desire to move forward – red;

Increase efficiency, strengthen freedom – red-orange;

Adds a sense of bodily warmth, comfort and joy – yellow-orange;

Inspires and activates life processes – raspberry (amaranth);

Pleases, reduces stress, restores after exhaustion – red-violet (fuchsia);

Will give self-confidence, activates desire – purple;

It will give you the opportunity to plunge into yourself and think about the meaning of life – purple (amethyst);

Harmonizes, puts in order “I” – blue;

Dark blue (indigo) – the color of dreams will help to fantasize and collect your dreams into an image;

Inspire, give an opportunity to reflect on ideas, projects, tasks – blue;

Facilitates the perception of reality, provides ease of being – pink;

Organizes and structures life processes – black;

Get rid of negative opinions – white;

Gray will help you reset your internal states;

Get rid of resentment and disappointment – brown.

Here is a little scientific explanation of how color works:

Color can have two different—and often opposite—effects. In connection with color coding of emotions, treatment with color can either evoke the expected psychological response typical of that color, or contribute to the expression of an emotion or problem corresponding to a color code. For example, take the color blue. Generally, blue will provide a calming effect. The optic nerves run from the retina, passing through the pituitary gland through the temporal lobe, to the back of the brain. This part of the visual system is focused on informing the conscious part of the brain about our environment – without interpretation.

Recently it has been discovered that an additional network of nerves runs directly from the retina to the hypothalamus. This explains the effect of light on the autonomic nervous system. Blue stimulates the anterior hypothalamus, which contains the main regulatory part of the parasympathetic nervous system. This means that all colors in the blue spectrum – from cyan/green through blue to violet – have a calming effect, activate digestion and promote sleep. Red stimulates the posterior lobe of the hypothalamus, and thus the sympathetic nervous system. Red provokes anger. All colors of the red spectrum – from magenta through red / orange to yellow – are stimulating, sometimes even provocative. Green maintains links between the two systems.

A branch of this neural pathway goes directly to the amygdala, bypassing the hypothalamus. The two bodies of the amygdala are very light sensitive areas of the limbic system and respond quickly to color affecting the eyes. The study demonstrated that each monochrome color frequency excites some neurons that are not stimulated by similar colors, but respond to the complementary (opposite) color. Therefore, each frequency of the color spectrum has a specific neurological and psychological effect.

Neurosurgeon Norman Shealy, MD, PhD, researcher and inventor of transcutaneous electrical nerve stimulation (TENS (Transcutaneous Electric Nerve Stimulation)) and the “spinal column stimulator”, conducted a study examining the biochemical changes in the brain after exposure to LUMATRON).

The German scientist Fritz Albert Popp confirmed the preliminary research of the Russian scientist and published his work, confirming the fact that the cells of the body constantly use light radiation to communicate with each other. Cells gossip, inform, celebrate and gloom. Only cancer cells behave differently: they don’t emit light.

Recent research in the field of stem cell therapy has revealed another surprising phenomenon: when cells are sick or stressed, they also emit “microscopic” sound signals. If the sounds made by a group of dying cells are artificially increased, it sounds like a group of women crying and grieving. The injected stem cells (from the umbilical cord of the embryos) travel to this signal and remain in this area to provide support. Stem cells are involved. Cells take care of each other. When things go wrong, as in the case of autoimmune diseases, they fight each other. Light (and sound) can have a profound effect on the regulation and correction of intercellular communication (Dietrich Klinghardt, MD, PhD).

Victoria Nazarevich 2019 ©