Bioelectronics
Let's dive into another fascinating aspect of essential oils: their vibrational properties. To explore this, we’ll use a tool known as bioelectronics, developed by Louis-Claude Vincent, often referred to by experts as "BEV."
Louis-Claude Vincent is a French engineer who has dedicated a significant part of his life to researching water quality, including both clean and wastewater. His goal has been to create a method for objectively assessing the quality of various aquatic environments. His research is grounded in key biophysical factors such as pH (hydrogen potential), rH2 (oxidation-reduction potential), and rô (resistivity potential).
Definition: A chemical reaction that takes place between an oxidizing substance and a reducing substance.
Definition: Resistivity is a property that describes the extent to which a material opposes the flow of electric current through it.
In the 1950s, Louis-Claude Vincent pioneered the field of bioelectronics to accurately assess water quality.
The horizontal axis represents the first biophysical aspect of water, which is its pH level. A pH range of 0 to 7 indicates an acidic environment, while a range of 7 to 14 signifies an alkaline environment. The vertical axis shows the rH2, which gauges the concentration of electrons available for redox reactions. In this context, a range of 0 to 28 indicates an electron-rich environment that is reduced, whereas a range of 28 to 42 points to an electron-poor environment that is oxidized.
Another important factor in bioelectronics is resistivity, measured in Ohms. This refers to the inherent electrical property of a material that resists electrical conductivity.
This gives us the following 4 zones:
Zone 1 In the bottom left corner, we encounter an acidic and reduced environment, which represents the water setting that promotes health and vitality for Vincent. This aquatic habitat is conducive to the growth of green algae and is rich in protons and electrons.
Zone 2 Moving to the top left, the environment remains acidic and proton-rich, but it has lost electrons, resulting in an oxidized state. This condition is ideal for the growth of mold and fungi.
Zone 3 In the top right corner, we find an oxidized yet alkaline environment. This water setting is not conducive to vitality, as it lacks protons and electrons, making it suitable for the proliferation of viruses.
Zone 4 Finally, in the bottom right, the environment is alkaline and reduced, characterized by a deficiency in protons but an abundance of electrons. This type of water environment supports the growth of certain bacteria.
Claude Vincent utilized the analysis of biophysical values in human body fluids to accurately assess an individual's health status. He highlighted the strong connection between three physicochemical values found in these fluids and a person's health or illness. The three bodily fluids he focused on were blood, saliva, and urine. Notably, the measurements, especially the electrical values of urine, enable a swift evaluation of a person's health condition. Louis-Claude Vincent conducted thorough research aimed at identifying precancerous conditions in individuals, with the goal of intervening early to prevent the development of disease. Below is a summary of his findings related to human measurements, specifically concerning blood.
In an acidic and reduced environment, specific types of meningitis can thrive. Conversely, an alkaline and reduced environment creates a conducive setting for harmful microbes like those causing typhoid, cholera, and plague. In an acidic and oxidized environment, we encounter poliomyelitis and the bacteria responsible for tuberculosis. Meanwhile, an oxidized and alkaline environment serves as a fertile ground for various degenerative diseases, including cancers, leukemia, heart attacks, multiple sclerosis, and alkaline diabetes.
This is the area that we find most significant, and essential oils provide outstanding supportive therapy for it. Now, let's explore how BEV relates to aromatherapy. The first aromatherapist to incorporate Louis-Claude Vincent's scientific research into natural medicine was the esteemed Dr. Jean Valnet. He was deeply invested in this field, which helped shape his approach to practical medicine. Today, we can still use Louis-Claude Vincent's bioelectronics to assess the electromagnetic properties of essential oils.
When we look at essential oils collectively, their bioelectronic properties suggest they thrive in a vibrant, acidic, and reduced environment. These oils exhibit remarkably high electrical resistivity, which is particularly intriguing as it helps us understand how friction impacts the resistivity of a person's surroundings. For instance, true lavender essential oil has a resistivity of 2,800 ohms, while clove essential oil measures at 4,000 ohms.
This information becomes even more fascinating when we compare the high resistivity of essential oils to that of the human body. For example, the resistivity of healthy human blood is around 210 ohms. When you apply pure essential oils to your skin through massage, you effectively enhance the overall resistivity of your blood, as these oils circulate throughout the body.
The Electric Properties of Essential Oils
Pierre Franchomme was instrumental in categorizing the various biochemical families found in essential oils based on the electromagnetic principles of bioelectronics. He conducted his measurements using isolated molecules.
However, the reality of essential oils is far more intricate. They consist of a vast array of different molecules, each with distinct electrical charges and biophysical properties. This complexity accounts for the seemingly "contradictory" characteristics of certain essential oils, which can have both calming and energizing effects. As Pierre Franchomme noted, "In summary, the following rule applies: the less a molecule is oxidized (hydrocarbons, terpenes, alcohols, phenols, oxides, ether oxides, etc.), the more positive it is. Conversely, the more a molecule is oxidized—by gaining oxygen or losing hydrogen—the more its negativity increases; this applies to ketones, aldehydes, and esters, as well as polyunsaturated terpenes (e.g., sesquiterpenes)." This understanding allowed him to classify aromatic molecules into two primary electrical categories using BEV. He then assessed the polarity of these aromatic molecules along the axis related to Vincent's pH: polar molecules, which have some affinity for water (like alcohols and aldehydes), are positioned on the left, while apolar molecules, which are less soluble or hydrophobic and do not mix with water, are found on the right.
Thus, the electrical reference framework for essential oils is grounded in the electrical and hydric behavior of aromatic molecules. Since this theoretical and scientific breakthrough, it has become common practice in France to depict the aromatic molecules present in essential oils according to their electrical dynamics.
This diagram illustrates the key biochemical families present in essential oils. It serves as a valuable tool for understanding the unique benefits of various essential oils in a straightforward manner.
This illustration streamlines the electrical values from the work of BEV and Franchomme. The molecules found at the top of the diagram possess anti-inflammatory properties, providing a soothing effect. When these molecules are applied to the skin, they transfer electrons to the tissues. Conversely, the molecules at the bottom of the diagram act as strong tonics, imparting a positive charge to the tissues. This diagram is featured in each video focused on a specific essential oil, clearly showcasing its primary functions. The aim of this visual representation is to help you quickly identify the key active ingredients. It also highlights the presence of certain molecules that may require special care due to their toxic components.
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