Biophotons or Oxidation?

In our Mineral Balancing Program, we often talk about the concept of oxidation rate. But did you know that this process is similar to the phenomenon of biophotonic emissions?

Biophotons are ultra weak electromagnetic waves that are emitted by living cells (source, source). They are thought to play a role in cellular communication and regulation, but their exact function is not well understood. Some researchers believe that biophotons may be involved in the regulation of cell growth and differentiation, while others propose that they may be used by cells to communicate with one another. Despite being weak in nature, biophotons have been detected in all living organisms, including plants, animals, and microorganisms. Biophotons encompass all frequencies found within the electromagnetic spectrum, including all colours visible to the human eye.

Currently, there are two theories behind the emission of biophotons. The first, known as the biochemical theory, suggests that biophotons are a byproduct of metabolic and oxidation processes within cells. According to Avijgan and Avijgan, the production of reactive oxygen species (ROS) such as H2O2 during these processes excites the cell's constituents, resulting in the release of ultraweak light. The second theory, known as the coherence theory, proposes that the emission of biophotons is a result of nonlinear, coherent interactions between weak radiation and collective biomolecules. This theory suggests that biophotons serve as an optical channel of information (source, source, source).

Biophotons are a fascinating topic in the world of biology and have been found to play a critical role in the functioning of living organisms. In our Mineral Balancing Program, we can't help but see parallels between the metabolic rate and biophotonic emissions.

According to the biochemical theory, as cells create energy, light is emitted. But, it's important to note that there may be more to this theory than meets the eye. Instead of just one theory being correct, it's more likely that both theories are interrelated. This means that there is a physical biophotonic field around the human body, which may be correlated with the metabolic rate, as well as non-physical photonic and sononic fields that are responsible for many unknown aspects of biology.

By measuring the metabolic rate through a hair tissue mineral analysis, we can assume that a Slow Oxidiser would have a less vibrant biophotonic field than a Fast Oxidiser. However, this does not necessarily mean that the Fast Oxidiser is healthier. This could also be due to the production of reactive oxygen species (ROS).

As we continue to explore the intricacies of our Mineral Balancing Program and learn more about the correlations between biophotons and the metabolic rate, we hope to gain a better understanding of the impact of biophotonic emissions on human health.