Six Types of Microbiota and How They Help Us Energetically

In my distant healing practice, I use remote viewing to see the body’s energies and then employ Diamond and Gemstone Therapy methods to correct imbalances that I find.

Based on my observations, I’ve come to recognize how important the microbiome is in maintaining the body’s physical and energetic health.

The microbiome consists of a community of microscopic species that range from extremely small viruses to single-celled and multicellular organisms. Each has a distinct job, and they partner together as needed for a common purpose: to help maintain and sustain the cells, as well as their own communities.

In return, cells give them a home and a reason for being. Serving the cells allows life energy to flow through the microbiota, and thus they are sustained too.

To date, I’ve identified the energetic identity of six primary types of microbiota populations in my work as a Diamond & Gemstone Therapy practitioner.

Viruses

By far the largest group of microbiota I come across in my sessions is symbiotic viruses. This might surprise you, as we tend to think of viruses as categorically harmful, not supportive. But the purpose of symbiotic viruses is to generously provide extra life-giving color rays to every cell in the body.

Viral spectrums contain only three color rays, as opposed to the usual seven present in humans’ and animals’ spectrums.

Because they only have three color rays, viruses specialize in supporting cells whose functions rely on those particular colors in abundance.

Within this category are also infinitesimally small three-color-ray frequency packages that are virus-like. The difference is that viruses as we know them also contain programming to do a specific job. The virus-like color packages simply provide color rays.

Microflora

The second most abundant symbiotic microbes in the body are the microflora. I first noticed them many years ago in the blood, but these plant-like microbes are present throughout the body.

While microflora also provide life-giving color rays, their primary purpose is to help cells receive other types of nourishment. Some of the flora act like antennas that attract water and the nutrients, hormones, or information that a cell needs.

When the nutrients are too large for the cell, microflora surround and capture them with net-like structures. Then, they break the nutrients down into pieces that are small enough to easily pass through the cellular membrane. The nets also help the cells regulate their vibrations so they can better receive what they need, communicate, and harmonize with other cells.

When there’s an excess of something in one place and a deficiency somewhere else, the microflora know about it. They disassemble the excess so it can be redistributed among deficient cells—but they don’t transport it themselves. That’s the job of the microfungi.

Microfungi

Microfungi form microscopically thin, long threads that look like fascia. In fact, they do intertwine with fascia cells to nourish and hydrate them.

They also provide pathways for nutrients, water, color rays, and unwanted energy to move from one area of the body to another. This is another way the microbiome helps maintain good communication between cells. Due to the structural nature of microfungi, they also help cells stay together in communities.

The microfungi structure often provides a home for symbiotic viruses, giving them something to attach to so that they can feed the fungi itself, as well as surrounding cells.

Bacteria

When you hear the word microbiota, bacteria may be the first thing you think of. Indeed, the body also contains a wide variety of symbiotic bacteria, and they have the most functions—and the most-varied functions—of all. Here are a few of the ways I’ve observed them serving the body.

Some bacteria resemble native cells so closely that it might be challenging to distinguish between them. These bacteria proliferate when a cell is tired, weakened, or undernourished. By mimicking the cells, the bacteria can join them in communicating their needs. With both calling for necessary nutrients and color rays, it’s more likely the cells will receive them.

Bacteria may also mimic cells that have been damaged and can’t regenerate quickly enough to meet the body’s needs. These microbes can multiply more rapidly than our cells can divide, and will stand in for them until the cells replenish their population.

Some symbiotic bacteria protect native cells from potentially harmful bacteria. These harmful bacteria might originate outside the body or wander from one part of the body to an area where they aren’t typically found. When unrecognized or identified as foreign bacteria, they’re attacked. If they belong elsewhere in the body and the symbiotic bacteria can’t control them, it can lead to the development of auto-immune tendencies.

Other bacteria act as personal managers for the cells. This role is essential, because our native cells are so highly specialized. While they excel at their specific functions, they might lack a broader perspective and not know when to slow down or ramp up, for example.

Perhaps their most useful function, no matter where they live in the body, is to feed upon the metabolic wastes excreted by the cells. This is yet another way they help the cells stay efficient and balanced in their functions, always aiming to keep the body healthy.

Archaea

Though once classified as bacteria, it’s been discovered that archaea have a significantly different genetic makeup and comprise their own group. They are considered among the earliest living things and are highly intelligent and adaptable.

This adaptability serves an important purpose in our microbiome, allowing the archaea to fill a variety of roles. Each one is like a jack of all trades.

To perform in this way requires the greatest overview of what the body needs. Indeed, the archaea are the wisest and most experienced of the microbiota. They have the widest viewpoint and excel at problem-solving. Yet they are just as happy serving in the cleanup crew (described below).

Archaea seem to prefer living in the moister areas of the body, like blood and lymph, so they can get anywhere they’re needed faster.

Other populations of archaea live in our digestive tract and give us feedback as to what foods are most useful. Archaea are the microbes best able to communicate with us telepathically. If you ask your microbiota what food to eat or avoid, the archaea are the most likely to give you a reply.

In the intestines, the archaea tend to feed off wastes. I’ve read that they are responsible for producing intestinal gas, which interpret as their way of giving us feedback as to what foods to eat.

Another job of the archaea is to help clear the remains of dead cells and microbiota out of the body. This is the sole responsibility of what I call the cleanup crew.

The Cleanup Crew

This category includes a type of microbiota called helminths. These are multicellular worm-like creatures that break down the feces in our intestines so they can pass more easily through us.

Though they were once considered parasites, scientists are now realizing this isn’t always the case.

My observations agree with them. The difference is clear: The helminths that remain inside the intestines and help break down food and waste are beneficial. Those that bore into the intestinal lining and feed on native tissue or steal color ray food are not.

Another type of microbiota called protists also belongs in this category.

Protists consist of a diverse collection of organisms that cannot be classified as animals, plants, bacteria, or fungi. Populations of them will appear in organs where natural function is breaking down. For example, they might be found in a liver that is unable to clear its own metabolic wastes or the toxins delivered to it by the blood.

The protists seem to specifically target unneeded molecules and feed on the bits and pieces of dead cells and other microbiota that the white blood cells can’t access.

When a cell dies, protists proliferate around it and in the general area where dead cells are located. Digesting and clearing them takes a fair amount of energy.

As we age, our cells don’t live as long, and more protists are needed to clear them. Their work requires energy that becomes unavailable to healthy cells, shortening their life span even more. This can produce a downward spiral of sorts—especially when we aren’t kind to the microbiota trying to sustain us.

Remember, the number one purpose of every species of symbiotic microbiota is to preserve the cells of their host—us. They all work together to help us stay as healthy as possible. We therefore owe it to our microbiome to support it as best we can.

One way we can do this is to make a greater effort to avoid the three things that hurt our microbiome the most.

Read my next blog post to find out what they are!