“This is one of the most complex examples of parasites controlling animal behavior because it is a microbe controlling an animal – the one without the brain controls the one with the brain.” – David Hughes Penn State University
Within the cosmic battleground of Earth, an eternal symphony and conflict persist, entangling the bodies, minds, and souls of all living entities within a web of inescapable interplay.
There is no refuge from the intricate melody of life and the dark filaments of warfare that bind us, compelled by the magnetic forces of nature to partake in an unending song or engage in mutual combat.
Nothing and no one is immune.
This eternal war we can observe all around us in those victims who have lost the fight as they begin to lose their bodies and control of their minds.
Zombie ants are a perfect example of one of nature’s bizarre phenomena who lost the battle I speak.
Studies have found that they are simply infected with a fungus that takes over their bodily processes, and DNA, and corrupts them to turn them into obedient, mind-controlled servants.
Researchers found that these ants were – 50% ant and 50% fungus.
Zombies, mutants, or hybrids…
As many of you know who follow my work, I believe the same process happens to humans.
QUICK FACT: Did you know that molds/fungi have been found in 100% of autopsied human brains of people who died from Alzheimer’s disease? (Perhaps they were also taken over and their memories wiped clean by the same foreign invaders who stole the ant’s brain.)
And NO Mr. David Icke, they are NOT reptilian elites so please go back to the research desk…
Back to the ants…
A recent study showed how scientists examined the activated genes in the heads of infected zombie ants firmly attached to plants, comparing them with the heads of uninfected ants.
Their findings revealed that when ants were affixed to leaves but still displaying signs of life, only about half of the cells in their heads belonged to the ants themselves; the remainder comprised cells of the invading fungal parasite. Their cells had been combined in the blood, brain, head muscles, and fatty tissue.
During this period of zombie ant behavior, the parasitic fungus triggered a unique set of genes influencing neurotransmitters akin to serotonin, noradrenaline, and dopamine which exhibited heightened activity while the host ants manifested their peculiar zombie-like conduct.
For example, depletion of serotonin in ants is known to hinder proper foraging, and in other animals, disruption of these neurotransmitters can induce hallucinations and muscle spasms. Serotonin is involved in numerous physiological processes in ants as it is in humans such as sensorimotor skills like sleep, memory, feeding, pain, motor activity, biological rhythms, and neural development.
In other words, the fungi put the ant into a sleep-like waking state as it manipulates the behaviors in its favor by influencing these neurotransmitter systems and specific chemical processes that allow it to take over the mind.
Again, I contend that the same thing happens in humans.
As you can see, serotonin regulates and controls many functions crucial to an ant and a human’s survival and as I mentioned, this is done by our microbiota via neurotransmission.
In 2020, a study found that human neurons are like “mini computers” communicating through a root-like structure inside our bodies called dendrites.
A dendrite means “a structure of nerve cells that comprise the human brain.” The word was coined by scientists who first studied the structure of the brain, they noted its strong resemblance to trees so they named it after the Greek Dendron, meaning “tree.”
These dendrites appear to be natures, animals, mammals, and humans’ super internet signaling pathways that we all share. A type of biological internet for communication and a whole host of other mechanisms such as parasitism and natural selection.
A textbook neuron resembles a leafless tree, with extensive roots, i.e., dendrites leading to a robust, bulbous base—the body.
Electrical signals, akin to water and nutrients, ascend through dendritic roots into the body, where a hump-like structure amalgamates all information. If the sound wave/electrical stimulation is strong enough, it travels down a solitary tree trunk—the output cable, or axon—before being relayed to another neuron via bubbles containing chemical messengers or electricity.
Studies have shown that human dendrites are electrically excitable, exhibiting backpropagating action potentials and fast dendritic calcium spikes.
Dendritic processes play a fundamental role in receiving information via transducing receptors (sensory neurons) or incoming synaptic contacts (conventional neurons). In the presence of weak input signals, the neuron discards the data. Neuroscientists commonly describe single neurons as “binary” or “digital,” reflecting their tendency to either fire or remain inactive.
Through the examination of individual neurons in rodent brains, scientists have recently uncovered that dendritic trees are not merely passive cables; instead, they are highly active components that play a crucial role in a concealed layer of neural computation. Some dendritic trees, for instance, can produce electrical spikes five times larger and more frequent than the conventional firing of neurons.
Rather than recording from a living, intact human brain, the research team decided to study fresh slices of the brain’s cortex removed from patients due to epilepsy or tumors. Utilizing brain tissue from two different patient groups helped them identify signals unique to each brain disease, allowing the researchers to unravel the fundamental computations of human dendrites.
A peculiar signal quickly manifested.
Human dendrites exhibited activity, but the electrical spikes rapidly diminished as they traveled toward the cell’s surface. In contrast, a typical neural signal maintains its intensity as it travels along the output cable to its next destination.
What’s even stranger is that dendritic signals relied exclusively on calcium ions to generate electricity, a significant departure from conventional neural signaling.
The researchers concluded;
“It’s like suddenly discovering a new species that consumes carbon dioxide, rather than oxygen, to sustain its activity—except that species is part of you. ”
This is EXACTLY what I believe is happening to humans.
This species they speak of I contend are fungi/molds that can control and kill their victims, whether it be an ant, pant, or human as they see fit based on these electrical and chemical signals I speak of such as the loss of serotonin.
This loss would create a specific sound wave frequency that the fungi would use for sensing purposes to repel or magnetize their victims like what I contend happens to people who contract Alzheimer’s disease (AD). A disease with currently 50 million victims
For example, new studies have suggested that serotonin loss in humans may be a key player in cognitive decline, rather than a side-effect of Alzheimer’s disease.
As it turns out, approximately 90% of the serotonin the human body produces by our microbiota is in the gastrointestinal tract, where it regulates several bodily functions via a serotonergic pathway. Studies have found that the serotonergic pathway is modulated by gut commensal microbiota components in our gastrointestinal (GI) tract where it manages and controls the gut-brain axis.
Meaning it is our microbiome (fungi) that manages and controls (immune system) our physical and mental health.
What scientists are finding is that the microbiome has signaling mechanisms within this axis that allow it to communicate with the gut and the brain. This is called a neurotransmitter and serotonin seems to be one of the the most important mediators in microbiota–host interactions.
The serotonergic system controls the GI tract and the central nervous system (CNS) physiology. When this pathway is disrupted or corrupted, the disruption results in a wide range of pathologies that are affected thus causing a wide range of brain and intestinal diseases.
The serotonergic pathway plays a crucial role in sensorimotor function, which combines two important components: sensory input and motor output.
Sensory input to visual stimuli involves the information received through our sensory systems, including vision, hearing, smell, taste, touch, and proprioception (the sense of body position and movement).
Motor output refers to the response generated by our body in reaction to the sensory information received. Sensorimotor skills are also influenced by individual experiences and learning.
Sensorimotor skills refer to the ability to receive sensory messages from the environment and our bodies, and then generate an appropriate motor response. These skills are crucial for our daily functioning and play a fundamental role in our overall development and interaction with the world around us.
It involves the coordination and execution of movements, whether they are fine motor skills (such as writing or buttoning a shirt) or gross motor skills (such as walking or throwing a ball). These movements are the result of complex interactions between our brain, muscles, and nervous system.
Each of these sensory systems provides us with essential information about our surrounding environment and our bodies.
Sensorimotor skills are acquired and developed through a process of continuous learning and refinement from infancy through adulthood. In infancy, sensorimotor skills are foundational for the development of other cognitive and physical abilities.
Babies learn to grasp objects, visually track moving stimuli, and explore their environment through touch and taste. As they grow, they gain more control over their movements and refine their sensorimotor skills to perform more complex tasks.
Through repetition and practice, individuals refine their abilities and become more efficient in performing specific tasks. This process is known as motor learning. For example, a novice pianist may initially struggle with finger dexterity and coordination but with practice, they become more proficient in playing complex pieces.
For example, our visual system allows us to see and process visual stimuli, such as colors, shapes, and movements. Our auditory system enables us to hear and interpret sounds, while our olfactory system helps us perceive different smells.
Similarly, our taste buds allow us to experience flavors, and our sense of touch allows us to feel textures, temperatures, and pressure. Proprioception, on the other hand, provides us with information about the position and movement of our limbs and bodies in space.
Studies have indicated a correlation between motor activity and serotonergic function, and the firing rates of serotonergic neurons responding to intense visual stimuli.
In addition to the natural progression of sensorimotor skills through typical development, some individuals may experience challenges or delays in the acquisition of these skills. Sensory processing disorders, for example, can affect how individuals perceive and respond to sensory information.
Animal models propose that kainate signaling negatively influences serotonin actions in the retina, potentially impacting the regulation of the visual system. The descending projections create an inhibitory pathway referred to as the “descending inhibitory pathway,” which may have implications for disorders such as fibromyalgia, migraine, and other pain disorders, as well as the efficacy of antidepressants in treating them.
A neuron that secretes 5-HT is termed as serotonergic. It is a very important neurotransmitter in the Central Nervous System but when it becomes impaired, or damaged, it decreases in this process causing sensory processing disorders. Hence, pathology ensues along with illness and disease.
5-HT in humans is extensively present in various bodily systems, such as the nervous, gastrointestinal, and cardiovascular systems. It influences a broad range of physiological and pathological conditions, including pain, sleep regulation, aggression, feeding, anxiety, and depression.
The disturbance of 5-HT signaling in various pain states has been observed in both basic research and clinical studies, suggesting a potential explanation for certain diffuse pain conditions. In certain neuropathic pain models, the baseline level of 5-HT in the spinal cord was found to be reduced.
Researchers have found that the disruption of 5-HT neurotransmission contributes to the decline in cognitive processes associated with aging, Alzheimer’s disease (AD), and various neuropathologies, including schizophrenia, stress, mood disorders, and depression. Also, people with autoimmune disorders like AIDS and similar diseases have significantly lower 5-HT and an increased rate of infections.
Multiple studies have affirmed the pathophysiological importance of the 5-HT system in AD, with several drugs enhancing 5-HT neurotransmission proving effective in addressing AD-related cognitive and behavioral deficits.
5-HT receptors, 5-hydroxytryptamine receptors, or serotonin receptors, are a group of G protein-coupled receptor and ligand-gated ion channels found in the central and peripheral nervous systems. They mediate both excitatory and inhibitory neurotransmission.
As I explained in my previous essay, recent studies suggest that vibrations caused by sound waves directly affect the ion channels in fungal cells, resulting in electrical activity. Other hypotheses propose that sound-induced electrical responses in fungi are linked to their role in communication, growth, or defense mechanisms.
As it relates to nature, scientists have identified that the main jobs of fungi are breaking down organic matter, and processing nutrients and chemicals in a commensal, symbiotic, or pathogenic relationship with its host. For fungi to thrive within a host, they must navigate a dynamic and often challenging environment, necessitating the capacity to perceive and understand their surroundings.
Under typical circumstances, predisposing host factors, like immune suppression, play a crucial role in the survival and propagation of pathogens within mammalian hosts. Once inside the host, these pathogens must contend with the host’s microbiota for essential nutrients. For opportunistic pathogens, breaches in the normal physiological barrier, whether in mammals or plants, serve as entry points.
Fungi have developed various virulence mechanisms to elude the host’s immune system, a topic thoroughly explored elsewhere (Collette and Lorenz, 2011). Sensing these external cues is necessary to adjust fungal morphology, metabolism, mating, and virulence. Furthermore, extensive reviews have delved into how fungi sense environmental cues such as nutrients, gasses, light, and stress (Bahn et al., 2007).
Fungal infections have become a significant medical challenge, and a team of researchers at Baylor College of Medicine has made a significant breakthrough in studying the short-term effects of fungal infection in the brain. According to a study published in the journal Nature Communications, the researchers discovered that Candida albicans, a common yeast and type of fungus, can cross the blood-brain barrier and trigger an inflammatory response in mice.
This response led to the formation of granuloma-type structures and temporary mild memory impairments in mice.
Researchers injected C. albicans into mice’s bloodstream and discovered that the yeast can cross the blood-brain barrier, triggering the activation of microglia cells in the brain. The microglia cells became highly active, consuming and digesting the yeast, while also producing molecules that caused an inflammatory response.
This led to the formation of a granule-type structure called fungus-induced glial granuloma (FIGG). The mice infected with the yeast showed impaired spatial memory, which improved once the infection cleared. Although the yeast infection cleared in about 10 days, the microglia cells remained active and the FIGGs persisted for at least 21 days.
These amyloid molecules are typically associated with Alzheimer’s disease.
“These findings suggest that the role fungi play in human illness potentially goes well beyond allergic airway disease or sepsis,” according to Dr. David B. Corry, professor of medicine-immunology, allergy and rheumatology and Fulbright Endowed Chair in Pathology at Baylor College of Medicine.
“The results prompted us to consider the possibility that in some cases, fungi also could be involved in the development of chronic neurodegenerative disorders, such as Alzheimer’s, Parkinson’s and multiple sclerosis. We are currently exploring this possibility,” Dr. Cory said.
Since they do not have eyes and a nose to successfully adapt, fungi must be attuned to external environmental and biochemical factors to process this information to respond and identify unique host-specific elements. They do this by sensing and reacting to the host’s temperature, pH, gasses, nutrients such as sugars, amino acids, nitrogen, and other trace elements along with serotonin, which are all essential for the growth and viability of fungal symbioses or pathogeneses in every environment.
Given that the fungal cell wall maintains constant contact with its surroundings, the expression of receptors, such as pheromone receptors, on the cell wall surface becomes crucial.
Pheromone receptors are proteins that are sensitive to pheromones, which are chemical signals that organisms release to communicate with each other. These signals play a crucial role in various biological processes, including mating, territory marking, and social organization. Pheromone receptors are found in a wide range of organisms, from bacteria and fungi to insects and mammals.
In 1961, researchers noted that some “chemical messengers” act within an individual (e.g., hormones and “other excitatory substances” such as CO2), whereas others (i.e., “pheromones”) act between individuals via ingestion, absorption, or sensory receptors. However, fast forward to 2023, various studies have not revealed conclusively if humans create pheromones on their own.
Considering the chance that we do not create them on our own, the question arises: where do they come from?”
Pheromones in humans may be present in bodily secretions such as urine, semen or vaginal secretions, breast milk, and potentially also saliva and breath, yet most attention thus far has been directed toward axillary sweat. However, studies suggest that we can detect each other through unique smells produced by signaler pheromones
In fungi, pheromone receptors are particularly important for sexual reproduction. They are eukaryotic organisms that reproduce both sexually and asexually.
During sexual reproduction, fungi use pheromones to signal their mating compatibility with other individuals of the same species.
This process is essential for the fusion of specialized sexual structures called gametangia, ultimately leading to the formation of new genetically diverse individuals.
Here is an image explaining this biological process:
The typical lifecycle of fungi involves the following steps:
1. Pheromone production: Fungi release pheromones into their environment. These pheromones act as signaling molecules, indicating the presence and mating compatibility of the releasing individual
2. Pheromone reception: Potential mating partners have pheromone receptors on their cell surfaces. These receptors are specific to the type of pheromones produced by compatible mating partners.
3. Chemotropism: The receiving fungal cells respond to the pheromones by growing towards the source of the pheromone (a process known as chemotropism). This directional growth helps mating partners to come into proximity.
4. Cell fusion (plasmogamy): Once the compatible cells come into contact, they undergo cell fusion or plasmogamy. This fusion of cytoplasmic contents is a crucial step in sexual reproduction.
5. Formation of sexual structures: Following plasmogamy, specialized structures such as a zygote or a dikaryotic mycelium are formed, depending on the fungal species.
6. Completion of sexual reproduction: The sexual structures eventually lead to the formation of spores or other structures that can disperse and give rise to new individuals.
The entire process is tightly regulated by the interaction between pheromones and their corresponding receptors. The specificity of these interactions ensures that mating occurs only between compatible individuals of the same fungal species. The study of pheromone signaling in fungi has provided valuable insights into the molecular mechanisms underlying sexual reproduction in eukaryotic organisms.
These pheromone receptors not only facilitate chemotropism for mating but also serve other essential roles. These chemicals in the body are “electrically charged” — when they have an electrical charge, they are called ions. ‘
The term “ion” finds its origin in the Greek language, specifically derived from the neuter present participle of “ienai” (Greek: ἰέναι), which translates to “to go.” In the realm of ions, a cation is associated with downward movement (Greek: κάτω pronounced kato, meaning “down”), while an anion is linked to upward movement (Greek: ano ἄνω, meaning “up”).
It is this ion channel that I believe is the main method that fungi use to exploit and corrupt once the negative charge ions become too imbalanced
An ion, as introduced by English physicist and chemist Michael Faraday in 1834, is a term used to describe a species that travels from one electrode to another through an aqueous medium. This concept was developed after a suggestion by the English polymath William Whewell. To understand the concept of an ion, it is necessary to delve into the world of chemistry and electricity.
In the realm of electrochemistry, ions play a crucial role. An ion is an atom or a molecule that has gained or lost one or more electrons, resulting in a net positive or negative charge. These charged particles are formed when an atom gains or loses electrons to achieve a stable electronic configuration.
The operation of batteries also relies on ion migration.
In a typical battery, chemical reactions occur at the electrode surfaces, resulting in the generation of a voltage. This voltage drives the migration of ions between the electrodes, allowing for the transfer of charge and the production of electrical energy.
During discharge, positive ions move from the anode to the cathode, while negative ions move in the opposite direction. This ion migration enables the flow of electrons through an external circuit, producing an electric current.
The term “ion” was coined by Faraday to describe the movement of these charged species during electrolysis. Electrolysis is a process that utilizes an electric current to drive a non-spontaneous chemical reaction. It involves the decomposition of an electrolyte, a substance that conducts electricity when dissolved in a solvent, typically water.
During electrolysis, an external electric current is applied to an electrolytic cell, which consists of two electrodes, an anode (positive electrode) and a cathode (negative electrode), immersed in an electrolyte solution. When the electric current flows through the cell, ions are attracted to the respective electrodes based on their charge.
The movement of ions from one electrode to another through the aqueous medium is what Faraday referred to as an ion catation. The term “catation” is derived from the Greek word “kation,” meaning “to go down.” This reflects the movement of positively charged ions, known as cations, towards the cathode.
On the other hand, negatively charged ions, known as anions, migrate towards the anode during electrolysis. These anions are formed when an atom gains one or more electrons, resulting in a negatively charged species. The migration of anions is often referred to as anion catation.
Anion (−) and cation (+) indicate the net electric charge on an ion. An ion that has more electrons than protons, giving it a net negative charge, is named an anion, and a minus indication “Anion (−)” indicates the negative charge. With a cation it is just the opposite: it has fewer electrons than protons, giving it a net positive charge, hence the indication “Cation (+)”.
In addition to their roles in electrochemical processes, ions are also essential for maintaining the balance of charges in various biological systems. In living organisms, ions such as sodium (Na+), potassium (K+), calcium (Ca2+), and chloride (Cl-) play vital roles in nerve conduction, muscle contraction, and maintaining osmotic balance.
The movement of ions across cell membranes through specialized ion channels allows for the transmission of electrical signals and the regulation of cellular functions.
HOW FUNGI USE SOUND WAVES AND FREQUENCIES CONTROL THE WORLD
Studies have shown that fungi are extremely polarized organisms that constantly produce internal electrical currents and fields that are generated by hyphae. Its growth requires a constant supply of proteins and lipids to the hyphal tip.
Researchers have proven that the individual hyphae of the filamentous fungi constantly perform cellular “monologue” and cell-to-cell dialog using signal oscillations to acquire or magnetically attract the nutrients it requires to grow and thrive within the host.
For example, studies have found how psilocybin reduces low-frequency oscillatory power in users’ brains, increases overall firing rates, and desynchronizes local neural activity. It indicates experiences correlate with the lagged phase synchronization of delta oscillations. Schizophrenia, which mimics symptomatically the psychotic effects of psilocybin, is associated with diffuse delta rhythms.
These oscillations create electricity which is one of the key factors shaping their growth and development. The hyphae become polarized and entrained as the branching of mycelium is induced by electric field frequency, which it uses to communicate and transport the raw human materials within the blood and central nervous system.
The electrical current helps fungi with the translocation of resources it gathers within the host using magnets and hydraulic pressure.
Recent studies have explored the potential of utilizing frequency-specific sounds as a viable substitute for chemical fungicides in combatting plant diseases. The research findings indicated that high frequencies possess the ability to impede mycelium growth, akin to the impact of high-pitched noises causing deafness.
Further investigation revealed noticeable morphological changes in the mycelium, providing insights into the mechanism. This suggests that certain sound wave frequencies can induce stressful growth conditions, presenting a sustainable approach to combating pathogenic fungal pathogens.
As signaling and metabolism in organisms are controlled by a precise ionic gradient across membranes, the disruption of this gradient contributes to cell death. This is a common mechanism exploited by natural and artificial biocides, including the ion channelsgramicidin and amphotericin (a fungicide).
So, not only are ion channels used to treat people with antifungal medicines, but supplementing with 5-HT in the serotonergic pathways can stop fungi from growing in the body and brain. As I mentioned, the serotonergic pathway is modulated by the gut commensal where 5-HT is biosynthesized with L-tryptophan (Trp) derived from our diets.
As I mentioned, the loss of serotonin or 5-HT causes a condition known as sensory processing disorder (SPD), which interferes with the typical processing of sensory information (stimuli) in the brain. This involves the processing of what you see, hear, smell, taste, or touch.
SPD may impact all senses or just one, resulting in heightened sensitivity to stimuli compared to the general population. These disorders can result in hypersensitivity or hyposensitivity to certain sensory stimuli, leading to difficulties in regulating behavior and responding appropriately to the environment.
For example, ants normally do not venture out solo and climb a big tree to nowhere destined to become its aerial deathbed.
Once the ant victim clamps down on the leaf, the parasitic fungus triggers a series of genes responsible for the degradation of the ants’ jaw muscles, resulting in the lockjaw effect. Simultaneously, it activates genes that suppress the ant’s immune system, facilitating the unimpeded growth and proliferation of fungal cells throughout the ant’s head tissues.
As the ants cease their struggle and succumb to the fungus, a staggering 75% of the cells in their heads transform into fungal cells.
The ant is no longer an ant but a parasitic fungus that has taken over an ant carcass, thus becoming a “zombie ant.”
During this period, numerous genes in the fungal genome related to ant host digestion, cell growth, and reproduction shift into high gear, marking the fungus’s transition to a rapid growth phase for the development of its reproductive stalk so it can shoot spores to infect other ants.
In another study from 2019, researchers found that at the moment of behavioral manipulation by the fungus, the host’s brain is not invaded by the fungus.
Instead, it invades other areas of the ant’s muscle tissue making them a co-pilot.
They discovered that despite not being invaded by the parasite, the brains of manipulated ants are notably different, showing alterations in neuromodulatory substances, signs of neurodegeneration, changes in energy use, and antioxidant compounds that signal stress reactions by the host.
I have often wondered if fungi/molds can do this to ants and other insects, why not humans?
After all, these tiny but deadly creatures have been around for millions of years and are well known for their industrious nature and strong social organization.
This so-called co-pilot stage may be what we witness in individuals with early-stage Alzheimer’s disease where the fungal cells eliminate and displace the human cells like it does the ant. Thus causing various pathologies.
At this stage, we call it dementia.
Ergothionine, a fungal-derived compound with known neuronal cytoprotection functions was found to be highly elevated in zombie ant brains suggesting the fungus, which does not invade the central nervous system, is preserving the brain.
Ergothioneine is a naturally occurring amino acid compound that is produced in relatively few organisms, notably actinomycetota, cyanobacteria, and certain fungi. Ergothioneine was first discovered in 1909 and named after the ergot fungus from which it was first purified.
The researchers found thousands of unique chemicals, most of them completely unknown. This, according to Hughes, is not surprising, since little previous work has mined these fungi for the chemicals they produce.
But what did stand out were two known neuromodulators, guanobutyric acid (GBA) and sphingosine. These both have been reported to be involved in neurological disorders and were enriched when the fungus was grown in the presence of the brains of its target species.
“There is no single compound that is produced that results in the exquisite control of ant behavior we observe,” de Bekker said. “Rather, it is a mixture of different chemicals that we assume act in synergy.
“But whatever the precise blend and tempo of chemical secretion,” she said, “it is impressive that these fungi seem to ‘know’ when they are beside the brain of their regular host and behave accordingly.”
Noted Hughes, “This is one of the most complex examples of parasites controlling animal behavior because it is a microbe controlling an animal — the one without the brain controls the one with the brain.
By employing metabolomics and controlled laboratory infections, we can now begin to understand how the fungi pull off this impressive trick.”
GNOSTIC WARRIOR CONCLUSION:
The research clearly shows that fungi can zombify an ant via a multi-prong approach. Meaning, there is not one specific method or neurotransmitter that the fungi use to manipulate its host.
Hence, it is hacking multiple bodily and mental processes to achieve its aim – Total Control.
To study this phenomenon, scientists use data sets called multiomics or “panomics” or “pan-omics” as a biological analysis approach to analyze complex biological big data to discover novel associations between biological entities, pinpoint relevant biomarkers, and build elaborate markers of disease and physiology.
The meaning of multiomics is to study life in a synergetic way using data sets with multiple “omes“, like the genome, proteome, transcriptome, epigenome, metabolome, and microbiome. That is essentially what I’m doing in the creation of this essay but also using a multidisciplinary scientific and logical approach to my theory.
A 2023 “multiomic” study found the dysregulation of neurotransmitter levels and neuronal signaling. The researchers believe this alteration or corruption occurs during infection, which immediately triggers;
1 – differential expression of neurotransmitter synthesis and receptor genes
2 – altered abundance of metabolites and neurotransmitters (or their precursors) with known behavioral effects in ants and other insects, and
3 – possible suppression of a connected immunity pathway. We additionally report signals for metabolic activity during manipulation related to primary metabolism, detoxification, and anti-stress protectants.
The researchers concluded;
“Taken together, these findings suggest that host manipulation is likely a multi-faceted phenomenon, with key processes changing at multiple levels of molecular organization.”
What is important to understand is that these alterations in the body lead to changes in animal host behavior mostly referred to as manipulations, preceding a fatal change in behavior. For example, the infected zombie ants, they began to stop communicating with their fellow ants as they then left their nest and normal foraging trails venturing solo into the forest which is not natural.
In our human society, we can witness similar traits among the mentally ill or people who have a disease and the alcoholic and drug addicts of our world. Their bodies and brains have been altered or corrupted
Scientists speculate that the diverse alterations observed in hosts might serve as exploitable traits for fungal parasites. This strategy allows the parasites to exploit host behaviors and symptoms without the need for costly host rewiring.
They believe that these various changes may represent behaviors that can be easily coopted for manipulation by fungal parasites.
The parasitical fungi may be taking advantage of existing host processes and symptoms without relying on costly mechanisms to “rewire” their hosts.
The same process I believe occurs in humans with similar zombie-like traits.
The long list of diseases and addictions killing people worldwide makes me ponder if these same fungi are manipulating our thoughts and behaviors, which seems to be affecting almost everyone alive.
It is the alcoholic who cannot stop drinking the very poison that is killing them. (Globally an estimated 237 million men and 46 million women suffer from alcohol-use disorders. – WHO)
It is the obese person who for the life of them, cannot stop eating junk that will cause them to have a heart attack and die. (Worldwide, more than 1 billion people have obesity—650 million adults, 340 million adolescents, and 39 million children. – WHO)
Millions of people losing control of their bodies as they lose their minds.
Annual incidence of Alzheimer’s disease and other dementias in Europe from 1990 to 2019(per 100,000)
The reengineering of potentially billions of people around the world within a Fungi Deep State.
Hundreds of millions of people have lost the ability to think or behave like a normal human being.
A globe covered by human fungal mutants or who we would call addicts and the mentally ill.
A defacto death sentence for the host but food and a playground for the very fungi who made it all happen – The Zombie Apocalypse.
Nature and life all around us are listening and secretly communicating via hidden networks.
A phenomenon called “bioacoustics and biocommunication.” Meaning, “the sound of life” or “the communication of life.”
The birds sing as they work hard pollinating the landscape producing fruit and seeds for the plants.
Humming to their own tune, bees carry on the great work of transporting pollen from one flower to the next.
Thus producing an alchemical celebration for the eyes with beautiful colorful flowers and a golden elixir we call honey that we can taste.
All the while, the plants, and trees are cognisant of the song of nature as they emit their sound waves secretly communicating through their roots via a vast global network of fungal mycelium.
Fungi, often hidden beneath the soil or nestled within decaying matter, form vast interconnected networks known as mycelium that grow long filaments, or ‘hyphae’, which interlink the root tips of different plants at a microscopic level.
The interlinking of fungal hyphae between different plant roots forms a symbiotic relationship known as mycorrhizae. Mycorrhizal fungi facilitate nutrient exchange between plants and enhance their resilience to environmental stressors.
The fruiting body is not just for the nourishment of the fungus itself but also the entire forest ecosystem, carrying electrical and chemical signals between plants. This allows different plant species that are compatible with the same species of mycorrhizal fungi to be connected via one common mycelium, coming together like the strings of a piano that strike a single harmonic chord.
By responding to sound waves, fungi may be able to optimize their mycorrhizal associations, enhancing nutrient uptake and improving plant growth and survival.
Hyphae make up a messy mass of branching, which gives rise to the vegetative mycelium. It is the mycelium that responds to sound waves.
The sound waves draw out the minuscule fungal tendrils like a snake charmer luring out snakes with music.
An interconnected bionetwork that appears to connect all living things together in its dark web that stretches deep into the earth’s abyss and 33,000 feet into space.
A universal fungal matrix that scientists are just learning to decode.
Recent studies have revealed that molds/fungi are magnetized (attracted) to low amplitude and low-frequency sound frequencies in the environment.
Scientists have made remarkable discoveries measuring the electrical responses of fungi (molds) to sound stimuli that have revealed that they demonstrate measurable electrical activity in response to different sound frequencies and patterns.
These findings suggest that fungi possess a form of sensory perception, enabling them to detect and respond to auditory cues. Moreover, they possess the remarkable ability to convert sound into electrical signals, much like our own auditory system, which may be a manifestation of the information received and then communicated between distant parts of the fungal colonies.
Researchers have also found that sound waves also have a profound impact on the biochemical processes within fungi, triggering the release of compounds like melatonin and indole, which are typically produced in times of stress and injury.
They have observed electrical spikes and oscillations in the fungi’s mycelium when exposed to music, vibrations, or even the sound of approaching predators.
It is hypothesized that sound might also serve as a means for fungi to communicate with each other, potentially facilitating resource sharing, warning signals, or even cooperative behavior.
By responding to sound, they may adapt their growth patterns, spore dispersal strategies, or interactions and defense mechanisms with other organisms.
These fascinating microorganisms, crucial to our ecosystems, can respond to sound waves in different ways, either by stimulating the growth of certain species or by inhibiting the growth of other competitors. This intriguing phenomenon can be attributed to the fungi’s ability to respond to sound waves in the environment that act to magnetize or repel through either a biochemical or transductive mechanism.
For example, sound waves can cause changes in air movement and humidity levels, which can in turn impact the growth and distribution of fungi. Some studies have suggested that certain frequencies of sound waves can enhance air circulation and increase evaporation rates, creating conditions that are less favorable for fungal growth.
Conversely, other studies have shown that sound waves can disrupt air currents and promote the spread of fungal spores, leading to increased colonization and infection rates.
The exact mechanisms responsible for fungi’s electrical responses to sound stimuli are still under investigation. Some theories suggest that vibrations caused by sound waves directly affect the ion channels in fungal cells, resulting in electrical activity. Other hypotheses propose that sound-induced electrical responses in fungi are linked to their role in communication, growth, or defense mechanisms.
The term “ion” finds its origin in the Greek language, specifically derived from the neuter present participle of “ienai” (Greek: ἰέναι), which translates to “to go.” In the realm of ions, a cation is associated with downward movement (Greek: κάτω pronounced kato, meaning “down”), while an anion is linked to upward movement (Greek: ano ἄνω, meaning “up”).
Chemicals in the body are “electrically-charged” — when they have an electrical charge, they are called ions. The important ions in the nervous system are sodium and potassium (both have 1 positive charge, +), calcium (has 2 positive charges, ++) and chloride (has a negative charge, -).
According to Science Daily;
“Elemental particles that transmit both heat and sound — known as acoustic phonons — also have magnetic properties and can, therefore, be controlled by magnets, even for materials thought to be ‘nonmagnetic,’ such as semiconductors. This discovery ‘adds a new dimension to our understanding of acoustic waves,’ according to a landmark study.
“This adds a new dimension to our understanding of acoustic waves,” said Joseph Heremans, Ph.D., Ohio Eminent Scholar in Nanotechnology and a professor of mechanical engineering at Ohio State whose group performed the experiments.
“We’ve shown that we can steer heat magnetically. With a strong enough magnetic field, we should be able to steer sound waves, too.”
People might be surprised enough to learn that heat and sound have anything to do with each other, much less that either can be controlled by magnets, Heremans acknowledged.
But both are expressions of the same form of energy, quantum mechanically speaking.
So any force that controls one should control the other.”
Researchers have found that high-intensity pulsed magnetic fields are widely used as a physical non-thermal sterilization technology in food processing, while weak magnetic fields are better at activating microorganisms and promoting their growth.
According to Science Direct, “the effect of magnetic fields on organisms, magnetic fields are classified into different intensity levels: weak (<1 T), strong (1–5 T) and ultra-strong (>5 T). Weak magnetic fields are better at activating microorganisms and promoting their growth [37], [38], [39]. Strong magnetic fields kill microorganisms.
The biological effects caused by low-frequency ultrasound include (1) changes in cell membrane permeability and increased cell growth rate; (2) changes in molecular conformation and intensification of reaction processes; and (3) activation of intracellular signal transduction systems and changes to the synthesis of metabolites within the organism.”
Low-frequency ultrasound has low energy consumption and reduced processing time and thermal effects, which can improve cell membrane permeability
Our cell membranes serve as our barriers and gatekeepers, but they are semi-permeable, which means that some molecules and organisms can diffuse across the lipid bilayer but others cannot.
This is where my whole theory of demonic fungi controlling the human brain rests…
In 2013, a Korean group examined the viability of employing frequency-specific sounds as an alternative to chemical fungicides for plant disease management. Their investigation unveiled that elevated frequencies possess the ability to impede the growth of mycelium, mirroring the effect of high-pitched noises causing deafness in humans.
Research has showed that high frequencies are capable of inhibiting growth of the mycelium, eerily similar to how high-pitched noises can deafen us.
This suggests that certain sound wave frequencies can induce stress in growth conditions.
On the other hand, low-frequency sounds seem to increase the productivity of certain fungi. For example, oyster mushrooms, known for their role in Asian cuisines, can be ‘sound treated’ and cultivated on sawdust, to increase their yield and rate of growth.
The study of sound wave-fungal interactions sheds light on the interconnectedness and complexity of the natural world.
The potential applications of sound wave manipulation in agriculture and horticulture are intriguing. By understanding the effects of sound waves on fungal growth, researchers and farmers could potentially harness these findings to optimize crop production and disease management.
For example, the use of specific frequencies of sound waves could be explored as a means of stimulating beneficial fungal symbiosis in plant roots, enhancing nutrient uptake and overall plant health. Conversely, sound wave technologies could be developed to disrupt the growth and spread of pathogenic fungi, reducing the need for chemical fungicides and promoting sustainable farming practices.
From plants subtly dancing to melodies to fungi exhibiting electrifying responses, the scientific exploration of these phenomena opens up new avenues for understanding and harnessing nature’s hidden secrets.
My ultimate theory is that fungi can also magnetize to animals and mammals, including humans via the same low frequencies to cause illness, disease, madness and death. A theory that I believe is being substantiated more and more.
When we live healthy and are on a higher vibration, we repel parasitical fungi.
As we delve deeper into this realm, it becomes clear that our world is intricately connected through the language of sound, inviting us to listen, explore, and embrace the symphony and even death metal that surrounds us in its web.
Alzheimer’s disease (AD) is a progressive brain disorder that destroys memory and thinking skills, ultimately causing an inability to perform even simple tasks. It also causes a significant slowdown in a person’s brainwave frequency activity to the point they could be medically described as living in a permanent sleep-like state.
In addition, people with this disease experience atrophy of the brain, which simply means that it is decaying or wasting away. (1) Hence, the old adage, use it or lose it applies to not only brain function, but whether you will have use of your mind, cognition, and memories as you age.
The same thing occurs to your muscles which is medically described as the wasting (thinning) or loss of muscle tissue. The main cause of atrophy is lack of physical activity or disuse (physiologic) of muscles occurs when you don’t use them enough.
As it related to atrophy of the brain, this is what I contend is one of the main causes of dementia and Alzheimer’s Disease worldwide. I believe this wasting away is the result of not actively using your brain on a regular basis to process and learn new information.
The resulting effects of this atrophy allow our microbiome and in particular, fungi to commandeer our cells, neurons, and central nervous system via our gastrointestinal tracts to induce a loss of consciousness or a sleep-like waking state.
As if we have biological laws programmed into our genes that supersede all human-made legal systems and structures that determine our fates. One of these ancient legal codes for not using our brains is to have them slowly eaten from within and wiped clean of all memories attained in this life.
What better and more sinister way than to have the very microbes within our body, blood, and organs be the very legislators of all life?
As it is related to dementia and Alzheimer’s, it is the fungi working within their central nervous system and brains that is turning off certain normal autonomous functions to make them sleep while they are awake in a covert biological attempt to control their minds as it steals their memories.
For example, a 2012 study found that fungal pathogens within the gut microbiota, which are normally well tolerated, may disseminate via the circulation to other sites including the brain leading to a systemic fungal infection, resulting in significant pathology and mortality (Brown et al., 2012).
Several studies have shown that the autopsied brains of Alzheimer’s patients reveal that they are infected with often multiple types of fungi (molds).
Fungal infections have also been widely observed in their blood vessels, which may explain why people who have Alzheimer’s also suffer from vascular pathology.
This is interesting given the fact that it appears to be a memory stealer and brain eater. It makes sense then that fungi may be the culprit responsible for this mind-decaying disease.
But this knowledge has been known by scientists for well over one hundred years.
In 1910, Czech psychiatrist, and an expert on dementia and Alzheimer’s disease, Oskar Fischer, proposed that these diseases were caused by foreign bodies in the brain, most likely fungi, which provoked inflammation and amyloid plaques (see Eikelenboom et al., 2006; Goedert, 2009; Mar 2009 conference news).
In his 1907 paper, Alzheimer described the presence of plaques and tangles in one case of presenile dementia, whereas Fischer described neuritic plaques in 12 cases of senile dementia. These were landmark findings in the history of research in dementia because they delineated the clinicopathological entity that is now known as Alzheimer’s disease.
in 2014, compelling evidence for the existence of fungal proteins in brain samples from Alzheimer’s disease patients. The study titled, “Fungal infection in patients with Alzheimer’s disease,” stated “a variety of fungal species in these samples, dependent on the patient and the tissue tested.
DNA sequencing demonstrated that several fungal species could be found in brain samples. Together, these results show that fungal macromolecules can be detected in the brains of Alzheimer’s disease patients. To our knowledge, these findings represent the first evidence that fungal infection is detectable in brain samples from Alzheimer’s disease patients.” (2)
A 2015 study titled, “Different Brain Regions are Infected with Fungi in Alzheimer’s Disease (AD),” showed the possibility that AD is a fungal disease, or that fungal infection is a risk factor for the disease. The researchers provided evidence in the study that tissue from the central nervous system (CNS) of AD patients contained fungal cells and hyphae.
According to the researchers, “Different brain regions including external frontal cortex, cerebellar hemisphere, entorhinal cortex/hippocampus and choroid plexus contain fungal material, which is absent in brain tissue from control individuals. Analysis of brain sections from ten additional AD patients reveals that all are infected with fungi.
Eleven patients (plus three additional CP samples) were described in this study, as well as in four patients previously analyzed, there is clear evidence for fungal cells inside neurons or extracellularly.
Therefore, 100% of the AD patients analyzed thus far by our laboratory presented fungal cells and fungal material in brain sections.
Moreover, fungal macromolecules (polysaccharides, proteins and DNA) have been found in blood serum from AD patients, and fungal proteins and DNA were detected by proteomic analyses and PCR, respectively, from frozen tissue of AD brain.
Collectively, our findings provide compelling evidence for the existence of fungal infection in the CNS from AD patients, but not in control individuals. (3)
It is mostly present in the brain’s major site of learning and memory, the hippocampus.
The study reports, “What causes neurodegenerative diseases like the most common early symptom of Alzheimer’s which is difficulty remembering newly learned information because Alzheimer’s changes typically begin in the part of the brain that affects learning, is still largely unknown, but something destroys nerve cells in the brain over a period of time as victims gradually lose their minds.”
Numerous studies suggest that the accumulation of beta-amyloid peptides (betaAP) plays a central role in the pathogenesis of Alzheimer’s disease. It is well established that betaAP has a wide range of toxic effects on neurons and we can connect their production in the human body to fungi.
The amyloid-beta precursor protein is an important example. It is a large membrane protein that normally plays an essential role in neural growth and repair. However, later in life, a corrupted form can destroy nerve cells, leading to the loss of thought and memory.
Scientists at the Stanford University School of Medicine have shown how the disease is strongly correlated with the overproduction and accumulation of amyloid-β peptide, which begins destroying synapses before it clumps into plaques that lead to nerve cell death.
A 2009 study found that the amyloid-β peptide induced depolarization of skeletal muscle plasma membranes can significantly disturb the functioning of skeletal muscles and therefore contribute to motor dysfunction observed in Alzheimer’s disease and other disorders associated with βAP accumulation.
Depolarization causes the rapid change in membrane potential from a negative to a positive state. The process of depolarization begins with a stimulus like fungi.
Brainwave activity is related to oscillatory activity at different frequencies ranging from 2–4 Hz (delta), 4–8 Hz (theta), 8–13 Hz (alpha), 13–30 Hz (beta), and >30 Hz (gamma). These frequencies transmit certain physiological information on the brain’s functional state during wake and sleep cycles.
The EEG findings of patients with Alzheimer’s disease show a slowing of alpha activity and an increase in slow-frequency activity
A few studies have shown a significant increase in delta and theta power in conjunction with a decrease in alpha and beta power over a period of two years from diagnosis of dementia. In another study, significant increases in delta and theta were found with a decrease in beta, alpha, and mean frequency.
The awakened state is medically described as being in the alpha frequency, which is mainly related to a person’s global attentional readiness. Alpha rhythms represent the dominant resting oscillations of an awakened human brain and have been linked to intelligent quotient, memory, and cognition. (5)
New research has revealed how fungi/molds can become lodged in our blood vessels, restricting blood flow as it blocks the blood supply to our brains.
These microbes start corrupting our immune system and biological autonomous processes as they rapidly multiply in what appears to be an attempt to commandeer the central nervous system to control our minds.
Not only can fungi block the blood flow to our brains, but they can also grow in the small blood vessels causing them to stretch, form clots, and explode.
Blood flow is very important when it comes to IQ because research has shown that a lack of blood flow to the brain has been associated with less intelligence and having an adequate amount of blood flow has been proven to increase intelligence.
Altered cerebral blood flow (CBF), which means less blood flow to the brain has been proven to lower IQ and cause severe mental disabilities, psychosis, and chronic schizophrenia (SCZ).
Studies have shown that fungi are extremely polarized organisms that constantly produce internal electrical currents and fields that are generated by hyphae. Its growth requires a constant supply of proteins and lipids to the hyphal tip.
Researchers have proven that the individual hyphae of the filamentous fungi constantly perform cellular “monologue” and cell-to-cell dialog using signal oscillations to acquire or magnetically attract the nutrients it requires to grow and thrive within the host.
For example, studies have found how psilocybin reduces low frequency oscillatory power in users brains, increases overall firing rates and desynchronizes local neural activity. It indicates experiences correlate with the lagged phase synchronization of delta oscillations. Schizophrenia, which mimics symptomatically the psychotic effects of psilocybin, is associated with diffuse delta rhythms.
These oscillations create electricity which is one of the key factors shaping their growth and development. The hyphae become polarized and entrained as the branching of mycelium is induced by electric field frequency, which it uses to communicate and transport the raw human materials within the blood and central nervous system.
The electrical current helps fungi with the translocation of resources it gathers within the host using magnets and hydraulic pressure.
Think of it like a driverless Tesla navigating the U.S. highway and air traffic system but it moves things around autonomously with electrical currents and hydraulic pressure without the need for the driver to consciously pilot the vehicle or aircraft
Researchers have discovered that fungi exhibit “several types of oscillations and characterized families of fast, slow, and very slow oscillations.
These electrical oscillations are very similar to the human brain, where fast oscillations might be related to responses to stimulation, including endogenous stimulation by the release of nutrients, and slow oscillations might be responsible for memory consolidation.”
Scientists believe that the direction of hyphal extension and the frequency of branching and germination could be affected by this electric field. Meaning the electric field’s frequency and power or lack thereof produced in our bodies determines our fates.
The long, filamentous tendrils that these organisms use to penetrate their host’s tissue and blood to gather nutrients and information from their environment or host. All the while within your cells, blood, veins, and organs, it grows within the perfect environment as it procreates, and explores, creating a network of hyphae that turns into a ball-like mass called mycelium.
One that I believe grows as it molds itself within our veins and central nervous system creating – Mold People.
As I have explained in a previous essay, trees actually communicate through a complex network of fungi that connect trees forming a symbiotic relationship. The uncanny resemblance between the human dendrites which are like filamentous structures within the brain and the fungi in the air and within the soil (mycelium).
You will find that these fungal mycelium networks are remarkably similar to the neural and central nervous systems of humans and animals and almost every biological system seems to be a copy of a copy. After all, they all serve the same means.
HOW DO FUNGI MIND CONTROL AND ARE THE BODILY LEGISLATORS OF HUMANS FROM WITHIN
A study that was published in the journal PLoS Pathogens shows how the fungus known as Cryptococcus neoformans infects our blood and then becomes lodged in blood vessels where they live and grow preventing blood flow and increasing blood pressure.
Cryptococcus is found all over the world in soil and it is often in bird excrement. It is the most common fungus that causes thousands of serious infections worldwide. If you breathe the fungus in, it infects your lungs and blood and can spread throughout the body (disseminate).
It is a facultative intracellular pathogen, which means that they are capable of growing and reproducing inside the cells of a host.
Several studies have shown that fungi cross the blood/brain barrier to infect the brain blood vessels as it spreads into the brain causing “fungal meningitis,” which affects an estimated 2.5 million people each year.
Dr. Simon Johnston, from England’s University of Sheffield’s Department of Infection, Immunity and Cardiovascular Disease, said: “The brain has very complex and effective defenses against microbes, but we have identified a simple and effective method that microbes may use to escape the blood and enter the brain.
“Previous research has focused on how microbes can break down the defenses of the brain or use immune cells as a route into the brain. We can demonstrate how, for some microbes, damaging blood vessels is a very effective method of invasion.
“Our immune system is very effective at recognizing and destroying microbes, including in the blood. However, some microbes can escape the immune cells and it is these microbes that would be most effective at using blood vessels bursting as a way into the brain.”
This is exactly how fungi/molds can start controlling our brain causing mental illness and various other diseases depending upon wherever they have made their home in our bodies.
As it infects our cells, it appears to hack them by slowing or stopping the normal oscillatory activity and biological rhythms.
This is interesting because recent research suggests that spontaneous electrical low-frequency oscillations (SELFOs) are found across most organisms, from fungi to humans, and play an important role as electrical organization signals that guide the development of all organisms.
Meaning that these electrical oscillations are the core mechanisms at the cell level determining how all organisms on earth communicate, grow, live, and die, as well as the quality of life.
Communication is crucial for all life on earth from fungi to humans.
As it relates to fungi, researchers have shown that they constantly use a form of constant “self-talk”, or monolog, to send signals to one another and possibly to explore the environment for another host of what is called a “fusion partner.”
Many studies have well established that the microbiomes of our bodies host vast microbial communities that communicate with each other internally within a human host, affecting many metabolic processes and they also communicate externally. They not only influence the immune system but also modulate the development of neural tissues in conjunction with neuromodulators and neurotransmitters.
As a result, they can profoundly influence health.
They do this by fusing with our cells thus becoming one with the human species as it appears to do with all life.
Scientists have discovered that this hyphal fusion within the host usually results in a form of programed cell death.
Studies have shown the formation of channels between fungal hyphae by self-fusion creating a fungal colony of a complex interconnected network.
A type of biological computer ouroboros program that is self-perpetuating as it mates with itself inside its host and hacks its cells to ultimately fuse together as one entity.
Unlike humans who use their eyes as visual cues from stimuli to explore their environments, fungi do not have eyes so they cannot see. Instead, they use electrical signals and secreted signaling molecules to communicate with the colony to orchestrate communication, and cell fusion to establish its hyphal network within the host.
All the while, its host is completely oblivious that an entity with a mind of its own, i.e., fungi have taken control of these biological processes.
Fungi use their hyphae to alternate roles as signal-sender and signal-receiver using signaling proteins. Researchers have found they act like a minuscule magnet within the cells in an oscillatory manner to the respective cytoplasmic membrane as it is interacting with the network hyphae.
Studies have shown that G-protein-coupled receptors (GPCRs) act as the signaling proteins which serve the fungi as transmembrane receptors to send signals from the external environment inside the cell.
They use G-protein signaling pathways for “sensing external ligands, which include nutrients, hormones, proteins, and peptides and especially pheromones, ions, hydrophobic surfaces, and light,” (Kochman, 2014).
This enables fungi to coordinate communication, metabolism, growth and sense nutrients for cell transport to create the perfect environment within the host while ensuring its survival, reproduction, and virulence means are constantly met (Van Dijck et al., 2017).
Extracellular signals regulate downstream pathways by activating G protein signaling and, thus, influence cellular behavior, environmental cues, and communication signals that bind to the GPCR. This process influences cellular growth, reproduction, metabolism, virulence, and stress responses.
One study found that once two fusion partners came into each other’s vicinity, their oscillation frequencies slowed down (entrainment phase) and transited into anti-phasic synchronization of the two cells’ oscillations.
The researchers suggested that single hyphae engage in a “monologue” that may be used for exploration of the environment and can dynamically shift their extra-cellular signaling systems into a “dialogue” to initiate hyphal fusion.
They discovered that the fungi’s hyphae constantly perform signal oscillations, comparable to a cellular “monologue” until they meet another hypha with which they then coordinate signal oscillations in a cell-to-cell dialog. They also showed how “signal oscillations are mechanistically interlinked with calcium-dependent growth oscillations.”
It appears that people who consistently operate within the range of low-frequency electrical oscillations attract these microbes like a magnet as if it is a type of autonomous kill switch that sends out signals in our environment for our own destruction.
“Incredibly, when it comes to learning, the neuron behaves like a giant antenna, with different branches of dendrites tuned to different frequencies for maximal learning.” – Mayank R. Mehta – UCLA Neurophysicist
A tracking beacon of sorts sending our frequencies so these fungi can find us and carry out our destruction no matter where we hide or go.
All the while, the host and the best medical professionals in the world remain clueless.
Hence, the point.
After all, how can we hide when for possibly millions of years they have already infected and altered the human operating system and when most of humanity has no knowledge of this ancient threat?
Some researchers claim these proteins should be called “the most successful structures evolved during the whole of animal evolution”. Meaning, that if you are looking for one of the secrets of life and biology, these scientists will point you to the study of fungi and the G protein signaling.
The process within and without our bodies and minds acts like a biological cable network connecting us all to the earth’s biosphere and to one another.
When I look at my own research over the years and my incessant quest for knowledge, I now realize I’m just a servant to something greater than myself.
Something much more ancient and intelligent that uses me to feed it the information and knowledge (light or glass) it demands daily. I’m just one of the tips of its hyphae that is part of a massive network spanning the globe.
This is what I contend may be the ultimate goal of the fungi hive mind.
A massive mycelium network that we will mimic as a hierarchical New World Order based on a One World Religion and Laws from the hive mind controlling the planet and biological strings of all life.
The Black Iron Prison of Philp K. Dick is in reality a global fungal network in which humans are entrapped within its web as hyphae that it uses to “see and expore the world to gather resources and spread the phosphporic light (heaven) or to become parasitic creatures (Dick’s Androids) of the dark chewing our own faces off (hell).”
A fact of our nature that we must admit there is no escape (mycelium web).
Only mutual cooperation (symbiosis) in a multipolar world (filaments) ensures our survival.
The Mold of Yancy by Phillip K. Dick is a science fiction story written in 1954 about mind control and subliminal messages, a cautionary tale of molding society. It later was adapted into his novel, The Penultimate Truth.
The story follows the life of Colony Callisto, a young woman who is the epitome of a model citizen of what looks like the perfect society that has emerged from the ashes of an off-Earth war on the planet, Jupiter. Her grandfather, John Edward Yancy, is the leader of the colony.
To the outside world, they live in what appears to be an idyllic society, but beneath the plastic façade lies a hidden world of secrets and deception.
It is a really totalitarian society that controls the populaces’ every thought and move through politics and the media.
Yancy, the colony’s leader, is a popular figure who uses his virtual persona to control all aspects of life for the colony’s inhabitants. ‘
Through broadcast shows and advertisements, Yancy dictates what the people of the colony should eat for breakfast, what music they should listen to, and even what political views they should hold.
The citizens seem to mold their thinking and behaviors exactly to whatever Yancy says, even though they seem to think their acting on their own accord.
He has the ability to speak on almost any subject by saying what people want to hear without really saying anything at all is what gives him power.
If Yancy delivered opinions on philosophy, art and culture, the plan would not work.
In this society, people are allowed to express their opinions freely without fear of repression. They enjoy life, reading, listening to music, and watching TV.
And even though they may complain about the government from time to time, they all ultimately subscribe to the same beliefs that Yancy gently suggests.
The result is a de-politicized, nonphilosophical and homogenized society of android like humans that follows Yancy’s every whim.
Analyst Peter Tavener works for the Niplan police, studying and creating reports on the political situation of Callisto.
He tells Police Director Kelleman that while Callisto they achieved a totalitarian society without an actual dictator, any elected Parliament has the potential to become totalitarian if they reach too deeply into people’s lives.
Tavener agrees to go undercover on Callisto, posing as one of their own who are increasingly looking alike.
Phillip K. Dick said that the Yancy character was roughly based on U.S. President Dwight D. Eisenhower.
Banal middle class culture has long been a source of inspiration for writers and filmmakers. In the 1950s, Dick saw this culture as a tool for conformity in the United States.
He used Eisenhower as an example of someone who was vapid and musing, yet still held immense power over the people through his broadcasts.
Of the story PKD had this to say:
“Obviously, Yancy is based on President Eisenhower. During his reign we all were worrying about the man-in-the-grey-flannel-suit problem; we feared that the entire country was turning into one person and a whole lot of clones. (Although in those days the word “clone” was unknown to us.)
I liked this story enough to use it as the basis for my novel THE PENULTIMATE TRUTH; in particular the part where everything the government tells you is a lie. I still like that part; I mean, I still believe it’s so.
Watergate, of course, bore the basic idea of this story out.”
Today, we can clearly see the hundreth-Yancy affect with political clones directing our thinking, as myself and others in the so-called middle class complain against many of these government policies, we still have to follow them and consume what is on the store shelves in order to survive.
Dick is correct in seeing the entry point of totalitarian conformity in consumerism.
While people may disagree on politics, they tend to find common ground when it comes to popular culture, which continues to move the population towards certain values.
Arguing against anti-intellectualism, it is often said that without intellectuals to question the status quo, fascism and other forms of totalitarianism can more easily take hold.
This is because intelligence and critical thinking are necessary to challenge authority and keep society free.
However, this argument presupposes that all opinions are equally valid, which is clearly not the case. Some opinions are simply better than others, and this is especially true when it comes to art, culture, and philosophy.
To be truly neutral on these matters would be impossible for anyone with a brain; one must either have an opinion or be dead inside or possibly a clone or android in Dick’s novels.
Thought and behavior control operating under the guise of social virtue is particularly invidious, easily capturing those of us suffering from the widespread malady of intellectual laziness.
The effort to mold a national way of thought can result only in a mouldering state of mind, a decay of initiative inviting totalitarianism to creep into every aspect of our lives.
I will leave you with Dwight D. Eiesenhower’s farewell speech to the colony, warning them about the danger of becoming captive to the military industrial complex and a technological elite.
The most famous quote from Eiesenhower came about halfway through the speech: “In the councils of government, we must guard against the acquisition of unwarranted influence, whether sought or unsought, by the military-industrial complex.”
