Health disruption, the real Boogie man – Part 1

Exploring the Potential Disruption of NAD Coenzyme by Electromagnetic Frequencies (EMFs)

The coenzyme nicotinamide adenine dinucleotide (NAD) plays a critical role in biological development. It sets the stage for essential upstream reactions. However, emerging research suggests that electromagnetic frequencies (EMFs), including radio frequencies, may significantly disrupt the biochemical processes involving NAD. This article explores the foundational concepts of chemical disruption, the influence of EMFs and radio frequencies on NAD’s electrochemical potential, and the importance of reliable sources when examining this topic.

What is Nicotinamide adenine dinucleotide (NAD)?

As you know, Nicotinamide adenine dinucleotide (NAD) is a coenzyme that has an important role in various biological processes. As a keynote, particularly in cellular energy metabolism. It is derived from vitamin B3, known as nicotinamide adenine dinucleotide (NAD+).

NAD exists in two forms, namely NAD+ (oxidized form) and NADH (reduced condition). NAD+ functions as an electron carrier, accepting electrons during metabolic reactions. While NADH carries those electrons to the electron transport chain in cellular respiration.

NAD+ is a crucial component in several enzymatic reactions. These include the breakdown of carbohydrates, fats, and proteins to generate energy. It acts as a cofactor for enzymes like dehydrogenases, which remove hydrogen atoms from molecules during metabolic reactions. NAD+ accepts those hydrogen atoms and is reduced to NADH in the process.

The NADH produced during cellular respiration then donates its electrons to the electron transport chain. Next, it leads to the synthesis of adenosine triphosphate (ATP), the cell’s primary energy currency.

In addition, NAD+ is involved in other essential cellular processes. It serves as a substrate for enzymes called sirtuins. It plays a role in gene regulation, DNA repair, and cell survival. NAD+ is required to activate sirtuins, and this interaction is believed to influence aging and longevity.

Furthermore, NAD+ participates in redox reactions throughout the body which acts as a cofactor in various enzymes involved in detoxification processes, antioxidant defense, and maintenance of cellular redox balance.

Research has depicted that NAD+ levels can decline with age and in certain disease conditions. This decline has been associated with impaired cellular function and increased age-related diseases. There has been growing interest in NAD+ supplementation and its potential advantages for health and longevity.


Exploring the Potential Disruption of NAD

Chemical Disruption and the Role of NAD

As you know, NAD, in its oxidized form (NAD+) and reduced form (NADH), plays a crucial role in cellular energy metabolism, including various enzymatic reactions.

NAD+ is involved in a wide range of biochemical reactions. These include glycolysis, the citric acid cycle, and oxidative phosphorylation. In glycolysis, NAD+ acts as a coenzyme for enzymes such as glyceraldehyde-3-phosphate dehydrogenase. It facilitates the oxidation of glyceraldehyde-3-phosphate to 1,3-bisphosphoglycerate and generates NADH.

NAD+ is a coenzyme for several dehydrogenase enzymes in the citric acid cycle. These include isocitrate dehydrogenase and alpha-ketoglutarate dehydrogenase. These enzymes catalyze reactions that direct the production of NADH. Also, it subsequently participates in the electron transport chain.

During oxidative phosphorylation, NADH donates its electrons to the electron transport chain, composed of a series of protein complexes embedded in the mitochondrial inner membrane. This transfer of electrons ultimately leads to the epoch of a proton gradient across the membrane, which drives ATP synthesis.

Moreover, NAD+ also participates in redox reactions throughout the body which serves as a coenzyme for enzymes involved in detoxification processes and maintenance of cellular redox balance. Disruption in NAD+ availability or function can interfere with these crucial cellular processes. This fact further highlights the importance of maintaining NAD+ homeostasis.

Understanding the potential disruption of NAD by external factors, such as electromagnetic frequencies (EMFs) and radio frequencies, is an area of ongoing research. Investigating the influence of these fields on NAD metabolism and its associated enzymatic reactions can provide insights into their potential impact on cellular processes, energy metabolism, and overall homeostasis.

Interaction of EMFs and Radio Frequencies

The potential effects of electromagnetic fields (EMFs), including radio frequencies, on biological systems have been a subject of scientific investigation. Optronics, a sub-field of photonics, focuses on using electronic devices and systems that detect and control light. While optronics primarily operates within the visible light spectrum, it also involves the utilization of radio frequencies outside the visible range.

EMFs, including radio frequencies, are considered non-ionizing radiation. It means they do not have sufficient energy to ionize atoms or molecules in biological systems directly. However, research suggests that non-ionizing radiation can still interact with biological systems, potentially influencing biochemical processes.


Studies have examined the potential effects of radio frequencies on various aspects of cellular physiology, including NAD-dependent reactions. While the specific mechanisms through which EMFs and radio frequencies may impact NAD metabolism are not yet fully understood, several hypotheses have been proposed.

One hypothesis is that EMFs can influence the activity of enzymes involved in NAD metabolism by altering their conformation or catalytic properties. For example, certain studies have suggested that radio frequency exposure might affect the activity of NAD+-dependent enzymes, leading to potential disruptions in cellular energy metabolism and redox balance.

Another proposed mechanism is the modulation of cellular signaling pathways. It is hypothesized that EMFs and radio frequencies could interfere with intracellular signaling cascades, including those that regulate NAD metabolism. This disruption in signaling pathways may subsequently impact the balance between NAD+ and NADH and potentially affect cellular processes dependent on NAD coenzyme activities.

Furthermore, oxidative stress has been implicated as a potential mediator of the biological effects of EMFs and radio frequencies. Oxidative stress occurs in situations, namely, during an imbalance between the exhibit of reactive oxygen species (ROS) and the cellular antioxidant defense system. Some studies suggest that exposure to EMFs and radio frequencies may increase ROS production, potentially leading to oxidative damage and affecting NAD-dependent processes.

It is important to note that the research investigating the effects of EMFs and radio frequencies on NAD metabolism is complex and evolving. The scientific consensus on the precise mechanisms and potential health implications is still being explored. Further studies are needed to understand these interactions better.

Sound Waves and Cellular Disruption

While the focus of research on biological effects often centers around electromagnetic fields, sound waves can also potentially contribute to cellular disruption. The area of cymatics, which explores the study of sound wave patterns and their effects on matter, provides insights into the impact of sound on cellular processes.

Studies in cymatics have shown that sub-sonic sound waves, below the audible range for humans, can harm cell genesis and development. These low-frequency sound waves can potentially interfere with the delicate processes involved in cellular reproduction and differentiation.

Cell nucleation, the formation of new cells, is a sensitive process influenced by various factors, including electromagnetic resonance. Cells also respond to electromagnetic fields in their immediate surroundings and interact with the Earth’s toroidal field. The planet’s magnetic field generates them. The interplay between these electromagnetic influences and cellular processes is essential for proper cell development and homeostasis.


Disruptions or imbalances in these electromagnetic influences can lead to divergent cellular behaviors and may contribute to adverse health effects, including carcinogenesis. While the precise mechanisms through which sound waves affect cellular processes still need to be fully understood. Research in cymatics provides valuable insights into the potential impact of sound on cellular development.

It is important to note that cymatics is still an area of ongoing research and the specific effects of sound waves on cellular processes. These conclude that NAD-dependent reactions require further investigation. The intricate interplay between sound waves, electromagnetic influences, and cellular behavior represents a complex area requiring rigorous scientific inquiry to comprehensively understand their potential implications on biological systems.

Examining the Impact on NAD Coenzyme

The disruption caused by EMFs and radio frequencies on NAD warrants further investigation. Researchers have explored potential interactions between these fields and NAD-dependent reactions, which can influence cellular signaling, gene expression, and oxidative stress. Understanding the mechanisms through which EMFs impact NAD metabolism can shed light on the potential health implications.


An active research area is the potential disruption of NAD, a critical coenzyme involved in numerous biological processes, by EMFs and radio frequencies. Exploring the intricate relationship between these fields and NAD metabolism can provide valuable insights into the potential effects on cellular processes and overall homeostasis. However, it is crucial to approach this subject with scientific rigor, relying on credible sources to separate factual information from misleading narratives being propagated by corporations with conflicts of interest and their lobbyists.

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