Hydrogen Peroxide IV Therapy

This page covers Hydrogen Peroxide IV Therapy. IV League specializes in Hydrogen Peroxide IV Therapy.

Intravenous hydrogen peroxide therapy is a therapeutic cancer treatment that has a significant number of loyal adherents. When hydrogen peroxide is brought into contact with blood, an enzyme called catalase causes it to disintegrate into water and large amounts of oxygen.

This happens when catalase reacts with hydrogen peroxide. Benefits will accrue to any region of the body that, for whatever reason, may have been oxygen-starved (for example, as a result of difficulties with the body’s circulatory system), as a result of this additional oxygen.

The oxygen that is released into the body is responsible for a wide variety of beneficial effects, some of which include the inhibition and/or killing of a variety of organisms within the body, including viruses, yeast, parasites, and bacteria.

It is generally agreed upon that hydrogen peroxide is one of the most astounding of all the natural remedies that are currently available. This is due to the numerous advantageous effects that may be brought about by using this substance.

The process of adding oxygen straightforwardly to the tissues of the body in the form of extremely reactive singlet oxygen, also known as lone oxygen atoms, is what constitutes the practice of bio-oxidative medicine which include hydrogen peroxide as well.

Hemoglobin, a protein that is located in red blood cells, is responsible for the transportation of oxygen (as O2) in living systems.

It is possible to ensure that oxygen does not interact with anything along its path from the lungs to the tissues of the body while yet achieving a very high level of efficiency by using this method.

Because it is bound by hemoglobin, it is unable to react to anything other than hemoglobin until the hemoglobin releases it. Until then, it cannot react to anything else (which then takes it up carbon dioxide and carries it to the lungs).

The practice of bio-oxidative medicine involves the administration of oxygen either in the form of hydrogen peroxide (H2O2) or ozone directly into the body (O3).

In spite of the fact that new research is currently being conducted in this country, the medical community in the United States continues to reject the idea that ozone can be used as a legitimate treatment option, despite the fact that this practice is commonplace in many other regions of the world, including Europe. To our good fortune, hydrogen peroxide is not handled in this manner, despite the fact that it is an equally effective method of oxidation.

Some of the many disorders treated with Hydrogen Peroxide include:

• Bacterial infections (including Lyme disease)
• Viral infection
• Epstein-Barr Virus
• Influenza
• Colds
• Sinus infections
• TIAs
• Various fungal infections
• Poor circulation
• Stroke
• COPD
• Chronic Bronchitis
• Angina
• Fibromyalgia

Hydrogen peroxide is also a moderate antiseptic that can be applied to the skin to treat small burns, cuts, and scrapes in order to avoid infection. One can also use it as a mouth rinse to assist clear mucus or to ease minor mouth discomfort (such as that caused by gingivitis or canker/cold sores).

When administered to the affected area, this product will work by releasing oxygen, ensuring that it accomplishes its purpose. Foaming results from the release of oxygen, which assists in the removal of dead skin and the cleaning of the area.

Benefits Of Hydrogen Peroxide IV Therapy

The general benefits of IV hydrogen peroxide are briefly described below:

Eliminates cells that are not healthy: It is possible for unhealthy cells to replicate and spread throughout the body, which can lead to many diseases and infections.

Combats infections caused by viruses: This includes the common cold, influenza, and any other common infections you may come into contact with over the year.

Boosts the immune system: If you take hydrogen peroxide regularly, your immune system will become more robust, and you will have a lower risk of becoming ill in the years to come.

Improves tissue oxygenation: If the tissues in your body receive an adequate amount of oxygen, you will be able to lead a healthy life and will have an easier time performing routine tasks such as working out.

Protects against microorganisms and parasites: The use of hydrogen peroxide therapy can make your body less susceptible to the infections that are being discussed.

Eliminates toxic waste and waste from living organisms: When your body is unable to clear toxins adequately, you will feel weak and sick for a significantly longer period of time.

Reduces buildup of plaque: Plaque deposits have been linked to a variety of health problems, including excessive cholesterol and heart disease.

Clears the lungs by dissolving mucus: Mucus can make it difficult to breathe, especially for people who already have respiratory conditions or allergies.

History of Hydrogen Peroxide IV

When it was first found in 1818 by Thénard, who gave it the name eau oxygénée, the history of H2O2 can be considered to have begun. Since the middle of the 1800s, hydrogen peroxide has been promoted for a broad variety of uses, some of which include non-polluting bleaching, an oxidizing agent, a disinfectant in the food processing industry, and even fuel for rockets.

In the year 1856, researchers discovered that H2O2 was present in biological systems. However, Wolffenstein did not succeed in isolating 100% pure H2O2 from H2O until the year 1894. This was accomplished by distilling H2O under vacuum.

Love documented the first use of hydrogen peroxide in medicine in 1888. He found that it was effective in treating a variety of illnesses, notably scarlet fever, diphtheria, nasal catarrh, acute coryza, whooping cough, asthma, hay fever, and tonsillitis.

Love made this discovery. In a similar vein, Oliver and his colleagues found that administering H2O2 by intravenous injection was an effective way to treat influenza pneumonia during the epidemic that followed World War I.

In spite of the fact that H2O2 had a number of favorable benefits, during the 1940s there was a slowdown in medical interest in additional research on H2O2 due to the rapid introduction of new prescription drugs. Urschel and later Finney and co-workers conducted several studies on myocardial ischaemia in the early 1960s.

These studies demonstrated a rescue afforded by H2O2, which suggested an essential preventative action of H2O2 against ischaemia-reperfusion (IR) damage. These studies were conducted on myocardial ischaemia. Urschel and later Finney and co-workers.

Notably, Farr is generally acknowledged to be the pioneer of what is now known as “oxidative therapy.” He did this by proposing the use of intravenous infusion of H2O2 to cure a wide array of illnesses. In later years, Wilhelm advocated for the use of H2O2 in treatment for a variety of conditions, including cancer, skin ailments, polio, and mental illnesses caused by bacteria.

He gave the definition of hydrogen peroxide as “God’s given immune system.” Grotz was another key figure in the H2O2 saga. He tried H2O2 as a treatment for the arthritic pain he was experiencing, and he found that it provided him with some relief.

What Are The Mechanisms of Action for Hydrogen Peroxide IV?

H2O2 is considered to be an endogenous oxidant in mammals due to its role in redox signalling and control. It is the most stable of the reactive oxygen species (ROS), and it is evidently involved in the control of the function of proteins. Furthermore, under certain conditions, it is also a precursor of the hydroxyl radical •OH and hypochlorous acid (HOCl).

H2O2 is reactive at micromolar quantities, and at large concentrations, it can cause harm to energy-transforming cell systems. For example, it can prevent the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase from functioning properly. In the Fenton reaction, soluble Fe(II) gives an electron to an H2O2 molecule, which causes the H2O2 molecule to break apart into hydroxyl radicals •OH + OH. These radicals react at diffusion rates and have the ability to randomly oxidise almost any organic molecule. Damage to DNA is the method of death caused by hydroxyl radicals.

Due to the fact that it is a by-product of oxidative stress in cells, H2O2 was thought to be an undesired and potentially detrimental product for metabolism until just a few decades ago. In its place, it has emerged in recent years as a crucial redox signaling molecule in a wide range of biological processes, such as cell proliferation and differentiation inflammation, tissue repair, circadian rhythm, and even the ageing process itself. H2O2 is frequently considered to be the most significant redox signal molecule. This is due to the fact that it is very stable, having a cellular half-life of around 10−3 seconds, that it is diffusible, and that it reacts selectively.

H2O2 is capable of performing the role of a signaling molecule as well as, on the other hand, causing oxidative damage to biomolecules (a condition known as oxidative stress). This ambivalence is determined by the context of the cell, the localized concentration of hydrogen peroxide, and the kinetics of its generation and removal. Under normal stable state, their production and removal are in equilibrium; however, under oxidative stress conditions, there is an excess generation of superoxide anion •O2 and, as a result, H2O2.

How Is Hydrogen Peroxide IV Therapy Used To Treat Inflammation?

Inflamed tissues are linked to high levels of hydrogen peroxide, and this mechanism plays a crucial part in the antimicrobial defenses provided by the host. During the inflammatory process, by-products of H2O2 react with proteins, lipids, nucleic acids, and other metabolites, which results in related molecular damage that can be severe and ultimately leads to the apoptosis of cells. Inflammation, which is primarily brought on by activated macrophages and microglia, is a factor that contributes to the development of some types of chronic disorders, such as Alzheimer’s disease.

The following is a plausible mechanism that describes the order of events that took place:

1. Hydrogen peroxide is created as a result of a response to a pro-inflammatory ligand, such as by NADPH oxidase; and
2. Hydrogen peroxide diffuses through cell membranes and enters adjacent target cells.

Inflammation results in the production of both H2O2 and TNF-α; however, because H2O2 has a limited capacity to activate NF- κB (the nuclear enhancer factor kappa light chain enhancer of activated B cells is a protein complex that governs DNA transcription), H2O2 instead up-modulates TNF-α, which in turn leads to the activation of NF- κB. Inflammation, innate and adaptive immunological responses to viral infection, cell proliferation, and apoptosis are all regulated by NF- κB, which plays a role in all of these processes. It is imperative that the existence of the H2O2 gradient be stringently managed at the enzymatic level in order to avoid severe tissue damage and sustained granulocyte recruitment and retention. Depolarization of the membrane, which is caused by the action of the oxidase enzyme, has the effect of inhibiting NADPH oxidase. The depletion of NADPH supplies brought on by continuous creation of H2O2 may, in and of itself, bring an end to the process of producing H2O2.

How Is Hydrogen Peroxide IV Used To Treat Plaque?

At Baylor University in the 1960s, researchers conducted studies that provided conclusive evidence that intra-arterial hydrogen peroxide can dissolve plaque in big arteries. In the treatment of vascular illness, EDTA has been found to clear small arteries and produce collateral circulation around big artery blockages. As a result of this, H2O2 is a perfect complement to EDTA and makes a superb addition to the treatment. The collective term for this approach is “Chelox Therapy.”

How Is Hydrogen Peroxide IV Used To Treat Brain Ischaemia?

Ischemia-reperfusion injury, often known as I/R injury, is one of the well-studied disorders related with reactive oxygen species (ROS), along with myocardial infarction, stroke, and other thrombotic events. After a period of ischemia, the process of reperfusion takes place when blood circulation is regained to the affected tissues. However, the return of circulation after an absence of nutrients and oxygen causes inflammation, and the oxidative stress that results in further damage to the affected tissues. In an attempt to understand the relationship between H2O2 and I/R injury, its expedited production in postischemic tissues was witnessed to be caused by enzymes worthy of reducing molecular oxygen to superoxide anions, which resulted in the release of H2O2 into the extracellular and intracellular space. This information was gleaned from observations made in the course of a study in which the authors attempted to figure out what links between H2O2 and I/R injury. The synthesis of superoxide anions, which have larger levels than the nitric oxide radical NO, was favoured after reperfusion of ischemic tissue. As a result, endothelial cells create more superoxide anion molecules, and production of NO by endothelial NO synthase eNOS diminishes.

Intravenous IV Hydrogen Peroxide vs. Oral Supplementation

It should be kept in mind before starting IV Hydrogen peroxide therapy that the quantity and frequency of the dose should be consulted with the doctor.

Intravenous: The intravenous administration of hydrogen peroxide is an effective treatment for bacterial infections as well as a wide variety of acute and chronic viral illnesses. It also has the potential to be effective for the treatment of other illnesses, such as arthritis and hypertension. The intravenous therapy, which consists of hydrogen peroxide at a concentration of 3% in 500 cc five percent glucose in water as a carrier solution and takes around 90 minutes to give, is typically employed. 2 grams of magnesium chloride are added additionally with a small quantity of manganese to avert vein sclerosis.

In some cases, bacterial infections could be treated with hydrogen peroxide administered intravenously, which would negate the need for pharmaceutical-grade antibiotics. Antibiotics are recognized to effectively cure infections that occur within the body; yet, it is common knowledge that they can inflict damage on other systems while doing so. As the illness is treated with antibiotics, certain people may develop stomach issues or perhaps even yeast infections as a result of the “good” bacteria being eliminated along with the infection.

Whenever there is an infection in the body, the body will manufacture its very own version of hydrogen peroxide. Because it is composed of oxygen, hydrogen peroxide has the power to eradicate pathogens that are incapable of surviving in an atmosphere with a high level of oxygen. The immune system receives a boost from the hydrogen peroxide as it travels through the circulation and into the tissues of the body. This allows the body to better fight off infections.

Oral: Therapies involving hydrogen peroxide taken orally have the potential to produce severe nausea. When H2O2 is taken by mouth, it causes the production of free radicals in the stomach, and these free radicals should be avoided at all costs. In the presence of iron and ascorbate, certain combinations of fatty acids that are likely to be found in the stomach, along with the free radicals hydroxyl and superoxide, have the potential to diminish hydrogen peroxide. The gastric and duodonal mucosa may be negatively impacted as a result of these, which may lead to a rise in glandular stomach erosion, duodonal hyperplasia (an abnormal increase in the number of cells), adenoma, and cancer.

Molecular Structure of Hydrogen Peroxide IV

Hydrogen Peroxide is an inorganic peroxide containing two hydroxy groups (O-H) combined together by a covalent oxygen-oxygen (O-O) single bond. There are four lone pairs and three bound pairs. Its molecular weight is 34.015 and its molecular formula is H2O2.