MMS / CDS OPERATION

 

The therapeutic effects of chlorine dioxide are attributed to its pH selectivity. This means that when chlorine dioxide comes into contact with an acid, it dissociates and releases oxygen. This oxygen release, along with the conversion of chlorine dioxide into sodium chloride (common salt), leads to the oxidation or "burning" of harmful pathogens with acidic pH, effectively transforming them into alkaline byproducts. Similar to how red blood cells release oxygen in response to acidity (known as the Bohr effect), chlorine dioxide also releases oxygen in an acidic environment, such as the presence of lactic acid or the acidic nature of pathogens.

One of the therapeutic benefits of chlorine dioxide is its ability to create an alkaline environment, which aids in the recovery from various diseases. Additionally, it eliminates small acidic pathogens through oxidation, following the criteria set by Andreas Kalcker. This oxidation process generates an electromagnetic overload that is impossible for unicellular organisms to dissipate. However, multicellular tissue, with its larger size, can better handle this charge and is not affected in the same manner. Biochemistry explains that cellular protection is achieved through glutathione in cells.

The use of chlorine dioxide for therapeutic purposes has several advantages. Firstly, chlorine dioxide is the second strongest disinfectant known, surpassed only by ozone. However, chlorine dioxide surpasses ozone in suitability for therapeutic use because it can penetrate and eliminate biofilms, which ozone cannot do. Furthermore, bacterial resistance to chlorine dioxide is impossible. While ozone is stronger in terms of its antiseptic properties, its high oxidative potential (2.07) and short half-life (only 15 minutes at 25 °C and pH 7.0) make it less effective for in vivo therapeutic applications.

 

Chlorine dioxide exhibits selective oxidizing properties, distinguishing it from other substances, as it does not readily react with the majority of constituents found in living tissue. However, when it encounters phenols and tyroles, which are crucial for bacterial survival, chlorine dioxide reacts swiftly. In the case of phenols, it engages in a mechanism that involves attacking the benzene ring, effectively eliminating unpleasant odors, tastes, and other intermediary compounds. 

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1. Chlorine dioxide, a yellow gas, readily dissolves in water while maintaining its structure.
2. The synthesis of chlorine dioxide involves combining sodium chlorite with diluted hydrochloric acid.
3. When chlorine dioxide gas is dissolved in water, it acts as an oxidant.
4 .Chlorine dioxide exhibits pH selectivity, with a stronger reaction observed in more acidic environments.
5. Toxicological studies conducted by the EPA (US Environmental Protection Agency) indicate that chlorine dioxide does not leave residues or accumulate in the body over the long term.
6. During the oxidation process, chlorine dioxide is transformed into oxygen and sodium chloride

(common salt).
7. Due to its dual nature as an oxidizing agent and a free radical, chlorine dioxide has the ability to neutralize reactive molecules like NO, O2-, H2O2, HClO, and OH. These molecules, which lack oxygen, are produced by  macrophages in response to stress or infection, causing inflammation and pain. Chlorine dioxid is particularly suitable for wound disinfection as it does not impede tissue reconnection, making it more preferable than iodine.

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