Chlorine Dioxide Used To Clean Cooling Towers of Biofilms:
I present the use of chlorine dioxide to clean cooling towers as an indication of what it might do to clean up plaque from blood vessel walls. (My wife did not like this analogy, but I do.) It does the same for cleaning pipes, so will it do the same for the thousands of miles of pipes in our vascular system?
Biofilm Control: Regular dosing of ClO2 helps to prevent and remove biofilm formation on heat exchange surfaces and within the entire cooling system. By disrupting biofilm, ClO2 improves heat transfer efficiency and reduces the risk of Legionella contamination.
Scaling Prevention: ClO2 aids in controlling the precipitation of scale-forming minerals. This not only enhances heat transfer efficiency but also prolongs the lifespan of the cooling equipment by reducing the frequency of descaling operations.
Corrosion Mitigation: By controlling microbial growth and maintaining water chemistry, ClO2 helps to reduce the corrosive effects on metal components. This leads to fewer leaks and structural issues, lowering maintenance costs and extending the life of the cooling tower.
Benefits of Using Chlorine Dioxide in Cooling Towers
Improved Efficiency: By effectively managing biofilm, scale, and corrosion, ClO2 enhances the overall efficiency of cooling towers, leading to better heat dissipation and energy savings.
Cost Savings: The use of ClO2 reduces the need for frequent maintenance and repair, resulting in significant cost savings over time.
Compliance and Safety: ClO2 treatment helps cooling towers meet health and safety regulations by reducing the risk of Legionella and other microbial hazards.
The association of bacteria with atherosclerosis has been only superficially studied, with little attention focused on the potential of bacteria to form biofilms within arterial plaques. Atherosclerotic carotid artery explants from 15 patients were all shown to test positive for the presence of biofilm deposits. 6 of the 15 plaques analyzed showed 16S rRNA genes from Pseudomonas aeruginosa biofilms.
Chlorine dioxide reduces plaque and gingival indices and bacterial counts in the oral cavity, so it should be the same in the blood vessels. Chlorine dioxide is renowned by dentists for its ability to penetrate, remove and prevent biofilm (plaque) easily. Plaque is the starting point of common dental issues like gingivitis, the earliest stage of gum disease. With 75% of adults displaying signs of gingivitis, using a mouthwash with stabilized chlorine dioxide is a simple way to keep plaque and tartar buildup under control, with everyone knowing that periodontal disease is a precursor to heart disease.
Chlorine Dioxide is a game-changer for cooling tower maintenance, offering a comprehensive solution to biofilm, scaling, and corrosion challenges. Chlorine dioxide is a miracle molecule that multitasks in your body, healing, repairing, and balancing. It is one of several miracle molecules you will meet in Natural Cardiology.
More Testimonies:
Edgar Quispe Salas:
“I read and see all kinds of cases cured with the CDS, and I am very happy to see my wife who was on the verge of death with incurable diseases such as heart ischemia as her coronary artery was obstructed and there was nothing to do after two heart catheter procedures and many medications. She also had diabetes, hypertension, hypothyroidism, knee osteoarthritis, and allergies, for which she had to take 14 to 18 pills. Thanks to the CDS, after two years of treatment, she is healthy and does not take any medication, only her blessed CDS.” (Translated from Spanish)
Fabrizio
(Translated from Italian) “My mother, 85 years old, had undergone angioplasty on one leg seven months ago due to severe arterial disease, which had caused necroses on her foot. Her condition had improved, but a small necrosis remained, which did not heal, and the foot was still swollen and burning. She had continued to take anticoagulants and painkillers, and her energy had decreased significantly. A month ago, I started doing protocol C, starting with 5 ml per liter of water, but this dosage made her feel nauseous; then, I dropped to 2 ml per liter for about one week. Then I gradually increased it, and at the moment, she takes 7 ml in a liter of water.”
“At the same time, I started spraying the necrosis with pure CDS, followed by about five drops of DMSO with a bit of water and CDS again, this 4 or 5 times a day. Now, the necrosis has closed, and her foot almost no longer burns. A few days ago, I started giving her half a teaspoon of magnesium chloride dissolved in water with three drops of 70% DMSO in the morning as soon as she got up. Now Mum has more energy, and I can only thank the CDS.”
Key Advantages of Sublingual Absorption
Sublingual absorption refers to administering drugs under the tongue, allowing them to dissolve and enter the bloodstream directly through the mucous membranes. This method offers several advantages over traditional oral administration. I am finding it relatively easy making it easier to incorporate a complete protocol of other agents.
Rapid Onset of Action:
Drugs absorbed sublingually can enter systemic circulation quickly, providing faster therapeutic effects. This is particularly beneficial in emergency situations, such as administering nitroglycerin for angina.
Avoidance of First-Pass Metabolism:
Sublingual administration bypasses the gastrointestinal tract and liver, avoiding first-pass metabolism, where a significant portion of the drug may be metabolized before reaching systemic circulation. This can enhance bioavailability and effectiveness.
Ease of Use:
Sublingual medications can be easier to administer for patients who have difficulty swallowing pills or for those requiring rapid relief from symptoms.
Chlorine Dioxide and Clots
Chlorine dioxide works on the central damaging aspect of COVID-19 vaccines: coagulation in the blood. “Normally doctors prescribe an anticoagulant, such as warfarin, which is a substance equal to rat poison, which, in the long term, will cause strokes, etc. So it’s not a solution at all. However, chlorine dioxide is a solution because we have seen that it directly dissolves mini clots before they get bigger,” says Dr. Andreas Kalcker.
“Oxygen deprivation is the cause of death for most COVID-19 victims. Chlorine dioxide floods the blood with oxygen, immediately enriching the hemoglobin molecules on red blood cells and allowing patients to breathe again,” continued Kalcker.
Blood clots have emerged as the common factor unifying many of the symptoms of COVID-19. Researchers in Germany have discovered that the virus changes the size and stiffness of red and white blood cells in the human body. Moreover, these changes can last for months, possibly explaining the seemingly never-ending symptoms of COVID-19.
In December of 2021, Astra Zeneca scientists finally admitted that their vaccine was causing deadly blood clots. A Utah mother blames COVID-19 vaccines after her 17-year-old son and her husband were hospitalized with rare blood clots soon after receiving the shots. “So it is true after all. After nearly one year of stonewalling and denials, they officially admit that the COVID vaccines can cause blood clots,” writes Vasko Kohlmayer.
Patients hospitalized with severe COVID-19 infections who have high levels of the blood-clotting protein factor V are at elevated risk for serious injury from blood clots such as deep vein thrombosis or pulmonary embolism, according to a study by Harvard Medical School.
“On the other hand, critically ill patients with COVID-19 and low levels of factor V appear to be at increased risk for death from a form of coagulopathy that resembles disseminated intravascular coagulation (DIC)—a devastating, often fatal abnormality in which blood clots form in small vessels throughout the body, leading to exhaustion of clotting factors and proteins that control coagulation,” continues the medical scientists at Harvard.
Notably, many sick and dying have red blood cells clumping together and are not moving freely. Severely clumped red blood cells (Rouleau) affect proper oxygenation because the red blood cells do not circulate well enough to deliver oxygen where it is needed. Early in the pandemic, New York physicians noted that it seemed COVID patients had been transported to 30,000 feet in altitude and were starving for oxygen. After taking chlorine dioxide, the red blood cells regain proper size and shape and move freely through the blood.
A Dutch study published April 10 in the journal Thrombosis
Research found 38 percent of 184 COVID-19 patients
in an intensive care unit had blood that clotted abnormally
Many sick and dying have red blood cells clumping together and are not moving freely. Severely clumped red blood cells (Rouleau) affect proper oxygenation because the red blood cells do not circulate well enough to deliver oxygen where it is needed. Early in the pandemic, New York physicians noted that it seemed COVID patients had been transported to 30,000 feet in altitude and were starving for oxygen. This video shows that the red blood cells regain proper size and shape after taking chlorine dioxide and move freely through the blood.
Chlorine dioxide does not thin the blood as a blood thinner like Coumadin would. It simply allows a more unrestricted flow of hemoglobin cells around one another. It reduces the Rouleaux effect. It does not impact the patient’s ability to create blood clots normally.
When blood is abundant, nourished, and well-connected, we feel alive and nourished. Red blood cells must demonstrate healthy separation. Blood does more than run through our veins and oxygenate cells. It ensures we have nourishment and moisture for the entire body. Blood keeps our tendons, skin, and hair healthy, strong, and flexible. It lubricates joints and allows for smooth movement. Blood nourishes the mind and is considered the material basis for mental activity. Vital blood ensures good sleep and helps us wake feeling rested.
Red blood cells (RBCs) exhibit unique deformability, which enables them to change shape reversibly in response to an external force. The deformability of RBCs allows them to flow in microvessels while transporting oxygen and carbon dioxide.
Poor blood viscosity, RBC aggregation, and poor rheology, either independently or collectively, are linked to cardiovascular diseases. For example, Neumann et al. claim that “Plasma viscosity and erythrocyte aggregation were more predictive of myocardial infarction (heart attack) than age, male gender, fibrinogen concentration, abnormal ECG readings, or coronary score.” Another study confirms that high blood viscosity has been associated with cardiovascular-related diseases such as stroke, heart attacks, and deep vein thrombosis.
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