Colloids are held in suspension via a very slight negative electrical charge on the surface of each particle. Like charges repel each other. This charge is called zeta potential. Blood is a colloidal solution, and all blood cells have a slight negative charge.
Zeta potential is a measure of the electrical force that exists between atoms, molecules, particles, and cells ina fluid. Zeta potential's strength determines the amount of material (nutrients, wastes) that fluids such as your blood and lymph can carry. Increasing the electrical force in the solution allows the fluid to dissolve and hold more material. In this way, more nutrients can be carried throughout your body and accumulated deposits of waste can be removed. When the zeta potential is too low, blood begins to coagulate. This is a condition known as intravascular coagulation. Blood becomes a sludge that is increasingly difficult for the heart to pump, and decreasingly effective at performing the usual functions of blood. "Blood sludge" is widespread in the population (more than half the population will die from heart problems). Intravascular coagulation is clearly visible in the blood vessels of the eye when viewed under relatively low level (60x) magnification. Blood is in constant motion at constant temperature and the pH of blood is fixed at 7.35 to 7.4, but its concentration of electrolytes is not fixed, and the electrolytes directly affect the zeta potential. "So long as the Zeta Potential (ZP) of the system remains constant, the fluidity (viscosity) of the system will also remain constant. But if the ZP of the system is progressively lowered by the introduction of cationic electrolytes or polyelectrolytes, then the stability of the system will undergo progressive changes — from simple agglomeration to fluid gel formation — and finally to a rigid gel."- Thomas M. Riddick.
One lab found that best results in reducing intravascular coagulation were obtained by drinking 8 glasses per day of water with a mix of potassium citrate and potassium bicarbonate added sufficient to raise the pH of the water to 8.0 to 8.4. The minerals MUST be taken with the water in order to be effective, because intravascular coagulation is also related to insufficient water intake. Potassium works better than sodium to reduce intravascular coagulation, in fact too much sodium in the diet is part of the problem. The lab recommends that everyone replace table salt with a mixture of 60% potassium chloride and 40% sodium chloride to better reflect the potassium/sodium balance found in foods. Forty to fifty percent of the people examined by this lab had significant blood coagulation. To increase your zeta potential you must avoid aluminum. Aluminum is used in water treatment plants to cause materials to settle out of solution. It does this by reducing the zeta potential. In your body aluminum does the same thing, causing coagulation of your blood, and deposits and plaques in your arteries, brain and throughout your body. Aluminum is found in municipally treated water, cooking utensils, vaccinations, non-clumping salt and baking powder, antiperspirants, antacids, drugs (read the label carefully), soft drinks and other canned goods where the plastic liner has cracked during sealing, and in other unexpected places. Consumption of alcohol produces intravascular coagulation. Editor's note: Alcohol also hardens the brain.The brain is a jelly, like raw egg white. To study the brain under a microscope, scientists must harden it and then they can slice it, stain it and view the slices. To harden the brain they use alcohol. As we saw in the quote from Thomas M. Riddick above, a rigid gel results from loss of zeta potential. Physicians use EDTA chelation therapy to increase zeta potential and remove toxic heavy metals from the body. The increased zeta potential allows toxic deposits in the body to re-enter solution so that they can be removed by the kidneys, liver, and in the sweat, etc. A study in Switzerland found that people who had chelation therapy to remove lead from their body also had less cancer in later years.
Xanya Sofra Weiss
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