Zeta Potential
Zeta Potential is the electric charge between solids in the blood. The higher the potential, the more powerfully the blood particles remain discrete, or separate, and the more easily the blood can flow (especially in the capillaries where clumped or agglutinated blood prevents adequate flow.)
The simplest and most effect way to increase Zeta Potential (and the flowability and "discreteness" of the blood), used by Riddick, is to take potassium citrate. The simplest way to do this is to place 1.5 grams of potassium citrate in 1.5 liters of water and drink throughout the day. (NOTE: be careful of taking any form of vitamin citrate as this may negatively effect copper balance.) The only preferred citrate comes in the form of natural lemon water. The regulated drinking of lemon water, as used in the Carey Reams program, also increases Zeta Potential. In addition, lemon water supports the liver and usually decreases blood-sugar levels. (So, if your blood-sugar levels are high you may take lemon water without adding any sweeteners; if your blood-sugar levels are low, take lemon water with some sweetener, possibly blackstrap molasses.)
Papers about Zeta Potential
http://www.biomedx.com/zeta/index.html
http://customers.hbci.com/~wenonah/riddick/chap22.htm
http://customers.hbci.com/~wenonah/new/mcdaniel.htm
(Technical Discussion -- Please skip unless you are really interested)
(DO NOT TAKE ANY FORM OF CITRATE WITHOUT EXPERT GUIDANCE)
Working with a Stock Solution (based on the work of Thomas Riddick):
Add 50 grams reagent to 1 liter of water
Reagent:
47 grams - potassium citrate
2 grams - sodium citrate
1 gram - sodium chloride
9.5 grams - potassium bicarbonate
.5 grams - sodium bicarbonate
Add 20 ml of stock solution to 1 liter water = 1 gram electrolytes /liter
Drink 1.5 liters/day = 1.5 grams of electrolytes / day
We find so far that of the five reagents —and the possible combinations —50 gpl of straight potassium citrate is the most effective. We add 10 grams of potassium (or sodium) bicarbonate to all Stock Solutions, regardless of formulation. This raises the pH of the Standard Solution to 8.0–8.4. We consider it highly essential to maintain the pH of water somewhat above the normal pH of blood (7.4.) This ten grams of bicarbonate is employed solely for pH control, and is in addition to the 50 grams of dispersants.
The optimum dosage range of 750 to 1,250 ppm (of a 1:3 electrolyte) agrees with one's expectations, based on overall findings.
Potassium compounds are more effective than sodium compounds in relieving PVC and IVC.
The 1:3 electrolytes [which includes potassium citrate] are considerably more effective than the 1:2. This, of course, agrees with all basic concepts of Zeta Potential.
As a generalization, a dosage of 20 ml/liter approximates optimum concentration. We usually bring up the dosage slowly: 15, 17.5, 20, 22.5 and 25 gpl of "Stock Solution" per liter of distilled water, being guided by the Sclerascope and ECG.
It should be stressed that none of our reagents could be employed in "capsule" form, because without the accompanying water, they would actually increase the "salting out" effect, and the degree of IVC. An absolute minimum of one liter (4 glasses) is required. One and one–half liters (6 glasses) is often preferable. It should be spaced throughout a 12 to 16 hour day.
Without doubt, the real answer to cardiovascular disease is to cease the practice of "salting out" the human blood system, and eliminate all ingestion of 3:1 electrolytes [which includes aluminum, found in aluminum products and in vaccinations, which is often deadly or crippling when administered to children]. Despite the fact that the basic chemical principles involved were common knowledge to Schulze and Hardy over 90 years ago, the FDA still does not have the slightest concept of them.
We have noted no untoward side effects from the daily ingestion of 1.5 grams of the reagents listed above. Any of the electrolytes taken internally at a dosage of 10 to 20 grams would have a pronounced laxative effect. In fact, magnesium citrate is widely employed as a laxative. At 1.0 gram per liter, one cannot detect any taste of the reagent in distilled water.
It is obvious that with a normal daily input of mineral solids equivalent to say 18 grams of NaCl, the daily ingestion of 1.5 grams of electrolytes in the formula water actually increases mineral input by 9%. This increased load should naturally be held to a minimum. By nature, anionic surfactants reach a peak of dispersion. But if the dosage is increased thereafter, the degree of dispersion is lessened. Therefore, one works between two sets of opposing forces: the necessity for adding sufficient reagent to obtain maximum dispersion, but not to a point where it would begin to "salt out" the system. The optimum dosage range of 750 to 1,250 ppm (of a 1:3 electrolyte) agrees with one's expectations, based on overall findings.
Zeta Potential is the electric charge between solids in the blood. The higher the potential, the more powerfully the blood particles remain discrete, or separate, and the more easily the blood can flow (especially in the capillaries where clumped or agglutinated blood prevents adequate flow.)
The simplest and most effect way to increase Zeta Potential (and the flowability and "discreteness" of the blood), used by Riddick, is to take potassium citrate. The simplest way to do this is to place 1.5 grams of potassium citrate in 1.5 liters of water and drink throughout the day. (NOTE: be careful of taking any form of vitamin citrate as this may negatively effect copper balance.) The only preferred citrate comes in the form of natural lemon water. The regulated drinking of lemon water, as used in the Carey Reams program, also increases Zeta Potential. In addition, lemon water supports the liver and usually decreases blood-sugar levels. (So, if your blood-sugar levels are high you may take lemon water without adding any sweeteners; if your blood-sugar levels are low, take lemon water with some sweetener, possibly blackstrap molasses.)
Papers about Zeta Potential
http://www.biomedx.com/zeta/index.html
http://customers.hbci.com/~wenonah/riddick/chap22.htm
http://customers.hbci.com/~wenonah/new/mcdaniel.htm
(Technical Discussion -- Please skip unless you are really interested)
(DO NOT TAKE ANY FORM OF CITRATE WITHOUT EXPERT GUIDANCE)
Working with a Stock Solution (based on the work of Thomas Riddick):
Add 50 grams reagent to 1 liter of water
Reagent:
47 grams - potassium citrate
2 grams - sodium citrate
1 gram - sodium chloride
9.5 grams - potassium bicarbonate
.5 grams - sodium bicarbonate
Add 20 ml of stock solution to 1 liter water = 1 gram electrolytes /liter
Drink 1.5 liters/day = 1.5 grams of electrolytes / day
We find so far that of the five reagents —and the possible combinations —50 gpl of straight potassium citrate is the most effective. We add 10 grams of potassium (or sodium) bicarbonate to all Stock Solutions, regardless of formulation. This raises the pH of the Standard Solution to 8.0–8.4. We consider it highly essential to maintain the pH of water somewhat above the normal pH of blood (7.4.) This ten grams of bicarbonate is employed solely for pH control, and is in addition to the 50 grams of dispersants.
The optimum dosage range of 750 to 1,250 ppm (of a 1:3 electrolyte) agrees with one's expectations, based on overall findings.
Potassium compounds are more effective than sodium compounds in relieving PVC and IVC.
The 1:3 electrolytes [which includes potassium citrate] are considerably more effective than the 1:2. This, of course, agrees with all basic concepts of Zeta Potential.
As a generalization, a dosage of 20 ml/liter approximates optimum concentration. We usually bring up the dosage slowly: 15, 17.5, 20, 22.5 and 25 gpl of "Stock Solution" per liter of distilled water, being guided by the Sclerascope and ECG.
It should be stressed that none of our reagents could be employed in "capsule" form, because without the accompanying water, they would actually increase the "salting out" effect, and the degree of IVC. An absolute minimum of one liter (4 glasses) is required. One and one–half liters (6 glasses) is often preferable. It should be spaced throughout a 12 to 16 hour day.
Without doubt, the real answer to cardiovascular disease is to cease the practice of "salting out" the human blood system, and eliminate all ingestion of 3:1 electrolytes [which includes aluminum, found in aluminum products and in vaccinations, which is often deadly or crippling when administered to children]. Despite the fact that the basic chemical principles involved were common knowledge to Schulze and Hardy over 90 years ago, the FDA still does not have the slightest concept of them.
We have noted no untoward side effects from the daily ingestion of 1.5 grams of the reagents listed above. Any of the electrolytes taken internally at a dosage of 10 to 20 grams would have a pronounced laxative effect. In fact, magnesium citrate is widely employed as a laxative. At 1.0 gram per liter, one cannot detect any taste of the reagent in distilled water.
It is obvious that with a normal daily input of mineral solids equivalent to say 18 grams of NaCl, the daily ingestion of 1.5 grams of electrolytes in the formula water actually increases mineral input by 9%. This increased load should naturally be held to a minimum. By nature, anionic surfactants reach a peak of dispersion. But if the dosage is increased thereafter, the degree of dispersion is lessened. Therefore, one works between two sets of opposing forces: the necessity for adding sufficient reagent to obtain maximum dispersion, but not to a point where it would begin to "salt out" the system. The optimum dosage range of 750 to 1,250 ppm (of a 1:3 electrolyte) agrees with one's expectations, based on overall findings.