pH Explanation
Whether a substance is considered alkaline or acid is determined by its pH (potential of hydrogen). pH is the measurement of the hydrogen ion concentration and is expressed in terms of a logarithmic expression. pH is quantified in a scale that ranges from 0 (which represents a complete saturation of hydrogen ions) to 14 (which represents a complete void of hydrogen ions). A pH measurement which falls between 0 and 6.99 is considered acidic while a pH measurement from 7.01 to 14 is considered to be alkaline. A pH reading of exactly 7.00 represents the middle point and is considered to be neither acid or alkaline. |
As the pH of a sample increases, the hydrogen ion concentration decreases. Conversely, as the pH of a sample decreases, the hydrogen ion concentration increases.
An accurate and precise measurement of the bodily fluids' pH is essential to understanding and then creating optimal health. The fact that hormone receptor sites, enzyme kinetics and mitochondrial function are all pH dependent, sheds a light of importance on comprehending the relative value of pH, while also providing effective means to controlling its variance.
rH2 Explanation
rH2 is a measurement of oxidation-reduction potential under a specific pH measurement. It indicates the amount of electron potential that exists in a tested solution.
The rH2 scale ranges from 042, where 28 represents the mid-point where the relative concentration of electron donors is approximately equivalent to the relative concentration of electron acceptors. Any rH2 value noted below 28 is considered to be reduced and contains a greater number of electron donors then electron acceptors. Conversely, if the value is greater then 28 the fluid is considered to be oxidized. Oxidized fluid has a lower number of electron donors then electron acceptors.
A high number of available electrons in the cells and more specifically in the mitochondria is a highly desirable condition. The electrons are produced as a result of an active and productive Krebs Cycle. The electrons are carried in high-energy biochemical intermediates. These intermediates are converted to usable energy (ATP, GTP) through the electron transport, oxidative phosporylation mechanism. In this case the rH2 value of the blood has increased from the optimal range. This indicates that the relative concentration of electron donors to electron acceptors has decreased. This scenario translates into a lowered ability to produce high-energy cellular fuel (ATP, GTP).
r Explanation
r is a measurement of resistivity in ohms. This reading is synonymous with the relative concentration of electrically conductive ions in solution. When biological fluids are being tested, r is an excellent indicator of relative mineral concentrations. r is inversely proportional to this relative concentration of minerals in such a way as when mineral concentration increases, r decreases. Conversely, when mineral concentration decreases, the r value increases.
When the r value is elevated it may indicate a lack of adequate and normal mineral concentration. This condition can often times be caused by malabsorption, which restricts the minerals from being properly absorbed, and transported into the blood.
An accurate and precise measurement of the bodily fluids' pH is essential to understanding and then creating optimal health. The fact that hormone receptor sites, enzyme kinetics and mitochondrial function are all pH dependent, sheds a light of importance on comprehending the relative value of pH, while also providing effective means to controlling its variance.
rH2 Explanation
rH2 is a measurement of oxidation-reduction potential under a specific pH measurement. It indicates the amount of electron potential that exists in a tested solution.
The rH2 scale ranges from 042, where 28 represents the mid-point where the relative concentration of electron donors is approximately equivalent to the relative concentration of electron acceptors. Any rH2 value noted below 28 is considered to be reduced and contains a greater number of electron donors then electron acceptors. Conversely, if the value is greater then 28 the fluid is considered to be oxidized. Oxidized fluid has a lower number of electron donors then electron acceptors.
A high number of available electrons in the cells and more specifically in the mitochondria is a highly desirable condition. The electrons are produced as a result of an active and productive Krebs Cycle. The electrons are carried in high-energy biochemical intermediates. These intermediates are converted to usable energy (ATP, GTP) through the electron transport, oxidative phosporylation mechanism. In this case the rH2 value of the blood has increased from the optimal range. This indicates that the relative concentration of electron donors to electron acceptors has decreased. This scenario translates into a lowered ability to produce high-energy cellular fuel (ATP, GTP).
r Explanation
r is a measurement of resistivity in ohms. This reading is synonymous with the relative concentration of electrically conductive ions in solution. When biological fluids are being tested, r is an excellent indicator of relative mineral concentrations. r is inversely proportional to this relative concentration of minerals in such a way as when mineral concentration increases, r decreases. Conversely, when mineral concentration decreases, the r value increases.
When the r value is elevated it may indicate a lack of adequate and normal mineral concentration. This condition can often times be caused by malabsorption, which restricts the minerals from being properly absorbed, and transported into the blood.
Hydration The Hydration Index is a quantitative value that can aid in the determination of the relative state of client dehydration. Research has proven that as we age or experience degenerative conditions, the relative levels of available water to and in our cells are diminished. By utilizing this new assessment index, insights into the severity of this condition can be illuminated. Obviously, increasing biologically pure water must be the first step in restoring this value to optimal ranges. However, evaluating and then treating the kidneys as well as the relative mineral supply should also be considered. This Index is based on distortion found in the resistivity values. |
Detoxification Ability
While removing toxic waste from the body should always be considered in the very first line of therapy, it must be noted that all clients do not detoxify equally. A certain amount of base cellular energy is necessary on order to facilitate the removal of waste products. If the underlying source of energy is not sufficient to allow for active transport and removal of waste products, then detoxification will not occur. By monitoring the detoxification ability information, a broad-spectrum assessment of these capacities can be realized. The resistivity values as well as the redox levels determine the detoxification ability factor.
Digestive Stress Factor
Many distinguished authorities have held onto the paradigm that the beginning of all dis-ease states begins in the digestive system. If the digestive system is functioning properly, then food products are effortlessly broken down to bio-available energy to run the many formal aspects of metabolism. If, however, the digestive system is distressed, then every subsequent metabolic process will also be compromised. The scientific data that precludes the degree of digestive stress is found in pH and redox information.
Mitochondrial Activity Level
All life is dependent upon the ability to produce useful energy packets that can be converted into functional metabolic pathways. In the human cell the organelle that is responsible for this crucial conversion of electrons into energy (ATP) is the mitochondria. If the mitochondria do not adequately produce life-giving energy, then the system will deteriorate and eventually die.
Maintaining optimal mitochondrial function and energy production is essential. Additionally, to Insure that the mitochondria is functioning properly there must exist a delicate balance between free radical production and elimination. If no oxidative stress is found in the mitochondria then it has lost its ability to protect itself against xenobiotic toxicity. If however, too great of a degree of oxidative stress occurs then permanent damage to mitochondrial sensitive DNA might occur. The mitochondrial activity level indicators, which are based on the degree of oxidative stress found within the fluids, might be a valuable means of monitoring this intercellular structure.
Organic Buffer Capacity
The quantity and capacity of the body's many buffer systems are essential to regulating pH sensitive metabolic processes. For instance, all enzymes that function within the body are dependent upon a specific pH range to function properly. If the pH varies outside of this defined range, the enzyme will not function.
The body has a very limited and exhaustive supply of buffers. If this supply is depleted, the pH values of the critical tissue will not remain stable. It is therefore essential that the buffer capacity never be drained and that there always remains a reserved amount to maintain adequate pH balance. This factor is determined by assessing the body's compensatory mechanisms to alterations of pH. If the body has an excellent ability to help compensate a significant alteration in pH then the overall buffering capacity of the system is excellent. If however the body has lost its ability to compensate for a pH shift then increasing organic salts and supporting the buffering capabilities of the body becomes crucial.
While removing toxic waste from the body should always be considered in the very first line of therapy, it must be noted that all clients do not detoxify equally. A certain amount of base cellular energy is necessary on order to facilitate the removal of waste products. If the underlying source of energy is not sufficient to allow for active transport and removal of waste products, then detoxification will not occur. By monitoring the detoxification ability information, a broad-spectrum assessment of these capacities can be realized. The resistivity values as well as the redox levels determine the detoxification ability factor.
Digestive Stress Factor
Many distinguished authorities have held onto the paradigm that the beginning of all dis-ease states begins in the digestive system. If the digestive system is functioning properly, then food products are effortlessly broken down to bio-available energy to run the many formal aspects of metabolism. If, however, the digestive system is distressed, then every subsequent metabolic process will also be compromised. The scientific data that precludes the degree of digestive stress is found in pH and redox information.
Mitochondrial Activity Level
All life is dependent upon the ability to produce useful energy packets that can be converted into functional metabolic pathways. In the human cell the organelle that is responsible for this crucial conversion of electrons into energy (ATP) is the mitochondria. If the mitochondria do not adequately produce life-giving energy, then the system will deteriorate and eventually die.
Maintaining optimal mitochondrial function and energy production is essential. Additionally, to Insure that the mitochondria is functioning properly there must exist a delicate balance between free radical production and elimination. If no oxidative stress is found in the mitochondria then it has lost its ability to protect itself against xenobiotic toxicity. If however, too great of a degree of oxidative stress occurs then permanent damage to mitochondrial sensitive DNA might occur. The mitochondrial activity level indicators, which are based on the degree of oxidative stress found within the fluids, might be a valuable means of monitoring this intercellular structure.
Organic Buffer Capacity
The quantity and capacity of the body's many buffer systems are essential to regulating pH sensitive metabolic processes. For instance, all enzymes that function within the body are dependent upon a specific pH range to function properly. If the pH varies outside of this defined range, the enzyme will not function.
The body has a very limited and exhaustive supply of buffers. If this supply is depleted, the pH values of the critical tissue will not remain stable. It is therefore essential that the buffer capacity never be drained and that there always remains a reserved amount to maintain adequate pH balance. This factor is determined by assessing the body's compensatory mechanisms to alterations of pH. If the body has an excellent ability to help compensate a significant alteration in pH then the overall buffering capacity of the system is excellent. If however the body has lost its ability to compensate for a pH shift then increasing organic salts and supporting the buffering capabilities of the body becomes crucial.
Biological Age Biological age is a mathematical calculation based strictly and solely on the levels of oxidative stress. There is a direct relationship between an increase in oxidative stress and an increase in the biological age factor. The converse is also true, a decrease in oxidative stress will cause a decrease in the biological age factor. |