Blood Fuel Training and the Fountain of Movement

Blood is 70% heavy hydrogen deuterium. Blood cells in your finger have the same DNA as those in your ear. Blood cells that have identical DNA become specialized as a result of the morphogenic field present within you. Damaged blood cells regenerate and new ones grow to regain the original configuration of the healed body part. The moment this is complete, the repair process ceases. Our morphogenic field is a localized intelligence that reverts us to normal as quickly as possible. Blood makes up the larger percentage of our body averaging about 10 gallons. Blood and lymph act more like a gas than a liquid. They can penetrate right through us. Blood is an amazing property. It is lighter as it becomes more solid. Blood is the most amazing solvent on the planet—and it is living!!!

Arterial blood is the oxygenated blood in the circulatory system—found in the lungs, the left chambers of the heart, and arteries.  It is bright red in color, while venous blood is dark red in color but looks purple through the translucent skin. It is the contralateral term to venous blood. Arterial blood passes through the lungs and is ready to boost oxygen to sustain peripheral organs. The essential difference between venous blood and arterial blood is the curve of oxygen saturation of hemoglobin. The difference is the oxygen content of the blood between the arterial blood and the venous blood is know as arteriovenous oxygen difference (AOD).

Venous Blood is deoxygenated blood, which travels from the peripheral vessels, through the venous system into the right atrium of the heart. Deoxygenated blood is then pumped by the right ventricle to the lungs via the pulmonary artery, which is divided into two branches. Blood is oxygenated in the lungs and returns to the left atrium through the pulmonary veins. Venous blood is typically colder than arterial blood, and has a lower oxygen content and pH. It also has a lower concentration of glucose and other nutrients, and has higher concentrations of urea and other waste products. Most laboratory tests are conducted on venous blood, with the exception if arterial blood gas tests. Venous blood is mainly used for blood transfusion. Commonly only components of the blood, such as red blood cells, white blood cells, plasma, clotting factors and platelets are used.

Plasma is the liquid portion of blood. Although often thought of as less important than the cells of the blood that carry oxygen and provide immunity, the plasma is equally, if not, more important as an indicator of many physiological functions in the body. One of these indicators is Blood Volume (BV). Proteins found in blood plasma in highest concentration is called albumin, an important protein for tissue repair and regrowth. This high concentration of albumin is also present in the fluids that surround cells, known as interstitial fluid. The concentration of albumin in this fluid is lower than plasma. Because of this, water is not able to move from the interstitial fluid into the blood. If the plasma did not contain such a high amount of albumin, water would move into the blood, increasing blood volume and causing an increase in blood pressure, which would make the heart work harder.

What Happens to Blood Cells When Athletes are Dehydrated?

Water concentration is essential in this function. The human body cannot function properly without this balance of osmotic deliverance. Dehydration is a condition where more water leaves the body than is taken in. Thirst is one sign of dehydration. There are other forms of dehydration. What happens to cells during dehydration depends on what type of dehydration the body is experiencing.

Hypotonic Dehydration

This is when the body’s fluids have less concentrated salts dissolved in the water. Water present in the extracellular fluid then moves into the cells because the cells have more dissolved salts, therefore, a higher osmotic pressure. It is possible to disrupt cell function and distort cell structure if over hydration occurs, such as when a person drinks too much water without taking salts in as well.

Hypertonic Dehydration

This is when the body has lost more water relative to salts. The extracellular fluid therefore has a higher osmotic pressure. Cells allow water to flow outward and into the extracellular fluid to balance the osmotic pressure difference between inside the cells and outside the cells.

Maintain blood volume and endocrine efficiency through electrolyte balancing.

Plasma carries salts, also called electrolytes, throughout the body. These salts including sodium, calcium, potassium, magnesium, chloride and bicarbonate are imported for many bodily functions. Without a desired concentration of these electrolytes salts, muscles would not contract and nerves would not be able to sent signals to and from the brain.

Hydrogen-Deterium Exchange“Centrifuge of a Snowflake”

Protein structure is the three dimensional arrangement of atoms in a protein molecule. Proteins are polymers, specifically, polypeptides formed from sequences of monomer amino acids. By convention, a chain under 40 amino acids is often identified as a peptide, rather than a protein. To be able to perform their biological function, proteins fold into one or more specific spatial conformations driven by a “number” of non-covalent interactions such as hydrogen bonding, ionic interactions and hydrophobic packing. Protein structures range in size from tens to several thousand amino acids. By physical size, proteins are classified as nanoparticles, between 1-100 nm. Very large aggregates can be formed from protein subunits. For example, many thousands of action muscles assemble into a microfilament. These are the tiniest filaments found in the cytoskeleton, a structure found in the cytoplasm of eukaryotic cells. These linear polymers of action subunits are flexible and relatively strong, resisting buckling by compressive forces and filament fracture by nano newton tensile forces. Microfilaments are highly reusable, functioning in cytokinesis, amoeboid movement, and changes in cellular shape. In inducing this cell motility, one end of the action filament elongates, while the other end contracts, presumably by myosin II molecules motors. Additionally, they fraction as part of actomyosin, driven contractible, molecular motors, where in the thin filaments serve as tensile platforms for myosin ATP dependent pulling action is muscle contraction and pseudopod advancement. Microfilaments have a tough flexible framework, which helps the cell in movement.