Cellfood Delivery System
When you mix Cellfood with water or
juice and ingest it, its proprietary water-splitting action begins
the moment you take the first sip. This cascading time release of
oxygen typically peaks within 8-12 hours, and then keeps working
hour after hour. In partnership with the body's own natural
intelligence, Cellfood releases oxygen whenever and wherever it's
needed— and if no longer needed, no more is released. And, its
essential natural minerals, enzymes, amino acids and electrolytes
are delivered simultaneously throughout the body on the deepest
cellular level.
Cellfood is a miracle of electromagnetic design. Since
Cellfood is colloidal and negatively charged— just like the blood
and lymph fluid— there is a natural synchronicity between these
fluids. Cellfood and its nutrients move through the cell walls
easily, and its vital nutrients are absorbed and assimilated quickly
and efficiently. And, Cellfood is a di-pole, di-base delivery
system, delivering its nutrients to the cells and tissues under any
conditions. (Di-pole means Cellfood is effective in any polarity
range of the body; di-base means it's effective in any pH range and
will tend to normalize the body's acid/base balance). Therefore,
Cellfood is exceptional as an overall delivery system not only for
its own nutrients, but for increasing cell-absorption (by as much as
3-5 times) of any other nutrients or substances introduced into the
body within the same 24 hour period. Notably, there is no known
toxicity associated with Cellfood.
Importantly, Cellfood won't create free radical damage. Free
radicals— believed to be a primary cause of aging and disease— are
positively charged ions of oxygen. Since Cellfood's released oxygen
molecules are negatively charged, they seek out and attract these
dangerous free radicals, joining with them to form stabilized
oxygen.
The Krebs cycle can be looked on as a machine for removing hydrogens from
foodstuffs; the hydrogens are sent to the Electron Transport System (ETS). Each
molecule of the hydrogen carrier in the Nicotin deAdenine Dinucleotide (NAD),
delivers two electrons and one proton of a hydrogen molecule to the ETS. The
energy produced by the ETS is used to form a chemical bond between Adenosine
Diphosphate (ADP) and inorganic phosphate to form ATP.
In fact, as a pair of electrons pass down the ETS from beginning to end, where
it is captured by oxygen, enough energy is trapped to synthesize three ATP
molecules. In fully functional cells, electron transport is tightly coupled to
oxidative phosphorylation. That is, if ATP synthesis is prevented (which would
happen if there were a lack of ADP or oxygen), electron transport will not take
place.
The initial energy for muscle action comes from the manufacture of ATP. When
energy is released by the breakdown of ATP, the synthesis cells contract. This
system provides energy for short, quick bursts of activity and is a major source
of power for the first 2O-30 seconds of intense exercise. Beyond the second
minute of exercise, the oxygen-using aerobic system, for endurance activities,
predominates.