ASEAASEA is the first and only stable, perfectly balanced mixture of Redox Signaling reactive molecules that exists outside the body, and can be used to help maintain proper balance inside the body to support the immune system and healing process.

Redox Signaling is a function that is central to all life on the planet. These molecules are created within every cell of the body and are vital to the immune system and cellular healing. Without Redox Signaling reactive molecules, you would die within seconds. A good supply of Redox Signaling molecules produces cellular healing: damaged cells being replaced by healthy, vibrant cells.

After age 12, our cells make fewer of these molecules - ASEA is the only source for replenishing Redox Signaling molecules.

 


Read more about ASEA:

asea

Understanding Human Metabolism, Metabolites, and Recent ASEA Research Developments

Prepared by: Gary Samuelson, Ph.D. Robertson D. Ward, M.D., FAAFP
David Carpenter, N.D., C.Ac., C.C.I.

The North Carolina Research Campus, and the Appalachian State University Human Performance Laboratory, under the direction of Dr. David Nieman’s world renowned team of scientists, uncovered new findings proving that the consumption of ASEA empowers humans to shift the availability of free fatty acids. These calorie sources represent a more favorable and efficient source of fuel for exercise and all daily life activity.

Facts about Our Metabolism

Cells inside our body breathe! The processes of metabolism at a cellular level involves the consumption of molecular oxygen and large molecule energy sources (sugar, glycogen, fatty acids, and amino acids). Through the process of oxidative phosphorylation (cellular respiration…breathing!) the cells create energy (ATP). The mitochondria in our cells do this work, and this is where Redox Signaling molecules are created.

Metabolism and Athletes

We understand that our cells always strive to run at the greatest efficiency possible. Through the conditioning of our bodies, our cells learn to use certain fuel sources preferentially. We are all familiar with the fatigue and pain that happens after rigorously exercising out-of-shape muscle groups. This happens because the muscle exhausts the standard glycogen source for fuel and then shifts to anaerobic metabolism (using fuel without oxygen), which forms lactic acid metabolites. But trained distance runners have conditioned their bodies to utilize a different fuel source: fatty acids (which are 6 times more energy-providing than other sources). By using fatty acids, these athletes preserve their muscle glycogen stores for strenuous bursts, like at the end of races, and that means greater endurance.

This is important. Endurance athletes actually condition their bodies to use fatty acids as a preferred fuel source, sparing muscle glycogen and increasing endurance.

Specific Metabolite Research Findings with ASEA:

The astonishing results of this randomized, double-blinded, crossover, placebo-based research showed that after one week of drinking 4 ounces of ASEA daily, the test subjects demonstrated a shift in 43 of 108 metabolites measured from the blood sample. These shifts were revealed using ultra-sensitive mass-spectroscopic measurement techniques. These shifts were so great that it was thought that there might be a software anomaly and scientists requested a manual inspection to verify data.

The largest metabolite shifts were in serum fatty acids. Again, these shifts happened after one week of consumption and before any athletic activity. Fatty acids are typically mobilized from abdominal body fat stores. They included myristic acid, palmitic acid, oleic acid, stearic acid, palmitelaidic acid, and capric acid. Don’t let the “acid” part throw you off; these are sources of fuel for the human body.

The chemical markers of these fatty acids are called “metabolites,” and their various concentrations in our blood represent a fingerprint of our metabolic balance. The metabolite shifts found due to ASEA ingestion are profound and very beneficial to health, since these shifts mimic what the body does when seeking fuel efficiency; that is, using fatty acids as a preferred fuel source and sparing muscle glycogen.

These important metabolite changes have resulted in applications for new patents for ASEA, and have prompted further studies at the North Carolina Research Campus. Additionally, all of these changes occurred without any evidence of toxicity whatsoever on any basic organ functions in liver and kidney tissue.

Conclusions

These initial results from a larger study on athletic performance have demonstrated that ASEA, which is composed of Redox Signaling molecules, has a profound impact on mobilization of fatty acids as they aid with efficiency in cellular respiration. This favorable pattern of increased availability of fatty acids for fuel consumption represents a foundational shift in our metabolic fingerprint – a shift toward more effective patterns of fuel usage and energy output.