Learn about Phosphoric acid metabolism . First, get acquainted (gain, obtain) with present-day techniques that came from Phosphoric Acid Metabolism. Metabolism is a term used to describe all the chemical reactions that play a role in maintaining the living state of cells and organisms. Metabolism can be easily divided into two categories:
Decomposition of molecules to obtain energy
Synthesis of all compounds required by cells
Metabolism is closely linked to nutrition and nutrient availability.
Minerals in foods do not directly contribute to energy needs, but are important as regulators and play a role in the body’s metabolic pathways. More than 50 elements are found in the human body. About 25 essential elements have been identified, meaning that the lack of symptoms creates a certain deficiency, one of which is phosphorus.
Phosphorus is a very important element for several metabolic pathways in all living organisms, exemplified by DNA, RNA, glucose and fructose-P, and adenosine triphosphate (ATP). Total phosphate metabolism in any living organism involves catalysis by many enzymes such as kinases, pyrophosphorylases, isomerases, and phosphatases.
Symptoms of hypophosphatemia include neurological dysfunction and dysfunction of muscles and blood cells, and can be caused by malnutrition, phosphate absorption, and metabolic syndromes. Phosphoric acid is widely used as an acidifying agent in a variety of pharmaceutical formulations such as acidifying, flavoring, antioxidant and synergistic separation. In laboratory and industrial areas, due to safety considerations, phosphoric acid may be considered as a valid alternative to strong and dangerous acids such as sulfuric, hydrochloric and nitric acids. In addition, phosphoric acid, among mineral acids, is less corrosive to steel and all commodities made from it.
With all of these arguments in mind, highly dilute, medium-temperature (o-PA) phosphoric acid can be used as oligosaccharides in the pre-treatment of polysaccharides for many biotechnologies.
The total phosphate metabolism in any living organism involves the catalysis performed by many enzymes. They are designed as kinases (making phosphoric esters), pyrophosphorylases (imported sugar synthesizers for polymers), isomerases such as the conversion of sugar phosphate hexose, G-6-P, to ketosis-6P-like. Phosphatases (hydrolyzed phosphate esters), both anabolic and catabolic, the free phosphate pool, soon Pi, corresponds to the bioavailability of the accumulation bed for the energetic pre-mobility of glucose units in storage polysaccharides.
In this way, glycogen in animals, yeasts and molds, and starches from plants and algae are sequentially catabolized into glucose-1P.
Orthophosphate is absorbed from the gastrointestinal tract and secreted to a limited extent.
Absorbed phosphoric acid is widely distributed in the body as phosphate. Elevated serum phosphate concentrations have rarely been reported after phosphoric acid intake.
In adults, about two-thirds of the ingested phosphate is absorbed and the amount absorbed is almost completely excreted in the urine.
In infants with normal renal function, the half-life of serum phosphate after oral or rectal overdose is 11 to 5 hours.