UA138537U - SUPERPURE COMPOSITION OF MICROELEMENTS WITH CARBONIC ACID BASED ON WATER SATURATED WITH HYDROGEN - Google Patents

Abstract

The superpure composition of trace elements with carboxylic acid based on water saturated with hydrogen contains a superpure aqueous composition of at least two trace elements from the group: selenium, iodine, sulfur, bromine - with carboxylic acid and carboxylate of at least one trace element selected from the group comprising iron, magnesium, manganese, zinc, in which complex compounds of iodine, sulfur and selenium with carboxylic acid and carboxylates of iron, magnesium, manganese, zinc are obtained by the interaction of micro- and nanoparticles of selenium, iodine, sulfur, iron, magnesium, manganese, zinc with carboxylic acid in aqueous medium . Has a hydrogen concentration of not less than 0.5 ppm, preferably not less than 1 ppm, has an oxygen concentration of not more than 0.1 ppm, preferably not more than 0.05 ppm. The value of the redox potential of the superpure composition of trace elements with carboxylic acid based on water saturated with hydrogen is in the range from minus 150 to minus 420 mV, preferably from minus 250 to minus 420 mV.

Description

A useful model belongs to the field of chemistry, more precisely to compositions of trace elements with carboxylic acid, which are widely used in medicine, agriculture, and biology.

A known aqueous composition of a metal with a carboxylic acid with a general formula of the form (ВСОО)pMe, where Me is a metal, НСОО is a carboxyl anion, p-1, 2, 3, obtained by the interaction of a metal, a metal oxide or a metal hydroxide with a carboxylic acid in an aqueous colloid solution

At the same time, the content of chlorine, nitrate and sulfate ions does not exceed 0.000001 wt. 95, while the metal, metal oxide, and metal hydroxide are in the colloidal solution in the form of metal nanoparticles, metal oxide nanoparticles, and metal hydroxide nanoparticles obtained by ablation of metal granules in water, and the ratio of the mass of metal carboxylate to the mass of nanoparticles is at least 1000 (see . Patent of Ukraine for utility model Mo 39397. Ultrapure aqueous solution of metal nanocarboxylate. IPC СО7С 51/41, СО7Е 5/00, СО7Е 15/00, С07С 53/126 (2008.01). Published 25.02.2009, Bull. Mo 4, 2009).

The disadvantage is the low quality of the composition, due to impurities of metal nanoparticles, which can have a negative effect on the body of humans and animals.

A known composition of trace elements containing minerals: phosphorus, potassium, magnesium, calcium, sulfur, iron, aluminum, manganese, zinc, copper, iodine, in which water saturated with hydrogen with a negative redox potential is used as a solvent for the production of biologically active additives ( ORP) from -201 to -225 m (Patent of Russia Mo 2568588. USE OF WATER WITH

NEGATIVE OXIDATION-REDUCTION POTENTIAL LESS

ZERO AS A BASE OF GELS FOR BIOLOGICALLY ACTIVE SUPPLEMENTS

GEL. IPC A6ITK 47/02. Publ. 20.11.2015 Bul. Mo 32).

The disadvantage of the known composition of trace elements is the presence in it of an uncontrolled amount of foreign impurities, which reduces its quality. This is due to the fact that it does not use high-purity phosphorus, potassium, magnesium, calcium, sulfur, iron, aluminum, manganese, zinc, copper, iodine in elemental form, but as a source of trace elements plant fruit extracts are used, the content of which is difficult to control as trace elements and foreign impurities. The presence of impurities changes the effect of active substances included in the composition of the substance. The second disadvantage of the known substance is the narrow range of ORP from -201 to -225 mV, while the standard redox potentials of biological systems are located in the range from -420 mV to 1820 mV (E.V. Pradedova, O.D.

Nymaeva, R.K. Salyaev. REDOX PROCESSES! IN BIOLOGICAL SYSTEMS. Journal "Physiology of Plants". Vol. 64, Mo. 6, 2017, pp. 433-445).

The closest to the claimed aqueous composition of trace elements is an ultrapure aqueous composition of trace elements with a carboxylic acid, which is a complex compound of trace elements with a carboxylic acid, containing at least two trace elements selected from the group including bromine, sulfur, selenium, which are obtained by interaction of micro- and nano-particles of trace elements with carboxylic acid in an aqueous medium (see Patent of Ukraine for utility model Mo 131087. ULTRA-PURE AQUEOUS COMPOSITION OF MICRO-ELEMENTS WITH CARBON

ACID. IPC AbIK 36/00, AEIK 33/00, AEIK 33/18, Ab1R 7/06. Publ. 10.01.2019, Bul. Mo 1).

The disadvantage of the known aqueous composition of trace elements with carboxylic acid is that the ORP of this aqueous composition of trace elements differs from the ORP of the internal environment of the human and animal body. This reduces the digestibility of trace elements and reduces the effectiveness of the substance. Thus, the ORP of the internal environment of a healthy person is always less than zero and ranges from -30 to -130 millivolts. The ORP of almost any, including purified water, is always greater than zero and ranges from 200 to 1400 millivolts. The indicated differences in the ORP of the internal environment of the human body and aqueous solutions mean that the activity of electrons in the internal environment of the human body is much higher than the activity of electrons in an aqueous solution. When such an aqueous solution penetrates the tissue of a human (or other) organism, it takes away electrons from cells and tissues. As a result, the biological structures of the body are subject to oxidative destruction. If the aqueous solution entering the body has an ORP close to the value of the ORP of the internal environment of the human body, then water and substances dissolved in it are easily absorbed, as they are biologically compatible according to this parameter. If the aqueous solution has an ORP more negative than the ORP of the body's internal environment, it feeds the body with energy that is used by cells as an energy reserve for the body's antioxidant protection against the adverse effects of the external environment (E.V. Pradedova, O.D. Nymayeva, R.K Salyaev. RARE PROCESS V

BIOLOGICAL SYSTEMS. Journal "Physiology of Plants". Vol. 64, Mo. 6, 2017, pp. 433-445).

The basis of the useful model is the task of increasing the efficiency of the aqueous composition of trace elements with carboxylic acid as a source of trace elements.

The task is solved in a water-based ultrapure composition of trace elements with carboxylic acid, containing an ultrapure aqueous composition of at least two trace elements from the group: selenium, iodine, sulfur, bromine - with carboxylic acid and a carboxylate of at least one trace element selected from the group that includes iron, magnesium, manganese, zinc, complex compounds of iodine, sulfur and selenium with carboxylic acid and carboxylates of iron, magnesium, manganese, zinc obtained in it by the interaction of micro- and nanoparticles of selenium, iodine, sulfur, iron, magnesium, manganese, zinc with carboxylic acid in aqueous medium, according to a useful model, has a hydrogen concentration of at least 0.5 ppt, preferably at least 1 ppt, has an oxygen concentration of no more than 0.1 ppt, preferably no more than 0.05 ppt, and the value of the redox potential of the ultrapure composition of trace elements with carboxylic acid based on water saturated with hydrogen is in the range of minus 150 to minus 420 mV, preferably from minus 250 to minus 420 mV. At the same time, when it is obtained, selenium, iodine, sulfur, bromine, iron, magnesium, copper, manganese, zinc in elemental form are used as starting substances containing trace elements, and food acids are used as carboxylic acids, and the content of foreign impurities in it is not exceeds 0.01 wt. at. This increases the effectiveness of the micronutrient composition with water-based carboxylic acid as a source of micronutrients.

The ultra-pure composition of trace elements with carboxylic acid is obtained on the basis of water saturated with hydrogen. Due to the single electron and the very small energy of the bond between the electron and the nucleus, equal to only 13.6 eV, hydrogen is a natural active antioxidant. And thanks to its small size, hydrogen is the best antioxidant, because it is able to penetrate cell membranes and clogged blood vessels. Aqueous solutions saturated with hydrogen, which have a negative ORP and, accordingly, have reducing properties, show high biological activity (I.M. Piskarev,

Ushkanov V.A. OXIDATION-REDUCTION POTENTIAL OF SATURATED WATER

HYDROGEN. National Institute of Nuclear Physics named after D.V. Skobeltsna 2006).

Ultra-pure composition of trace elements with carboxylic acid based on water saturated with hydrogen, obtained by interaction of carboxylic acid with nanoparticles of a trace element in an aqueous colloidal solution of nanoparticles of a trace element. This makes it possible to use for its production such highly pure substances as elemental selenium, elemental iodine, elemental sulfur, elemental bromine, elemental iron, elemental magnesium, elemental

Z manganese, elemental zinc. As a result, the composition has a high purity, in which the content of extraneous impurities does not exceed 0.01 wt. 95. This increases the quality of the composition of trace elements with carboxylic acid as a source of trace elements. When the content of extraneous impurities is more than 0.01 wt. 96 quality of trace elements decreases, toxicity increases, which accordingly limits its use for medicinal preparations.

The ultra-pure composition of trace elements with carboxylic acid based on hydrogen-saturated water has a hydrogen concentration of at least 0.5 ppm, preferably at least 1 ppm. At a hydrogen concentration of less than 0.5 ppt, it is impossible to ensure the value of the redox potential from minus 150 to minus 420 mV.

The ultra-pure composition of trace elements with carboxylic acid based on hydrogen-saturated water has an oxygen concentration of no more than 0.1 ppm, preferably no more than 0.05 ppm. At an oxygen concentration of more than 0.1 ppt, it is also impossible to ensure the value of the redox potential from minus 150 to minus 420 mV.

Ultrapure composition of trace elements with carboxylic acid based on water saturated with hydrogen, has a value of redox potential from minus 150 to minus 420 mV, preferably from minus 250 to minus 420 mV. Redox reactions in biological systems occur in an aqueous solution. Standard redox potentials of biological systems range from -420 mV to 1820 mV. Therefore, the extreme limit of negative ORP for aqueous solutions should not exceed the limit of minus 420 mV (E.V. Pradedova, O.D. Nymaeva, R.K. Salyaev. REDOX-

PROCESSES IN BIOLOGICAL SYSTEMS. Journal "Physiology of Plants". Vol. 64, Mo. 6, 2017, pp. 433-445). When the value of the redox potential is more than minus 150 mV, the biological activity of the composition of microelements decreases.

When obtaining an ultrapure composition of trace elements with carboxylic acid based on water saturated with hydrogen, food acids are used as carboxylic acids. This increases the digestibility of the obtained substance as a source of trace elements.

Example.

An ultrapure composition of selenium, iodine, sulfur, bromine, iron, magnesium, manganese and zinc with citric acid based on water saturated with hydrogen is obtained in this way. First, an aqueous colloidal solution of nanoparticles of selenium, iodine, sulfur and a separately aqueous colloidal solution of nanoparticles of iron, magnesium, manganese, and zinc are obtained separately. To obtain a colloidal bo solution of nanoparticles of microelements, use, for example, electropulse ablation

(see Patent of Ukraine for utility model Mo 23550. Method of erosion-explosive dispersion of metals. IPC B22E 9/14. Publ. 05/25/2007. Bull. Mo 7). Granules of iodine, selenium and sulfur are placed in a vessel for dispersion and evenly placed on the bottom of the vessel between the electrodes. Deionized water is poured into the vessel. When pulses of electric current, in which the energy of the pulses exceeds the sublimation energy of these microelements, pass through the chains of granules of iodine, selenium, and sulfur, spark discharges occur at the points of contact of granules of microelements with each other, in which explosive dispersion of iodine, selenium, and sulfur is carried out. The temperature in the discharge channels reaches 10,000 degrees. Areas of the surface of iodine, selenium and sulfur granules in the zones of spark discharges melt and explosively collapse into the smallest nanoparticles and steam. The molten nanoparticles that fly away fall into the water, cool down in it and form a colloidal solution of nanoparticles of iodine, selenium and sulfur.

Similarly, an aqueous colloidal solution of nanoparticles of iron, magnesium, manganese, and zinc is obtained.

Due to the high activity of nanoparticles and their developed surface, nanoparticles react with oxygen dissolved in water. This leads to a slight increase in the pH of the solution and a slight increase in the electrical conductivity of deionized water. As a result, hydrogen begins to form at the cathode, due to its dissolution in water, the aqueous colloidal solution is saturated with hydrogen. The solubility of hydrogen in water is 18.2 ml/l.

The value of the ORP redox potential decreases to minus 50 - minus 250 mV.

Oxygen is formed at the anode. The solubility of oxygen in water is 31 ml/l. However, the oxygen formed at the anode does not lead to the saturation of water with it, because the nanoparticles capture it with the formation of oxides and hydroxides. The concentration of oxygen in the colloidal solution does not exceed 01 ppm.

Citric acid is added to the resulting colloidal solution of selenium, iodine, and sulfur nanoparticles.

Since no other substances are included in the number of reagents, and nanoparticles of selenium, iodine and sulfur are almost completely involved in the reaction of the formation of complex compounds, a product of high biological activity and ecological purity with a very low content of impurities is formed.

During the interaction of citric acid with nanoparticles of selenium, iodine and sulfur, hydrogen is formed, which increases the degree of saturation of the solution with hydrogen. Then bromine is added to the solution. After decolorization

From the solution, an ultrapure aqueous composition of selenium, iodine, sulfur and bromine with citric acid, saturated with hydrogen, is formed.

A colloidal solution of nanoparticles of iron, magnesium, manganese and zinc pre-obtained and pre-saturated with hydrogen is mixed with an aqueous composition of iodine, sulfur, bromine and selenium with citric acid, also saturated with hydrogen at the time of preparation. Citric acid is added to the mixture obtained in this way in an amount not less than necessary for the formation of iron, magnesium, manganese and zinc citrates in the mixture in accordance with the stoichiometric ratio to the amount of iron, magnesium, manganese and zinc added to the mixture in the form of nanoparticles. During the formation of citrates of iron, magnesium, manganese and zinc, which occurs during the interaction of citric acid with nanoparticles of iron, magnesium, manganese and zinc, hydrogen is formed, which further increases the degree of saturation of the aqueous composition of trace elements with hydrogen. As a result, the redox potential of the water composition of trace elements reaches minus 250 mV - minus 420 mV.

The resulting ultrapure composition of microelements with carboxylic (citric) acid based on hydrogen-saturated water does not contain potassium iodide, potassium bromide and/or sodium bromide, sodium selenite, sulfides or sulfates, which makes it possible to obtain a product of high ecological purity and biological activity .

Claims (4)

USEFUL MODEL FORMULA 1. Ultrapure composition of trace elements with carboxylic acid based on water saturated with hydrogen, which contains an ultrapure aqueous composition of at least two trace elements from the group: selenium, iodine, sulfur, bromine - with carboxylic acid and a carboxylate of at least one trace element selected from the group that includes iron , magnesium, manganese, zinc, in which complex compounds of iodine, sulfur and selenium with carboxylic acid and carboxylates of iron, magnesium, manganese, zinc are obtained by the interaction of micro- and nano-particles of selenium, iodine, sulfur, iron, magnesium, manganese, zinc with carboxylic acid in an aqueous environment, which is distinguished by having a hydrogen concentration of at least 0.5 ppt, preferably at least 1 ppt, an oxygen concentration of no more than 0.1 ppt, preferably no more than 0.05 ppt, and the value of the redox potential of ultrapure composition of trace elements with carboxylic acid based on water saturated with hydrogen, 60 is in the range of minus 150 to minus 420 mV, preferably from minus 250 to minus 420 mV. 2. Ultrapure composition of microelements with carboxylic acid based on water saturated with hydrogen, according to claim 1, which differs in that when it is obtained, selenium, iodine, sulfur, bromine, iron, magnesium, copper are used as starting substances containing the microelement. manganese, zinc in elemental form. 3. Ultrapure composition of microelements with carboxylic acid based on water saturated with hydrogen according to any of claims 1, 2, which differs in that food acids are used as carboxylic acids in its preparation. 4. Ultrapure composition of microelements with carboxylic acid based on water saturated with hydrogen, according to any of claims 1-3, which is characterized by the fact that the content of foreign impurities in it does not exceed 0.01 wt. 95.