RU2713367C1 - Method of producing colloidal solution of titanium trisulphide with antimicrobial properties - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: invention can be used in treating soil, porous structures and waste water in order to suppress activity of pathogenic microorganisms. To obtain colloidal solutions of titanium trisulphide in deionised water, having antimicrobial activity, synthesis of titanium trisulphide from metallic titanium and powder of elemental sulfur, taken in stoichiometric ratio according to reaction Ti+3S=TiS. Metal titanium and elementary sulfur powder are sealed in quartz ampoules in vacuum of not less than 10 bar. Synthesis is carried out in a tubular furnace for 24 or 48 hours at temperatures from 450 to 500 °C at temperature gradient. Resulting crystals are dispersed in deionised water in concentration from 0.001 to 0.01 g/l with ultrasound treatment. Then, before use dispersion top part is centrifuged and separated.EFFECT: invention enables to obtain an antimicrobial solution without using wide-spectrum antibiotics, with the possibility of long-term storage of the powdered component before preparing the dispersion, and reduces harm to the environment.1 cl, 2 dwg, 1 ex

Description

FIELD OF THE INVENTION

The invention can be used to treat porous systems in order to suppress the activity of pathogenic microorganisms, including the treatment of various types of soils.

State of the art

As analogues of the present invention, patent [RU 2025470 C1] can be considered which describes a method for producing a medium that improves plant growth by treating the waste of separating cotton fibers with a solution or dispersion of hexachlorophene. Moreover, the authors mainly plan to use this moment only for composting existing cotton production waste, and the description does not affect the direct effect of the main active substances on microorganisms and does not include soil treatment or addition to other compositions and compositions. Antimicrobial compositions containing nanoparticles of inorganic compounds are described in [RU2327459 C1]. Where the authors consider the possibility of using compositions of inorganic nanoparticles and protein agents that allow the drug to be administered without significant side effects. That is, the invention involves the use of a carrier protein and an antimicrobial agent that inhibits the growth of pathogenic organisms and prevents contamination of the medium. Since the described invention involves the use of titanium trisulfide as the main antimicrobial agent, it can be indicated that the method of self-propagating high-temperature synthesis is patented for its production, where Ti ₂ S is used as the starting material [RU 2552544 C2], while the authors of this application propose applying an alternative approach using pure metal and elemental sulfur.

Disclosure of Invention

The essence of the invention lies in the use of gas transport reaction techniques to obtain crystals of pure titanium trisulfide (TiS ₃ ) in sealed quartz ampoules. The starting materials used are metallic titanium in the form of a powder or foil and elemental sulfur powder in a shallow vacuum of no worse than 10 ^-3 bar. The synthesis should be carried out at a temperature of not more than 500 ° C and not less than 450 ° C. The size of the ampoule should be in the range of 10 to 25 cm in length. For the synthesis, a tube furnace with a diameter of the working zone of 50 mm is used. Synthesis is carried out within 24 or 48 hours. The crystals obtained as a result of synthesis are used to prepare colloidal solutions in deionized water at a concentration of from 0.001 to 1 g / l as a result of sonication in closed tubes for 2 hours. The resulting colloid is then decanted and a stable dispersion is drained from the precipitate, suitable for research and further use. Since the material has a layered structure as a result of the action of ultrasound, peeling of crystallites occurs across the crystallographic direction 'c', where there are no strong covalent bonds, which leads to an even more developed surface and an increase in the activity of this material.

The invention is primarily aimed at the use as a liquid antimicrobial agent for soil treatment, porous structures and wastewater. The invention is characterized by the possibility of long-term storage of the powder component before preparing the dispersion. Also, during the interaction of titanium trisulfide with water due to a highly developed surface, various impurities and microorganisms sorb onto the surface of the solid phase, which can lead to flocculation with the possibility of separation of pathogenic microorganisms by the method as a result of sedimentation of sediment.

Due to the fact that during the interaction of TiS ₃ with water, the formation of small amounts of H ₂ S can be observed, the active life activity of many different pathogenic microorganisms is suppressed. The presence of sulfur in the active substance also contributes to the manifestation and fungicidal properties.

The main difference from analogues is the use of active solid phase nanoparticles in the form of colloidal solutions directly having antimicrobial activity without the need to use organic compounds of the broad-spectrum antibiotic class. Moreover, in the case of prolonged exposure to light and oxygen, the material can turn into harmless titanium oxide, which allows us to talk about low environmental damage.

Example 1

At the first stage, for the synthesis of the TiS ₃ compound, weighed portions of pure titanium powder (99.99%) and ChDA grade elemental sulfur powder in a stoichiometric ratio in accordance with reaction 1.

The obtained sample was analyzed by scanning electron and optical microscopy, Raman spectroscopy, X-ray diffraction analysis and atomic force microscopy. The results of scanning electron microscopy are shown in figure 1. As can be seen from the image as a result of synthesis, ribbons were obtained whose width varies from 1 to 10 μm, and the thickness is less than 100 nm.

At the second stage, the obtained material is washed in isopropanol and distilled water 2 times, and then it is either dried for further storage or dispersed in the required buffer or deionized water to obtain a colloid with ultrasonic treatment for 10 minutes.

Further stabilization is achieved by centrifugation at 6000 rpm for 15 minutes of the colloid obtained after sonication with subsequent separation of the precipitate. The result is a colloidal solution of TiS ₃ particles in the required buffer. The stability of these colloids is evaluated in accordance with the stability assessment technique, which is based on the method of measuring the electrokinetic potential (zeta potential) and particle size distribution.

The study of the biocidal properties of titanium trisulfide (Fig. 2) showed interesting properties of the nanomaterial — the manifestation of high antibacterial activity at low concentrations (complete death of microorganisms) and the stimulation of bacterial luminescence in high concentrations. Moreover, the storage time of the dispersions of nanoparticles did not affect the properties shown, with the exception of the 0.1 g / l variant, in which the opposite effect of the nanopreparation on the test object was noted - the manifestation of the high toxic effect of a fresh solution and the maximum stimulation of bacterial luminescence under the action of a sample aged 24 hours.

Claims (1)

A method for producing colloidal solutions of titanium trisulfide in deionized water having antimicrobial activity, including the synthesis of titanium trisulfide from titanium metal and elemental sulfur powder, taken in stoichiometric ratio in accordance with the reaction Ti + 3S = TiS ₃ , sealed in quartz ampoules in vacuum no worse than 10 ^-3 bar, while the synthesis is carried out in a tube furnace for 24 or 48 hours at temperatures from 450 to 500 ° C with a temperature gradient, the crystals obtained as a result of synthesis are dispersed in deionized water in a concentration of from 0.001 to 0.01 g / l during ultrasonic treatment, then centrifugation and separation of the upper part of the dispersion are carried out before use.

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