RU2376761C1 - Antiseptic and fungicidal preparation - Google Patents

Abstract

FIELD: veterinary.

SUBSTANCE: invention relates to field of antiseptic preparations and can be applied in veterinary and agriculture, as well as in medicine, in particular for formation of medium of staying (culturing, storing, processing) of bio-objects in premises, chambers and containers. Antiseptic and fungicidal preparation, contains polydimethyldimethylenepyrrolidinium chloride, water solution of ammonia, tetramethylammonium hydroxide hydrate and (or) tetramethylenediamine and water, with definite ratio of components (wt %).

EFFECT: invention insures duration, strengthening and extension of spectrum of preparation antiseptic effect.

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Description

The invention relates to veterinary medicine and agriculture and can be used to form a host environment (cultivation, storage, processing) of bio-objects in rooms, chambers and containers, and can also be used in medicine.

Known antiseptic agent containing dimethyldiallylammonium chloride and alkali, as well as water [1].

Closest to the proposed is an antiseptic containing polydimethyldiallylammonium chloride, tetra-N-butylammonium hydroxide hydrate and aqueous ammonia, as well as distilled water. The tool has a good effect on tuberculosis microbacteria and is used in medicine [2].

A disadvantage of the known antiseptic agents is the lack of fungicidal properties, the instability of the bactericidal action during storage, the relatively low overall bactericidal activity.

The aim of the invention is to enhance and expand the spectrum of antiseptic action of the agent, the long-term preservation of this action on the surfaces of the shells of containers, for example, on the basis of paper, cardboard, the manifestation of fungicidal properties.

This goal is achieved in that the new antiseptic agent containing poly-N, N-dimethyl-3,4-dimethylene pyrrolidinium chloride, as well as aqueous ammonia and water, additionally contains tetramethylammonium hydroxide hydrate and (or) tetramethylethylenediamine in the following ratio, wt .%:

poly-N, N-dimethyl, 3,4-dimethylene pyrrolidinium chloride 0.5-3.0 Tetramethylammonium hydroxide hydrate 0.1-1.0 Tetramethylethylenediamine Up to 1.0 Aqueous ammonia Up to 0.5 Water Rest

The antiseptic agent according to the invention relates to cationic water-soluble substances containing a Quaternary nitrogen atom in both the monomer compound and the macrochain.

The presence of a huge positive charge on the macrochain, the nature of the anion, the specific structure and structure of the polymer molecule of polydimethyldimethylene pyrrolidinium chloride in combination with such additives or activators as tetramethylammonium hydroxide hydrate, as well as tetramethylethylenediamine, determine the high bactericidal and fungicidal properties of the proposed agent.

Studies have shown that this antiseptic is active against both gram-positive (staphylococci, streptococci, pneumococci) and gram-negative bacteria (typhoid group, dysentery, cholera, etc.). It has been established that the tool inhibits the vital activity of protozoa, fungi and viruses.

Based on the latest data on electron microscopy using the phase contrast method MF-2 and other studies, it was determined that the mechanism of action of the agent consists in the fact that at the first stage there is rapid adsorption by its microbial cell and recharging of the enzymes involved in the energy and oxidation processes leading to their irreversible damage. At the same time, there is a recharge of the protein structure of the cell surface, a change in the membrane permeability and cell death. This is also confirmed by the fact that cell death occurs always earlier than its disintegration.

The use of an antiseptic is illustrated by the following examples.

Example 1

When testing the drug for bacterial activity in the air of a house, the total airborne contamination of the house was determined with the ventilation system turned off by two series of experiments by placing Petri dishes with Endo medium in 6 control points uniformly distributed throughout the house and infecting them with the surrounding air. Then, the value of the infection of the nutrient medium in the Petri dishes was determined in laboratory and controlled conditions according to the standard method and was an estimate of air infection at the control point of the house.

Assessment of airborne infection in the house was determined as the average of values at 6 control points.

The first series of experiments is performed before the drug is introduced into the air of the house, the second series of experiments - 1 hour after the introduction of the drug into the house The average value of insemination obtained in the first series of experiments is taken as 100%.

The results of processing the air environment of the house are given in table 1.

Table 1 Name of components Quantitatively ratio, wt.% Dose, ml / m ³ Seed in% 1 hour after treatment. Polydimethyldimethylenepyrrolidinium chloride 1,0 fifty 37 + 1,2 Tetramethylammonium hydroxide hydrate 0.5 Aqueous ammonia 0.1 Water Rest Polydimethyldimethylenepyrrolidinium chloride 1,0 fifty 52 + 1,0 Tetramethylammonium hydroxide hydrate 0.5 Aqueous ammonia 0.1 Water Rest

As can be seen from the table, the contamination of the air environment of the house after processing decreased by 36-50%.

Example 2

When testing the drug for bactericidal activity in the air of a hatchery, the total airborne contamination of the hatchery air was determined with the ventilation system turned off by two series of experiments by placing Petri dishes with Endo medium at 6 control points uniformly distributed over the volume of the hatchery and infecting them with the surrounding air. Then, similarly to the procedure described in Example 1, the assessment of the total airborne contamination of the air was determined as the average of 6 control measurement points. The average value of insemination obtained in the first series of experiments is taken as 100%. The results of processing the air of the hatchery are given in table.2.

table 2 Name of components Quantitatively ratio, wt.% Dose, ml / m ³ Seed in% 1 hour after treatment. Polydimethyldimethylenepyrrolidinium chloride 1,0 fifty 37 + 1,2 Tetramethylammonium hydroxide hydrate 0.5 Aqueous ammonia 0.1 Water Rest Polydimethyldimethylenepyrrolidinium chloride 3.0 fifty 2.3 + 0.1 Tetramethylammonium hydroxide hydrate 0.5 Aqueous ammonia 0.1 Water Rest

As can be seen from table 2, the seeding of the air of the hatchery is almost completely suppressed with an increase in the amount of polydimethyldimethylene pyrrolidinium chloride.

Example 3

When testing the drug for bacterial activity on the internal surfaces of the premises with the ventilation system turned off, two series of experiments were taken (one series before the drug was used, the second after), washings from various surfaces in the hatchery (wall and trays of the incubation cabinet, cardboard sheets and an egg in the warehouse) and placed them on Petri dishes for the subsequent evaluation of the seed contamination of the surfaces as an average value for the set of (6) control points. The average seed value obtained in the first series of experiments, It is charged for 100%.

The results of surface treatment in the hatchery are given in table 3.

Table 3 Option Name of components Quantitatively ratio, wt.% Seed in% 1 hour after treatment. one Polydimethyldimethylenepyrrolidinium chloride 1,0 36 + 1,5 Tetramethylethylenediamine 0.5 Aqueous ammonia 0.1 Water Rest 2 Polydimethyldimethylenepyrrolidinium chloride 3.0 0.22 + 0.01 Tetramethylammonium hydroxide hydrate 0.5 Tetramethylethylenediamine 0.5 Aqueous ammonia 0.1 Water Rest

The table shows that the maximum inhibition of microbial growth on the inner surfaces of the hatchery was achieved during processing according to the 2nd option.

Example 4

When testing for the duration of the manifestation of bactericidal properties, 24 hours after treatment with the preparation according to Example 3, washes were taken from cardboard laying of eggs and their seeding was determined in the above manner. As a result, it was obtained that after treatment with the preparation in option 2, there was no bacterial growth on the nutrient media.

Example 5

When laying the potatoes harvested in conditions of excessive humidity (Moscow Region, autumn 2006) in a vegetable store with storage technology in ventilated bins, they processed 20 tons of potatoes with the preparation, and the rest were placed in adjacent bins without processing.

After 3-4 months, the unprocessed potato became completely unfit for consumption, while 80% under the influence of bacteria of the intestinal group (decay) and 20% under the action of fungal microorganisms.

The potatoes processed by the preparation during this period were completely preserved.

Example 6. In order to determine the duration of preservation of the bactericidal properties of the drug on the surfaces of the shells of containers based on paper and cardboard, the preparation as a part of option 2 (see example 3) they were processed by the moistening method. The wrapping paper and box cardboard were then dried.

Surface contamination was determined one day after treatment and 10 months later.

The experiments were carried out with two test cultures: Vas. Subtitis-6633 (spore culture) and St.aureus-209P (vegetative culture) by agar diffusion on solid nutrient media by applying samples of materials treated in the form of disks in the form of discs with a diameter of 5 mm. The results of the experiments are given in table.4.

Table 4 Name of experience option The diameter of the zone (mm) lack of growth of the test culture You. Subtitis-6633 St.aureus-209P 1 day 10 months 1 day 10 months Cardboard box unilateral coating 7.0-7.5 6.5-7.0 8.0-8.5 7.5-8.0 Packaging paper (single-sided processing) 10.0-11.5 7.5-8.0 11.5-12.0 8.0-9.0 Packaging paper (double-sided processing) 11-12.5 8.0-8.5 13.0-13.5 9.0-9.5

The table shows that the treatment of the packaging material with a bactericidal agent led to a prolonged absence of bacterial growth on them.

Example 7. In order to determine the fungicidal properties, four identical vegetation vessels were taken, filled with one type of soil naturally infected with microorganisms. Three of them were treated with a preparation of various concentrations in the composition of option 1 of example 3 and at the rate of 50 ml per 1 dm ³ of soil volume with thorough mixing. The fourth vegetation vessel, the control, was watered with an equal amount of water while also thoroughly mixing the soil. In each vessel, ten simultaneously sprouted seeds of the same cucumber plant were planted. All vessels were in the same external conditions. 25 days after the emergence of seedlings, during which the soil moisture was maintained at the same level in all vegetation vessels and necessary for the development of plants, the sizes of the Fusarium lesion of the assimilation apparatus of cucumber plants were determined. The size of the plant damage (average in total) in the control vegetation vessel was taken as 100%. The results of experiments conducted for two types of soils are given in table 5.

Table 5 Type of soil Fusarium concentration on plant assimilation apparatus Low organic soil 6.7 times less than in control High Organic Soil 5.6 times less than in control

From table 5 it is seen that after soil treatment with the claimed antiseptic and fungicidal agent, the concentration of Fusarium decreased several times, therefore, there is a suppression of soil pathogenic microflora.

Thus, the presented examples indicate the presence of pronounced long-acting antiseptic and fungicidal properties of the claimed agent containing polydimethyldimethylene pyrrolidinium chloride in combination with tetramethylammonium hydroxide hydrate and (or) tetramethylethylenediamine, as well as aqueous ammonia and water.

Literature

1. USSR copyright certificate (analogue) N974653, cl. A61L 2/00, 1980.

2. USSR author's certificate (prototype) N 1069820, cl. A61L 2/16, 1984.

Claims (1)

Highly effective antiseptic and fungicidal agent with a wide spectrum of action and high duration for use in veterinary medicine, agriculture and medicine, containing polydimethyldimethylene pyrrolidinium chloride, as well as aqueous ammonia and water, characterized in that it additionally contains tetramethylammonium hydroxide hydrate and (or) tetramethylethylene diamine in the following ratio components, wt.%:
Polydimethyldimethylenepyrrolidinium chloride 0.5-3.0 Tetramethylammonium hydroxide hydrate 0.1-1.0 Tetramethylethylenediamine up to 1.0 Aqueous ammonia up to 0.5 Water Rest