Аннотация и ключевые слова
Аннотация (русский):
An analysis of literature sources and own research devoted to the study of disinfection properties of disinfectants based on cationic surfactants (CS), oxygen-active compounds, and halogens is presented. It has been established that the greatest disinfection activity of them is possessed by iodine complex compounds. Hydrogen peroxide is inactive against such resistant parasitic objects as ascarid eggs. It was also established that, as a result of studying the antiparasitic properties of drugs, for each group of disinfectants, disinfectants with the most pronounced disinfection effect were determined. Of the drugs based on CS, these are "B-des" and "Brovadez-plus", of oxygen-active drugs – "Chlorine Dioxide", of chloractive drugs – "Glavchlor Extra" and "DP-2T", and of iodine-active drugs – "Povidone- iodine" and "Pharmadez".

Ключевые слова:
disinfectants, cationic surfactants, oxygenated compounds, halogens, geohelminthiasis, ovicidal effect
Текст
Текст произведения (PDF): Читать Скачать

Parasitic diseases are widespread in the world. According to the WHO, every fourth inhabitant of the Earth is a carrier of this or that parasite. Intestinal helminthiases are considered to be the most dangerous diseases, it is believed that they occupy the 4th place in damage to human health, in comparison with other pathologies. More than 2 billion people in the world are affected by geohelminthiases [1-3].

According to various sources, on the territory of Russia and the countries of the Near Abroad, from 60 to 70 species of helminths have been found, of which about 20-30 species are most common. In the country, 2 million patients are detected annually, however, taking into account the correction factors, the true number of them may exceed 20 million [4, 5]. Of helminthiasis, in terms of the frequency of registration among the population of Russia, enterobiasis is in the first place, and 90-95% of the patients are children. Significant circulation of the causative agent of this disease occurs in preschool, school and health care institutions. The second place is occupied by ascariasis [6-8]. The problem of toxocariasis deserves serious attention, especially in megacities. The spread of this disease is associated with an increase in the number of dogs in cities and non-observance of the rules for keeping them in the absence of measures for excrement disinfection [6-10].

The constant detection of parasitic pathogens in the environment indicates the insufficient effectiveness of disinfection measures [6, 11, 12]. In the complex of measures for disinfestation of objects of the external environment, the use of chemical agents plays an important role. However, today the range of such products is very small. Of the huge variety of disinfectants known today, only a small part is suitable for disinfestation. In addition, not all of them have such properties as a wide spectrum of action, ease of preparation, reliability of the disinfecting effect. Therefore, the search and development of new drugs with a strong antiparasitic effect remains a very important direction in the protection of the environment from contamination with invasive material and the prevention of parasitic diseases [13-17].

According to literary sources and our own research, a comparison was made of the antiparasitic activity of 28 disinfectants.

The purpose of the work is to study the physicochemical, antimicrobial, antiparasitic and disinfecting properties of various disinfecting compositions from literary sources.

 

1 Antiparasitic activity of disinfectants based on cationic surfactants (CS)

The most important representatives of CS are quaternary ammonium compounds (QAC), guanidine derivatives and tertiary amines. Table 1 shows the ovicidal efficacy of 6 disinfectants based on these compounds against the eggs of 8 types of helminths. Of these, 7 are representatives of the Roundworm type, suborders Ascaridata (Neoascaris  vitulorum, Ascaris suum, Parascaris equorum, Ascaridia galli, Toxocara canis, Toxocara cati) and Strongylata (family Trichostrongylidae, Nematodirus sp.), and 1 –  is a representative of the Flatworm type, class Cestodes (Taenia sp.). Analyzing the indicators of ovicidal action, we can say that preparations based on QAC are not very active against ascarid eggs. They show a pronounced effect in concentrations of at least 10% with prolonged exposure of 12-24 hours [2, 3]. The drug "GABO" showed in our experiment a strong effect (ovicidal efficiency 100%) with a shorter exposure of 4 hours, but in a high concentration of 25%. On the example of the action of the drug "Aminocid" there is a noticeable difference in the sensitivity of the test objects to the action of disinfectants. This preparation, with an exposure time of 12-24 hours, was effective against Trichonema sp. (family Trichonematidae, suborder Strongylata) at a concentration of 5-10%, caused the death of eggs of Toxocara cati at a concentration of 10% and had no effect on the eggs of Taenia sp. (class Cestoda) [4].

Table 1 – Antiparasitic activity of CS-based disinfectants

 

Drug, composition of the drug

Test-object

Exposure time

Drug concentration

Disinfection efficiency

Sourse of information

Samarovka: Alkyldimethylbenzylammonium chloride;

Alkyldimethylethylbenzylammonium chloride                                                    

Neoascaris  vitulorum,

 Ascaris suum,          Parascaris equorum, Ascaridia galli

24 hours

10 %

60-80 %

2

Ecosan:

Alkyldimethylbenzylammonium chloride; Alkyldimethylethylbenzylammonium chloride

Toxocara canis

24 hours

10 %

60 %

3

Encke Mod:

Quaternary ammonium compounds, own research

Ascaris suum

4 hours

25 %

100 %

OR

24 hours

12 %

90 %

Septa:

Alkyldimethylbenzylammonium chloride; Didecyldimethyl ammonium chloride

Ascaris suum

4 hours

100 %

11 %

OR

24 hours

100 %

99 %

Aminocide:

Alkyldimethylbenzylammonium chloride; N, N-bis (3aminopril) dodecylamine; Didecyldimethyl ammonium chloride

Trichonema sp.

12-24 hours

5-10 %

100 %

4

Toxocara cati

12-24 hours

10 %

 

100 %

Taenia sp.

12-24 hours

10 %

Absent

Brovadez:

Dimethyldialkyl ammonium chloride; Didecyldimethyl ammonium chloride; EDTA

Ascaris suum

1 hour

1,5 %

92 %

6

Trichuris suis

1 hour

1,5 %

78 %

Bi-des:              

Dodecyldipropylene triamine; Polyhexamethylene guanidine (PGMG-x); Cocoamidopropyl Betaine (surfactant); Glutamic acid

 

Toxocara canis

1 hour

0,3 %

61 %

5

1 %

95 %

Ascaris suum

1 hour

1 %

98 %

6

Trichuris suis

1 hour

1 %

79 %

These data indicate a relatively higher chemical sensitivity of Trichonema eggs compared to Toxocara eggs and a higher resistance of cestode eggs compared to these species. Of all the considered CS-based disinfectants, the "B-des" and "Brovadez-plus" preparations showed the highest ovicidal activity. The composition of the preparation "Bi-des" includes such representatives of CS as triamine and a guanidine derivative as the main components. In relation to eggs of a fairly stable species Toxocara canis, this drug showed a pronounced effect at a concentration of 0.3% at exposure time

1 hour [5]. It is interesting to compare the effect of the drug "Bi-des" in the same experimental conditions (1%; 1 hour) on the eggs of 3 species of nematodes. The effect of the drug on ascaridate eggs (Ascaris suum and Toxocara canis is approximately the same (the death of eggs is 98% and 95%, respectively), and the eggs of the whipworm (Trichuris suis) were more resistant (79%) [5, 6]. "Brovadez-plus" in addition to two representatives [2, 3] QAC includes EDTA, a representative of chelating agents that form strong intracomplex compounds (chelates) with metal ions. At a concentration of 1% with an exposure time of 1 hour, its ovicidal efficacy against Ascaris suum and Trichuris suis eggs was 85% and 77%, respectively [6].

 

2 Antiparasitic activity of disinfectants based on oxygen-active compounds

Table 2 shows data on the effect on helminth eggs of such oxygen-active compounds as hydrogen peroxide, potassium permanganate, chlorine dioxide, as well as three disinfectants based on hydrogen peroxide and other peroxide compounds.

Table 2 Antiparasitic activity of disinfectants based on oxygen-active compounds

Drug,

composition of the drug

Test-object

Exposure time

Drug concentration

Disinfection efficiency

Sourse of information

Hydrogen peroxide

Toxocara canis

60 minutes

30 %

Absent

3

20 days

6 %

Absent

7

Ascaris suum

4 hours

33 %

Absent

OR

24 hours

33 %

73 %

Peroxam Ultra:

Hydrogen peroxide

Ascaris suum

24 hours

100 %

100 %

OR

50 %

11 %

Desolex:

Hydrogen peroxide

Ascaris suum

24 hours

100 %

100 %

OR

50 %

35 %

Manganese-sour potassium

Toxocara canis

1 hour

30 %

Absent

3

Virkon:

Potassium peroxomonosulfate; Surfactant; organic acids)

Trichonema sp.

12-24 hours

5-10 %

100%

 

4

Toxocara cati

12-24 hours

10 %

100%

Taenia sp.

12-24 hours

10 %

Absent

Chlorine dioxide

Ascaris suum

4 hours

0,25 %

90 %

OR

24 hours

0,06 %

100 %

 

First of all, it should be noted the low efficiency of hydrogen peroxide against helminth eggs. At a concentration of 6%, usually destructive for microbiological objects, peroxide did not affect the development of eggs of Toxocara canis at all. On the 9th day, larvae formed in them, which did not lose their viability until the end of the experiment for 20 days [7]. Even in a concentrated state (30%), hydrogen peroxide does not act on eggs of Toxocara canis at an exposure time of 1 hour [3]. In our experiments, hydrogen peroxide at a concentration of 33% did not have a detrimental effect on the eggs of Ascaris suum at an exposure time of 4 hours and showed a pronounced effect on the eggs of this object only after an exposure of 24 hours (73%). Preparations based on hydrogen peroxide "Peroxam Ultra" and "Dezolex" in undiluted form with an exposure time of 24 hours had a strong ovicidal effect on Ascaris suum eggs (OE 100%), but after dilution by 2 times their effect became weak (OE 11-35 %). The preparation "Virkon" with an exposure time of 12-24 hours was effective against eggs of Trichonema sp. at a concentration of 5-10%, against eggs of Toxocara cati - at a concentration of 10% and is ineffective against eggs of Taenia sp. at this concentration [4]. Potassium permanganate at a concentration of 40% after 1-hour exposure did not affect the further development of Toxocara canis eggs [3]. Chlorine dioxide has the strongest ovicidal effect of the considered oxygen-active compounds. In our experiments, it was active against Ascaris suum eggs at a concentration of 0.25% at an exposure time of 4 hours (90%) and caused the death of 100% of the eggs at a concentration of 0.06% at an exposure time of 24 hours.

3 Antiparasitic activity of disinfectants based on chloroactive compounds

Table 3 shows the data on the ovicidal activity of chloractive disinfectants made on the basis of sodium hypochlorite, trichloroisocyanuric acid (TCA) and sodium salt of DCCA. According to the available literature data, Toxocara canis eggs died from the action of a hypochlorite solution with an active chlorine (ACh) content of 9-16% within 30 minutes [3]. At the same time, when testing commercial drugs such as "Comet" gel ("Double effect"), "Bleach" and "Domestos", it took much longer to achieve a similar effect - from 15 to 48 hours [8]. Of all the considered disinfectants based on sodium hypochlorite, the most active drug is "Glavkhlor Extra". As our studies have shown, from its action at a concentration of 0.45% (hereinafter, the concentration is given as active chlorine (ACh), complete elimination of Ascaris suum eggs occurred within 2 hours. Comparison of the ovicidal effect of sodium hypochlorite disinfectants suggests that it is not directly related to the ACh level in the preparations. The same conclusion can be reached by comparing the effectiveness of drugs based on isocyanuric acids and their derivatives. The ovicidal effect of disinfectants varies widely, although the reported ACh levels are approximately the same. Thus, our studies of the ovicidal activity of 4 preparations based on the sodium salt of DCCA showed the following. There is no activity of "Astera" (43% ACh content) tested at a concentration of 3% with an exposure time of 4 days against Ascaris suum eggs. In relation to the same object, the effectiveness of the drug "Pharmachlor" (ACh content 41%) at a concentration of 8% with an exposure time of 1 day was only 17%. The ovicidal efficacy of "Nika Chlor" (ACh content 45.5%) and "Nika Chlor Lux" (ACh content 42%) against Toxocara canis eggs tested at a concentration of 10% at an exposure time of 1 day was quite high and amounted to respectively, 92% and 85%. According to literary sources, the preparation "Javel Absolute" (sodium salt of TCA, content of ACh 43%) in 12-24 hours caused destruction and death of eggs of nematodes of the genus Trichonema at a concentration of 5-10%, as well as eggs of Toxocara canis and Taenia sp. - at a concentration of 10% [4]. The drug "DP-2T" based on TCA (32% ACh) is very active against the eggs of parasitic nematodes. It causes death of Toxocara canis eggs at a concentration of 5% (according to the preparation) with an exposure time of 24 hours [9], and Nematodirus sp. - at a concentration of 0.06% in 30 minutes [10].

Table 3 Antiparasitic activity of disinfectants based on chloroactive compounds

Drug, composition of the drug

Test-object

Exposure time

Drug concentration

Disinfection efficiency

Sourse of information

Sodium hypochlorite

Toxocara canis

30 minutes

9-16 % by ACh

100 %

3

Bleach: Sodium hypochlorite;
Sodium hydroxide; Surfactant

 

Toxocara canis invasive eggs

48 hours

4,8-14,3 %     by ACh

100 %

8

Gel "Comet Double Effect":

Chlorinol; Formic acid; Phosphoric acid

Toxocara canis invasive eggs

15-24 hours

100 % by drug

100 %

 

 

Domestos: Sodium hypochlorite;
Surfactant

Toxocara canis invasive eggs

48 hours

4,8 %  by ACh

100 %

Glavkhlor Extra: Sodium hypochlorite

 

Ascaris suum

1 hour

0,45 % by ACh

95 %

OR

2 hours

0,45 % by ACh

100 %

Astera: Dichloroisocyanuric acid sodium salt

Ascaris suum

4 days

3 % by ACh

Absent

OR

Farmahlor:

Dichloroisocyanuric acid sodium salt

Ascaris suum

24 hours

8 % by ACh

16 %

OR

Nika Chlor:Dichloroisocyanuric acid sodium salt

Toxocara canis

23 hours

10 %
by ACh

91 %

OR

Nika Chlor Lux: Dichloroisocyanuric acid sodium salt; Surfactant

Toxocara canis

23 hours

10 %
by ACh

87 %

OR

Javel Absolute:

Dichloroisocyanuric acid sodium salt

 

Trichonema sp.

12-24 hours

2- 4,3 % by ACh

100 %

4

Toxocara cati

12-24 hours

4,3 % by ACh

100 %

Taenia sp.

12-24 hours

4,3 % on ACh

100 %

DP-2T:Trichloroisocyanuric acid; Surfactant (sulfonol)                     

 

Nemato-dirus sp.

30 minutes

0,06 % by ACh

 100 %

10

                 

 

4 Antiparasitic activity of disinfectants based on iodine active compounds

The antiparasitic activity data shown in Table 4 indicate the high efficacy of iodine-based preparations. So the preparations "Cystodesis" and "Paradesil" containing crystalline iodine, at a concentration of 3-4%, destroy 94-100% of Buxtonella sulcata cysts within 2 hours. The drug "Paradizel" also works in relation to oocysts of Eimeria sp., And in relation to eggs of Ascaris suum, the same level of its effectiveness is achieved after exposure for 24 hours [11, 12]. The disinfection activity of disinfectants based on iodine complex compounds is even higher. The preparations "Pharmayod and" S-280 "at concentrations of 1-5% (by drug) cause the death of 100% of the eggs of such a stable object as Ascaris suum within 1-3 hours [13]. The drug "Pharmades", which includes pharmaco, is highly effective against all pathogens of parasitic diseases and is recommended as the main disinfectant for disinfecting contaminated objects [14]. In our experiments, "Pharmadez" caused the death of 100% of pork roundworm eggs at a concentration of 0.03% for active iodine (hereinafter I) within 2 hours, and within 24 hours - at a concentration of 0.002%. The drug "Povidone-iodine" was even more active. Its ovicidal efficiency at a concentration of 0.005% according to AI with an exposure time of 2 hours was 64%, and at a concentration of 0.0006% with an exposure time of 24 hours - 100%.

Table 4 Antiparasitic activity of disinfectants based on iodine active compounds

Drug, composition of the drug

Test-object

Exposure time

Drug concentration

Disinfection efficiency

Sourse of information

Cystodesis:

Crystalline iodine; Glutaraldehyde; Ethanol%; Potassium iodide;PEG-400                          

Buxtonella sulcata

2 hours

3 % by drug

98 %

11

4 % by drug

100 %

Paradesil:

Crystalline iodine;

Potassium iodide;

Glutaraldehyde;

PEG-400; Ethanol                                    

Ascaris suum

24 hours

3 % by drug

94 %

12

4 % by drug

100 %

Buxtonella sulcata

2 hours

3 % by drug

94 %

Eimeria sp.

2 hours

3 % by drug

93 %

Pharmayod:

Iodophor

Ascaris suum

3 hours

1 % by drug

100 %

13

S-280:

Iodophor

Ascaris suum

1 hour

5 % by drug

100 %

13

Pharmades:

Pharmayod;
Sodium lauryl sulfate;
Syntanol;                                                    

Ascaris suum

1 hour

0,03% by DV (5% for the drug)

100%

     14

2 hours

0,03% by DV

100%

OR

0,008% by DV

96%

4 hours

0,002% by DV

73%

24 hours

0,002% by DV

100%

Povidone iodine:

Povidone iodine; Glycerol; Nonoxynol; citric acid, etc.                                        

Ascaris suum

2 hours

 

 

0,0005- 0,005%  by DV

64%

 

 

OR

24 hours

0,0006%
by DV

100%

 

 

Conclusion

From literary sources, the disinfection properties of disinfectants based on CS, oxygen-active compounds, and halogens have been established. Complex compounds of iodine have the greatest disinfection activity of them. As a result of studying the antiparasitic properties of drugs, for each group of disinfectants, disinfectants with the most pronounced disinfection effect were determined. Of the drugs based on CS, such are "B-des" and "Brovadez-plus", of oxygen-active drugs – "Chlorine Dioxide", of chlorine-active drugs – "Glavchlor Extra" and "DP-2T", and of iodine-active drugs – "Povidone-iodine" and "Pharmades", from drugs that include aldehydes - "Cystodes-ultra", "DZPT-1" and "DZPT-2".

Список литературы

1. MUK 4.2.2661-10. Methods of sanitary and parasitological research: approved by the Chief State Doctor of the Russian Federation on July 23, 2010: introduced instead of MUK 4.2.796-99

2. Dolbin, D.A. Analysis of the effectiveness of the use of modern means for disinvasion / D.A. Dolbin, R.Z. Khairullin // Bulletin of the Kazan Technological University. - 2015. - V.18, №1 6. - P. 314-315.

3. Masalkova, Yu.Yu. Disinfection activity of chemicals and drugs in relation to eggs Toxocara canis // Veterinary medicine. - 2016. - № 3. - P. 30-33.

4. Neprimerova, T.A. Ovocidal and larvocidal properties of some disinfectants / T.A. Neprimerova, T.N. Sivkova // Materials of reports of the international scientific conference "Theory and practice of combating parasitic diseases". - Moscow, 2012. - Iss. 13. - P. 277-280.

5. Stibel, V.V. Influence of the disinfectant "Bi-des" on the embryogenesis of Toxocara canis / V.V. Stibel, O.B. Priyma, N.N. Danko, O.A. Svarchevsky // Scientific Bulletin of LNUVMB im. S.Z. Gzhitsky. - 2016. - V. 18, № 1 (65), part 1. - P. 177-181.

6. Yuskiv, I. D. The effectiveness of using various test cultures of helminth eggs to establish the disinvasive properties of chemical agents // Bulletin of the Poltava State Agrarian Academy. - 2015. - № 4.

7. Pautova, E.F. Effect of disinfectants on Toxocara canis eggs (results of experimental studies) / E.F. Pautova, A.S. Dovgalev, L. D. Shchuchinova, L.V. Alyautdin // Med. parasitol. - 2013. - № 4. - P. 27-29.

8. Shchuchinova, L. D. Effect of household chemicals on the invasive eggs of Toxocara canis / L.D. Shchuchinova, E.A. Pautova, A.S. Dovgalev // Med. parasitol. - 2013. - № 4. - P. 30-32.

9. Pautova E.A. Epizootological, epidemic and ecological aspects of toxocariasis in the Altai Republic: specialty 03.02.11 "Parasitology": dissertation for the degree of candidate of biological sciences / Elena Anatolyevna Pautova; Gorno-Altai State University. - Gorno-Altaysk, 2016. - 179 P.

10. Lutfullin, M.Kh. Ovocidal effect of chemotherapy on eggs of nematodes of the Strongylata suborder / M.Kh. Lutfullin, N.A. Lutfullin, D.A. Dolbin // Scientific Notes of the N.E. Bauman Kazan State Academy of Veterinary Medicine. - 2015. - V. 224, № 4. - P. 122-125.

11. Safiullin, R.T. Disinfection of environmental objects against cysts of parasitic protozoa (Buxtonella sulcata) of cattle / R.T. Safiullin, S.K. Shibitov // Russian parasitological journal. - 2019. - V. 13, Iss. 1. - P. 64-74.

12. Patent № 2727519 Russian Federation, IPC A61L 2/18, A01N 25/02, A01N 59/12, A61L 101/06, A61L 101/36. Means for disinfestation of objects of the external environment: № 2020107067: apl. 16.02.2020: pub. 22.07.2020 / Shibitov S.K.; patentee of Scientific Center for Veterinary Parasitology and Therapy LLC.

13. Novikov, N.L. Development of means and methods for disinfecting livestock buildings from pathogens of invasive and infectious diseases: specialty 03.00.19 "Parasitology": dissertation for the degree of candidate of veterinary sciences / Novikov Nikolai Leonidovich; All-Russian Scientific Research Institute of Helminthology named after K.I. Scriabin. - Moscow, 2004. - 145 P.

14. SP 1.3.2322-08. Sanitary and Epidemiological Rules. Safety of work with microorganisms of III-IV groups of pathogenicity (danger) and pathogens of parasitic diseases. approved and put into effect from May 1, 2008 by the Decree of the Chief State Doctor of the Russian Federation of January 28, 2008 № 4.

15. Patent № 2748168 Russian Federation, IPCA01N 25/02, A01N 33/04, A01N 35/02. Means for disinfestation of objects of the external environment: № 2020129699: apl. 09.09.2020: pub. 20.05.2021 / Safiullin R.T., Arisov M.V., Shibitov S.K.; patentee FSBSI FSC AIEV RAS.

16. Dakhno, I.S. Screening of preparations for disinvasion of environmental objects / I.S. Dakhno, Yu.V. Negreba, G.F. Dakhno // Materials of reports of the international scientific conference "Theory and practice of combating parasitic diseases". - Moscow, 2010. - Iss. 11. - P. 144-147.

17. Dolbin, D.A. Resistance of helminth eggs to unfavorable physical, chemical and biological factors of the environment (literature review) / D.A. Dolbin, R.Z. Khairullin // Russian Journal of Parasitology. - 2017. - V. 39, Iss. 1. - P. 14-19.

Войти или Создать
* Забыли пароль?