CH703944A2 - Protecting aqueous system e.g. aqueous paints and varnishes, aqueous wall plaster, starch solution, and private and public swimming pools against microbial attack, comprises using polyvinylpyrrolidone complex bonded hydrogen peroxide - Google Patents

Abstract

Protecting aqueous system against microbial attack, comprises using polyvinylpyrrolidone complex bonded hydrogen peroxide, which gradually replaces water by complexing agents and develops as activated oxygen with biocidal action.

Description

The invention relates to active oxygen, complexed to PVP (polyvinylpyrrolidone) as an additive to substances that can be attacked by harmful microorganisms. Polyvinylpyrrolidone can be present in linear form (water-soluble, PVP) or in crosslinked form (water-insoluble, PVPP).

In particular, the invention is directed to H2O2 complexes of polyvinylpyrrolidones. In this five-lactam ring, amide carbonyl is a strong acceptor of hydrogen bonds. If there is an excess of water in the system, hydrogen peroxide will be deliberately released, which has a bactericidal effect.

Biocidal agents are used in many fields, for example for controlling bacteria, yeasts and fungi. It has long been known to use 4-isothiazolin-3-ones, as there are very effective biocidal compounds among them.

5-chloro-2-methyl-isothiazolone has a very good biocidal effect, but in its practical handling has the disadvantage that people often deal with it are affected by allergies. In most industrialized countries there are legal restrictions on the AOX value of industrial wastewater. Wastewater must not exceed a certain concentration of activated carbon absorbable organic chlorine, boron, and iodine compounds. This then prevents the desired use of these compounds to the extent necessary. The stability of these compounds is under certain conditions, e.g. high pH values or in the presence of reducing agents or nucleophiles sufficient.

Isothiazolones are described in various compositions and in their synergistic action. US Pat. Nos. 5,328,926, EP 1 005 271 B1, JP 01 224 306, JP 06 092 806 all descriptions do not provide any freedom from allergies or a solution of the AOX values in waste water.

With great effort, a wide range of materials has been developed which effectively prevent the growth of microbes and halt the destruction caused by microbes. Such biocidal agents include halogenated compounds, organometallic compounds, quaternary ammonium compounds, phenols, metallic salts, heterocyclic amines, formaldehyde donors, organosulfur compounds, and the like.

One of the most effective and well-known class of biocides is that of halopropynyls, especially iodopropynyl. Such compounds are widely used in the patent literature, e.g. U.S. Patents 3,660,499; 3,923,870; 4,259,350; 4,592,773; 4 616 004 and 4 639 460 just to name a few.

The invention has for its object to eliminate or control microorganisms in aqueous systems, so that the system to be protected suffers no harm without any environmentally relevant by-products or residues arise.

This object is achieved by the use of active oxygen which is released slowly and selectively by its complex binding without any environmentally harmful by-products remain or health risks arise. An addition of emulsifiers, organic solvents or stabilizers is not necessary.

The preparation of such products is described in US Pat. Nos. 5,077,047 and 5,674,462.

The biocidal efficacy of peroxydel has been reported by La Rocca Laboratories lnc. 1 Neil Court, Dumont N.J. 07628, USA, examined. The result of this investigation is attached as Enclosure 1.

The novel polyvinylpyrrolidone H2O2 complex can be used in very different fields. It is suitable, for example, for use in aqueous paints as pot preservation, cleaning, chalk slurries, lignosulfonates, surfactant solutions, cooling lubricants, adhesives, cleaning agents, cosmetic products, water cycles, proteins, latex, polymer dispersions, starch solutions, swimming pools against the infestation of bacteria, yeasts and fungi ,

In practical application Peroxydel (polyvinylpyrrolidone-H2O2 complex) can be used as a water-soluble variant Peroxydel K-30, K-90: PVP or as a crosslinked, water-insoluble variant Peroxydel XL-10: PVPP application.

Peroxydel products in water hold over a long time a constant active oxygen content in the aqueous system. The level of active oxygen content is given by the concentration of peroxydel in the system.

In all examples in which the water-soluble active ingredient (Peroxydel K-30, K-90) or the crosslinked, water-insoluble active ingredient (Peroxydel XL-10), an additional biocidal active ingredient can be used.

Example 1: Paints Canned preservatives

Water based paints are susceptible to microbial attack in the packaging containers and must be protected with biocides.

The samples were first examined for the presence of microorganisms.

The unpreserved sample showed a strong bacterial contamination with spore-forming bacteria. The water sample also showed a strong bacterial contamination. The remaining samples were germ-free.

The results are shown in Table I.

Table 1: Input vaccination

[0020] <tb> Paint Perl Color <sep> <sep> B <sep> H <sep> P <tb> 1. <sep> AM-12 without <sep> 3 * <sep> 0 <sep> 0 <tb> 2. <sep> AM-12 with 0.2% Peroxidone XL-10 <sep> 0 <sep> 0 <sep> 0 <tb> 3. <sep> AM-12 with 0.5% Peroxidone XL-10 <sep> 0 <sep> 0 <sep> 0 <tb> 4. <sep> AM-12 with 1.0% Peroxidone XL-10 <sep> 0 <sep> 0 <sep> 0 <tb> 5. <sep> AM-12 with 5.0% Peroxidone XL-10 <sep> 0 <sep> 0 <sep> 0 <tb> 6. <sep> PC painter, batch: 01166 <sep> 0 <sep> 0 <sep> 0 <Tb> 7 <sep> Water <sep> 4 <sep> 0 <sep> 0

Explanations:

B = bacteria, H = yeasts, P = molds nd = Not determined? = not evaluable, overgrown with mold fungi * = spore formers <tb> Symbol <sep> Determined Germinal Content (CFU) <sep> microbiological description of growth <tb> 4 <sep> ≥ 1000 <sep> high germ count <tb> 3 <sep> 101-1000 <sep> moderate germ count <tb> 2 <sep> 11-100 <sep> low germ count <tb> 1 <sep> 1-10 <sep> single colonies <Tb> 0 <sep> 0 <sep> sterile

Bioburden test

From the samples approaches were weighed into screw-top jars and inoculated with a mix suspension of the microorganisms listed below. A concentration of 107 germs per ml of sample was set. The inoculations were repeated twice at 7-day intervals. The samples were incubated during the experiment at a temperature of 30 ° C.

Table II Microorganisms used

[0023] <tb> Bacteria <sep> <sep> Mushrooms (yeasts & molds) <sep> <Tb> Pseudomonas aeruginosa <sep> DSM 1128 <sep> Aspergillus niger <sep> DSM 1988 <p> Pseudomonas putida <sep> DSM 291 <sep> Candida albicans <sep> DSM 1386 <tb> Escherichia coli <sep> DSM 1576 <sep> Rhodotorula mucilaginosa <sep> DSM 70825 <tb> Proteus vulgaris <sep> DSM 13387 <sep> <sep> <tb> Enterobacter aerogenes <sep> DSM 30053 <sep> <sep> <tb> Alcaligenes faecalis <sep> DSM 13644 <sep> <sep>

Results

Only the sample AM-12 without showed after all inoculations a high bacterial count> 1000.

All other inoculated samples remained germ-free.

Example 2: Wall plaster an outer wall, west direction.

1% Peroxydel XL-10 (cross-linked) used as an additive in a mortar: after one year outdoor weathering: no algae growth. Sample without peroxydel: strong algae growth.

Example 3: Chalk slurry.

Aqueous chalk slurries are used in large quantities in the paper industry, but also in the paint industry.

An addition of 0.5% peroxydel keeps such a slurry germ-free during the tested period of two months despite weekly inoculation.

Example 4: Polymer Dispersions.

An acrylate dispersion without addition of biocidal showed after three days inoculation strong germination. The sample, which was mixed with 0.5% peroxydel, remained free from staining after six weeks.

Example 5: starch solutions.

Starch solutions for paper sizing are very susceptible to microbial attack. The addition of 0.5% peroxydel keeps such a starch solution free from microbial attack for up to three weeks.

Example 6: Lignosulfonates.

Lignosulfonates are used for concrete liquefaction, but also for the production of dye suspensions. It is necessary to protect these substances from biocidal infestation. The use of peroxydel prevents the biocidal destruction of these substances.

Example 7: Surfactant solutions.

Surfactant solutions are attacked by bacteria and fungi. The use of biocides is necessary. With the help of active oxygen, supplied by Peroxydel, it is possible to stabilize these solutions over several weeks. By replenishing Peroxydel, the resistance can be extended as desired.

Example 8: Cooling lubricants.

Aqueous cooling lubricants are extremely susceptible to bacterial infestation. Active oxygen, dosed by Peroxydel, prevents the growth of bacteria and keeps the circulation bacteria-free.

Example 9: Detergent.

Detergents, especially in the hospital sector, are bactericidal equipped. Active oxygen, supplied by Peroxydel, in dosed quantities prevents any growth of bacteria.

Example 10: Cosmetic products.

In order to prevent bacterial contamination of hydrous Kosmetikas has been used inter alia, including formaldehyde. Active oxygen, delivered in correspondingly small doses from the peroxydel complex, prevents any bacterial growth.

Example 11: Water cycles.

Industrial water cycles are regularly attacked by bacteria and algae and then have to be released with biocidal aids. If active oxygen is now used in small amounts (amounts between 3 ppm to 8 ppm), these water cycles can be kept biocide-free. If a polyvinylpyrrolidone-H2O2-Complex (Peroxydel) is used, this content of active oxygen can be kept constant for weeks.

Example 12: Textile Aid Industry.

Textile auxiliaries are usually water-based and thus prone to biocidal infestation. Through the use of the polyvinylpyrrolidone-H2O2 complex, it is possible to keep these aids biocide free without using the usual biocidal agents.

Example 13: Swimming pool control.

The biocidal infestation of swimming pools is known. Various products are used to keep a pool under bacterial control. Large swimming pools can be controlled with ozone (active oxygen). There is no burden of by-products.

When the active oxygen is supplied by products which release further by-products, the pool is enriched with chemicals. However, when polyvinylpyrrolidone (cross-linked) complexed with hydrogen peroxide is used, an active oxygen content of 3 ppm to 8 ppm can be adjusted without loading the water with chemicals, which also allows smaller private pools with active oxygen to be kept biocide-free. The water remains free from any chemical stress.

Supplement 1

Report on Minimal Inhibitory Concentration Determination for Peroxydel® K-30 Solutions against Selected Microorganisms

Objective: La Rocca Science Laboratories, Inc. What contracted to determine the minimal inhibitory concentration of peroxide solutions, derived from different sources, against selected microorganisms. Peroxydel K-30 (aqueous), Peroxydel K-30 (alcoholic), & Urea (Carbamide) peroxide (aqueous), against culture controls.

Procedure:

[0041] <tb> 1. <sep> The following cultures were grown, harvested, and standardized: <tb> <sep> - Escherichia coli <tb> <sep> - Pseudomonas aeruginosa <tb> <sep> - Pseudomonas cepacia <tb> <sep> - Streptococcus pvoqenes <tb> <sep> - Staphlococcus aureus <tb> <sep> - Candida albicans <tb> <sep> - Clostridium perfrinqens <tb> 2. <sep> Three products were tested at three concentrations <tb> <sep> - Aqueous Peroxydel K-30: 3.0%, 1.5%, 0.5% H2O2 <tb> <sep> - Alcoholic Peroxydel K-30: 3.0%, 1.5%, 0.5% H2O2 <tb> <sep> - Aq. Urea (Carbamide) Peroxides: 3.0%, 1.5%, 0.5% H2O2 <tb> 3. <sep> For each test, one milliliter of diluted product and 0.1 ml of standardized culture were added to 9 ml of culture medium. Approximately 106 microorganisms were added. <tb> 4. <sep> The inoculated media was incubated for 48 hours and checked for growth. <tb> 5. <sep> Subcultures were made into fresh media from all the tubes showing no growth. <tb> 6. <sep> Culture controls were run simultaneously with the test sample.

Results: No growth found in any of the inoculated tubes containing peroxides. The results are presented in tables 1-4.

Table 1

MIC Determination for Aqueous Peroxydel K-30

La Rocca Lab no. R9-7401 <Tb> Cuiture <sep> Sample Dilution <sep> Results after 48 hours Incubation <sep> subculture <tb> Escherichia coli <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <Tb> Pseudomonas aeruginosa <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Pseudomonas cepacia <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Streptococcus <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> pyogenes <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Staphylococcus aureus <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Clostridium perfringens <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Candida albicans <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep>

Table 2

MIC Determination for Alcoholic Peroxydel K-30

La Rocca Lab No. R9-7402 <Tb> Culture <sep> Sample Dilution <sep> Results after 48 hours Incubation <sep> subculture <tb> Escherichia coli <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <Tb> Pseudomonas aeruginosa <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Pseudomonas cepacia <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Streptococcus pvogenes <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Staphylococcus aureus <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Clostridium perfrinqens <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Candida albicans <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep>

Table 3

MIC Determination for Aqueous Urea (Carbamide) Peroxides

La Rocca Lab no. R9-7403 <Tb> Culture <sep> Sample Dilution <sep> Results after 48 hours Incubation <sep> subculture <tb> Escherichia coli <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <Tb> Pseudomonas aeruginosa <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Pseudomonas cepacia <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Streptococcus <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> pvoqenes <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Staphylococcus aureus <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Clostridium perfrinqens <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep> <tb> Candida albicans <sep> 3.0% <sep> No Growth <sep> No Growth <Tb> <sep> 1.5% <sep> <sep> <Tb> <sep> 0.5% <sep> <sep>

Table 4

Culture Controls La Rocca Labs

[0046] <Tb> Culture <sep> Colony-forming Units per 0.1 ml <sep> Results after 48 hours Incubation <sep> Subculture4.2 x 10 <6> <tb> Escherichia coli <sep> <sep> Growth <sep> Growth5.3 x 10 <6> <tb> Pseudomonas aeruginosa <sep> <sep> Growth <sep> Growth4.9 x 10 <6> <tb> Pseudomonas cepacia <sep> <sep> Growth <sep> Growth6.7 x 10 <6> <tb> Streptococcus pvoqenes <sep> <sep> Growth <sep> Growth9.2 x 10 <6> <tb> Staphylococcus aureus <sep> <sep> Growth <sep> Growth2.9 x 10 <6> <tb> Clostridium perfringens <sep> <sep> Growth <sep> Growth2.4 x 10 <6> <tb> Candida albicans <sep> <sep> Growth <sep> Growth

Report Signed: Rudolph La Rocca - President La Rocca Science Laboratories, Inc.

Claims (18)

1. Schulz against microbial attack of aqueous systems, characterized in that polyvinylpyrrolidone complex bound hydrogen peroxide is used, which slowly dissolves in water from the complexing agent and developed as active oxygen biocidal effect. 2. The complex-forming polyvinylpyrrolidone can be used as a water-soluble variant (polymer chain linear, PVP) in concentrations of 0.1 to 5.0%. 3. The complex-forming polyvinylpyrrolidone can be used as a water-insoluble variant (polymer chain cross-linked, PVPP) in concentrations of 0.1 to 5.0%. The polymer can be separated again after delivery of the active oxygen. 4. protection against bacterial attack of water-based paints and varnishes according to claim 1 to 3, characterized in that between 0.1% and 5% Peroxydel is used as a pot preservation. 5. Protection against microbial attack of water-based masonry plaster according to claim 1 to 3, characterized in that between 0.1% and 3% Peroxydel is used. 6. protection against bacterial attack of water-based chalk slurries according to claim 1 to 3, characterized in that between 0.1% and 3% Peroxydel is used. 7. protection against microbial attack of polymer dispersions according to claim 1 to 3, characterized in that between 0.5% and 1% Peroxydel is used. 8. protection against germs of starch solutions for paper sizing according to claim 1 to 3, characterized in that between 0.3% and 1% Peroxydel is used. 9. protection against microbial attack of water-soluble lignosulfonates according to claim 1 to 3, characterized in that between 0.2% and 3% Peroxydel is used. 10. protection against microbial attack of aqueous surfactant solutions according to claim 1 to 3, characterized in that between 0.1% and 2% Peroxydel is used. 11. protection against microbial attack of water-based cooling lubricants according to claim 1 to 3, characterized in that between 0.2% and 5% Peroxydel is used. 12. protection against microbial attack of water-based cleaning agents according to claim 1 bi 3, characterized in that between 0.1% and 3% Peroxydel is used. 13. protection against microbial attack of water-based cosmetics according to claim 1 to 3, characterized in that between 0.1% and 3% Peroxydel is used. 14. Protection against microbial contamination of water circuits such as cooling water according to claim 1 to 3, characterized in that between 0.1% and 4% Peroxydel is used. 15. Protection against germ attack of cleaning water in the printing industry according to claim 1 to 3, characterized in that between 0.1% and 3% Peroxydel is used. 16. Protection against germs of products of the detergent industry according to claim 1 to 3, characterized in that between 0.1% and 4% Peroxydel is used. 17. Protection against microbial attack of aqueous aids of the textile industry according to claim 1 to 3, characterized in that between 0.2% and 3% Peroxydel is used. 18. Protection against germs of private and public swimming pools according to claim 1 to 3, characterized in that between 0.2% and 5% Peroxydel is used.