PT105240A - PROCESS OF OBTAINING AND USING PORCELAIN GRAINS WITH ANTI-MICROBIAL ACTION - Google Patents

Abstract

The present invention relates to the process of obtaining porcelain grains with anti-bacterial action, or whether it promotes the death of bacteria without impairing other important characteristics of the product, in particular the high chemical resistance and the anti-staining properties. THIS PRODUCT IS OBTAINED FROM A PORCELAIN GRASS PASTE WITH 2.5% (BY WEIGHT) OF BLACK CERAMIC PIGMENT CONTAINING CHROMIUM AND IRON IN ITS COMPOSITION, APPLICATION BY SPRAYING A SMALL QUANTITY OF TRANSPARENT GLASS (NORMALLY USED TO IMPROVE THE CHARACTERISTICS SURFACES OF THE MATERIAL) AND COOKING WITH THE NORMALLY USED CYCLE FOR THESE PRODUCTS. AFTER COOKING A CHEMICAL TREATMENT (SOLUTION WITH SODIUM NITRATE AND SILVER NITRATE) AND THERMAL (430ºC) is carried out. AFTER OPTIMIZATION A MATERIAL WITH HIGH ANTIBACTERIAL ACTION IS OBTAINED: AN EFFECTIVENESS, OR A% BACTERIA REDUCTION, OF 77% FOR THE S. AUREUS BACTERIA AND 81% FOR THE E. COLI BACTERIA, A SURVIVAL RATE (100-% R) OF THESE BACTERIA ONLY ABOUT 20%.

Description

1

DESCRIPTION

PROCESS OF OBTAINING AND USING PORCELAIN GRAIN WITH

The present invention relates to the process of obtaining porcelain stoneware with anti-bacterial action, i.e., which promotes the killing of bacteria without detriment to other important characteristics of the product, namely the high chemical resistance and the anti- spot. The antibacterial action, proven by determining the survival rate of the Gram-positive bacteria, Staphylococcus aureus, and Gram-negative, Escherichia coli is achieved through the use of a ceramic pigment and a chemical and thermal treatment. The anti-microbial effect achieved only works when the bacteria are in direct contact with the ceramic pieces.

Since the pigment used is normally used in this type of products to achieve aesthetic effects, the increase in the cost of this material with anti-bacterial properties comes only from the costs associated with chemical and thermal treatment. The developed product has anti-stain characteristics, belonging to class 5 (ISO 10545-14) and is chemically resistant, being classified by ISO 10545-13 as UA, ULA and UHA for all tested 2 chemical agents except for solution of hydrochloric acid, 18% (v / v), which promotes a slight chemical attack on its surface (UHB).

BACKGROUND OF THE INVENTION

List of documents found N. Kalantari, S. Ghaffari, Evaluation of toxicity of heavy metals for Escherichia coli growth, Iran. J. Environ. Health. Know. Eng., 5, (3), 173-178, 2008. R. Narayanan, M.J. Mchale, Antimicrobial glaze and acid resistant porcelain for enameled Steel producets, WO / 2006/133075. I. Birky, J.V. Wood, Monolithic ceramic material comprising an antimicrobial material, WO 0014029, 2000. I. Akira, T. Mitsuo, I. Rie, Antibacterial ceramic product and its production, JP 8290985, 1996. N. Hiroshi, A. Kiminori, S. Muniteru , Antimicrobial calcium phosphate based ceramics, JP 4288006, 1992. S. Shuji, A. Kiminori, F. Keijiro, Inorganic antimicrobial agent and production thereof, JP 4013605, 1992.

state of art

Pathogens are present in a wide range of applications, from the domestic, school, antibacterial surfaces, bacterial growth, and are very attractive to a wide range of hospital environments up to and including ...

Ceramic materials are widely used in the interior finish of buildings, so the development of ceramic floors and coatings with anti-bacterial properties is a significant asset.

Taking into account the technical characteristics of porcelain stoneware, in particular its very low porosity and high chemical resistance, this product is suitable for developing this functionality. The anti-bacterial effect of silver has been known since antiquity. Greco-Roman civilizations, on the other hand, found that algae did not develop in copper and silver containers containing water for human consumption, unlike clay vessels.

This action was named by Pelkzar et al. [1] as an oligodynamic effect and was defined as the ability of small amounts of certain metals to exert a lethal effect on bacteria.

One of the issues of environmental and health concern is the toxicity of heavy metals.

However it has been shown that for macroscopic life forms, silver is the least toxic element and does not exhibit any contraindication when used 4 at low concentrations [2].

On the contrary, silver and osmium are the most toxic elements for microscopic beings because fungicide, within the same group of the periodic table, increases with the increase of atomic weight [3].

Due to its intense anti-bacterial activity silver and its salts are used in the treatment of water or placed in organic matrices for diversified uses, from clothing to medical and surgical devices [4].

The mechanisms of the anti-bacterial action of silver ions are closely related to the thiol group (sulfhydryl-SH) [3-4], which consists of proteins, which in turn are responsible for the enzymatic activity. The addition of silver ions to a medium containing bacteria causes the release of the phosphate ions from the bacteria.

Thus, the plasma of the bacterium or its cytoplasmic membrane, which is associated with important enzymes, becomes a target for the silver ions [5].

The effects caused by the addition of silver ions to bacterial E. coli enzymes are inhibition of bacterial growth and deposition of silver ions in the voids and cell walls as precipitates [6]. The cell of the bacterium increases in size and the cytoplasmic membrane, the cytoplasmic content and other 5 layers of the cell have anomalies in the structure.

Finally, the silver ions interact with the nucleic acids, causing the bacterium to lose its reproductive capacity and, therefore, is limited to its proliferation [6].

In the case of S. aureus bacteria the addition of silver ions also causes damage. The walls and membranes separate, which results in the release of their cellular content in the surrounding environment.

There is also a decrease in the density and heterogeneity of the cytoplasm. It is common to find dense or precipitous particles around the damaged cells. Chromium ion is considered biologically important for all levels of living organisms; in particular the trivalent chromium plays an important role in controlling the metabolism of carbohydrates and lipids in cells [7].

Although inhibiting bacterial growth and decreased pathogenicity, the chromium ion may interact with iron in the metabolism of living organisms [8]. Iron is an essential nutrient for life forms because of its activity in the transport of electrons in the reactions of biological systems. 6

However, their insolubility and reactivity, respectively, lead to problems of availability and toxicity in bacteria cells [9].

Elevated amounts of iron are extremely toxic and can lead to anti-bacterial effects [8].

Kalantari and Ghaffari [8] evaluated the influence of chromium and iron on the growth of E. coli bacteria, and found that the presence of the Cr3 + ion has an inhibitory effect, which can reduce it to 38% (solution with a concentration of ions 0.5 mM chromium / L).

In a culture of E. coli bacteria, the addition of solutions with high concentration of iron ions (1 mM / L) promotes a reduction of their growth. Fe (III) reduced it to 31.3% and Fe (II) completely inhibited it [8].

These authors further verified that the joint action of iron and chromium ions is extremely effective in inhibiting the growth of E. coli. The addition to the culture medium of a 0.1 mM / L solution of Fe 3+ and Fe 2+ and 0.5 mM / L Cr 3+ promotes a dramatic inhibition of bacterial growth, which is only 8%.

Thus, high concentrations of Fe2 + inhibit the growth of bacteria; chromium, although only partly inhibitory when acting alone, combined with iron becomes lethal to E. coli because the 7-chromium salts will promote the precipitation of the iron inside the cell, causing its death.

References: [1] RJ Luckens, Structure activity relationship, In Kleinzellar, A., Springer, GF, Wittmann HG (ed.), Molecular Biology, Biochemistry and Biophysics, Chemistry of Fungicidal Action, Springer-Verlang, New York, 76-90, 1971.

[2] A. Goetz, Water sanitation with silver. J. American Water Works Association, 35, 579-584, 1943.

[3] M. J. Pelkzar et al. Microbiology: Concepts and

Applications, São Paulo: MAKRON Books do Brasil, 2, 517, 1996.

[4] A. Tucci, A. Nanetti, L. Malmusi, G. Timellini,

Ceramic surfaces with bacteriological action for hospital environments, Cerâmica Industrial, 12, 7-10, 2007.

[5] W.J. Schreurs, H. Rosenberg, Effect on silver ions on transport and retention of phosphate by Escherichia coli, J. Bacteriol., 152, 7-13, 1982.

[6] W.K. Jung, H.C. Koo, K.W. Kim, S. Shin, S.H. Kim, Y.H. Park; Antibacterial activity and mechanism of action of the silver ion in Staphylococcus aureus and Escherichia coli, Appl. Environ. Microbiol., 74 (7) 2171-2178, 2008. 8 [7] V. Juturu, J. R. Komorowski, Chromium supplements, glucose and insulin responses, Am. J. Clin. Nutr., 78 (1) 192-193, 2003.

[8] N. Kalantari, S. Ghaffari, Evaluation of toxicity of heavy metals for Escherichia coli growth, Iran. J. Environ. Health. Know. Eng., 5 (3) 173-178, 2008.

[9] S. C. Andrews, Iron storage in bacteria, Adv. Microb. Physiol., 40, 281-351, 1998.

Differences between the published works and the present invention The anti-bacterial effect of silver, chromium and iron is known and the existence of ceramic material with anti-bacterial properties is already a reality.

However this work is innovative because the antibacterial effect of chromium and iron was only tested in solution with no report of its application to the ceramic materials which have the peculiarity of being subjected during processing to elevated temperatures (1200 ° C), which promote densification of the material and the occurrence of chemical reactions.

In this invention advantage is taken of the fact that these metal elements form part of the composition of ceramic pigments which are normally used to color the porcelain stoneware pastes.

Other ceramic pigments, used to obtain porcelain stoneware with other colors, may also confer 9 anti-bacterial properties to the ceramic material. The currently available anti-bacterial ceramic material was developed by an Italian group (Fiandre and Iris Ceramic) (Active Clean Air & Anti-Bacterial Ceramic - http://www.active-ceramic.com/; PCT / IB2009 / 006002).

In this product the anti-bacterial effect comes from the presence, on the surface of the product, of a material with photocatalytic properties: T1O2.

Thus, for the material to exhibit anti-bacterial properties it needs radiation.

In the present invention it is only necessary that the bacteria be in direct contact with the material.

DESCRIPTION OF THE INVENTION The name of porcelain stoneware is sufficient to define the origins and characteristics of this product.

In ceramic terminology, stoneware is synonymous with a very compact material consisting of several crystalline phases dispersed in a glassy matrix. The adjective porcelanato has an etymological root in the term porcelain. According to ISO 10545-3 this type of material has a water absorption of less than 0.5%. However, most manufacturers rely on products with even lower water absorption (< 0.05%). 10

Thus, this material does not require a glaze to waterproof its surface and it can be polished if a shiny surface is desired.

Another important feature of this product is that even if abrasion occurs, although its abrasion resistance is quite high, there is no discontinuity of its characteristics because there is no distinct surface part of the inner part. The novelty of this product comes from the fact that allied to the ancestral knowledge of the anti-bacterial effect of some heavy metals, namely silver, iron and chromium, to a relatively recent ceramic product, porcelain stoneware which has excellent technical characteristics .

This material is suitable for indoor or outdoor applications, high traffic sites, etc. The antimicrobial effect of the material with the addition of only 2.5% (by weight) of black ceramic pigment translates into a 51% efficacy for E. coli bacteria. The increase to 81% comes from the treatments: chemical (with silver salts) and thermal.

In any case, the use of the ceramic dye alone already reduces the amount of E. coli bacteria by half, without any extra cost in the case of black porcelain stoneware material. 11

Example

Materials:

Porcelain stoneware paste (composition%): 66.20% SiO2; 19.42% A1203; 1.06% Fe203; 0.65% CaO; < 0.50% MgO; 2.02% Na 2 O; 2.36% K20; 0.38% TiO2; < 0.30% MnO; > 0.50% P205. Black ceramic pigment (2.5% by weight), whose average composition, estimated by Scanning Electron Microscopy / X-ray Dispersive Energy Spectroscopy (SEM / EDS), is (atomic%): chromium 36.8%; iron 44.2%; aluminum 8.8%; 6.0% magnesium; 0.8% titanium; and 3.4% oxygen. - Transparent commercial glass consisting of a single crystalline phase [estimated by X-ray Diffraction (XRD)] - Ba0.8 (Al1.6Si2.4Os) · Its chemical composition is (% by weight): 47.2% SiO2; 16.8% A1203; 24.3% BaO; 5.4% CaO; 6.3% Na2 0.

After forming and drying the material, the clear commercial glaze as an aqueous suspension was sprayed onto the material (about 130 g / m 2 with a density of 1280 g / L). Its main function is to fill the microporosity on the surface of the parts in order to improve stain resistance. The material was then baked in an industrial roller kiln with a cycle of 90 minutes and a maximum temperature of 1210 ° C. 12

After firing, about 20 g / m 2 of an aqueous solution with 98% sodium nitrate and 2% silver nitrate (percentages by weight) were also sprayed.

Thereafter the material was subjected to a heat treatment at 430 ° C.

Evaluation of bacterial reduction:

Two bacterial strains were used in this evaluation: Staphylococcus aureus (NCTC 6871) and Escherichia coli (ATCC 25922).

For the growth of each of the indicator strains in liquid medium, 10 ml of a stock solution of Tryptic Soy Broth (TSB) (Tryptic Soy Broth) culture medium was pipetted into a test tube.

With the aid of a lamp, a loop was sterilized by approaching the flame.

It was expected to cool slightly and the cells collected in the solid medium (from the 2 culture collections) into the TSB test tubes, which were closed and identified.

To promote cell growth they were placed on a shaker for 24 hours at a constant temperature of 37 ° C and under agitation (150 rpm).

In an Erlenmeyer flask, 0.7 ml of the inoculum was added to a sterile buffered potassium hydrogen phosphate solution (70 ml) (pH 7.2), which constituted the test culture medium.

To estimate the initial number of viable cells, an aliquot was removed to make decimal serial dilutions which were then plated (100 μΐ on each plate) in petri dishes containing Tryptic Soy Agar (TSA).

These plates were then incubated at 37 ° C for 24h, at which point the colony forming units (CFU) were analyzed and counted.

The CFU determinations were done in triplicate using at least two dilutions.

To perform the bacterial reduction assessment test, the test samples were added to the test culture medium and incubated for 1h with shaking at 20Â ° C.

Upon completion of the incubation, viable cell counts were performed by the determination of CFU / ml as described for the initial cell count (at least five replicates were performed for each assay in order to assure reliability of the results). The percent reduction (% R) of the colony forming units (CFU) was quantified using the equation:% R = (Co - C) x 100 / Co where Co represents the UFC number in the test with the control sample and C translates the CFUs obtained with the material under test. 14 The reduction rate obtained for the material developed was 81.1% for E. coli bacteria and 77.8% for S. aureus bacteria.

Resistance to stains: The material developed has a high resistance to stains belonging to class 5 (ISO 10545-14) for all tested staining agents (green chromium, olive oil and iodine solution).

This means that, 24 hours after the stain, the stain can be removed only under running water, leaving no trace.

Chemical resistance: The chemical resistance was tested according to ISO 10545-13: - household chemicals (ammonium chloride, 100 g / L); - chemicals for use in swimming pools (sodium hypochlorite solution, 20 mg / L); acids and bases with low concentrations: hydrochloric acid solution, 3% (v / v); potassium hydroxide, 30 g / L; citric acid, 100 g / L; - acids and bases with high concentrations: hydrochloric acid solution, 18% (v / v); potassium hydroxide, 100 g / L and lactic acid, 5% (v / v). The material developed has an anti-acid behavior (UA, ULA and UHA), except for a solution of hydrochloric acid, 18% (v / v), which causes a slight chemical attack on the surface (UHB). (L and H mean that the concentration of the chemical agent used is respectively low and high; A translates that, after contact with the chemical solutions, the product has no surface defect, i.e., no chemical attack.) invention has the object of obtaining a ceramic material for application as a floor or as a coating (porcelain stoneware) with excellent antibacterial properties without detriment to other important technical characteristics normally associated with this type of material, namely high strength chemical, abrasion and anti-stain.

Moreover, part of the anti-bacterial action (51% reduction of the E. coli bacteria) is achieved by the use of a raw material commonly used in the production of this type of products to obtain aesthetic effects (ceramic pigments), which implies absence additional costs. The increase of the anti-bacterial action to 81% reduction already involves additional costs, which are expected to be reduced, so that the cost / benefit ratio is interesting. The prior art features only ceramic material with antibacterial action acting only if irradiated by sunlight or ultraviolet. The material now developed only needs to contact 16 with the bacteria.

Although ceramic pigments are a common raw material in the processing of porcelain stoneware in order to obtain products in the most varied colors, its anti-bacterial action has never been thought of. The present invention exactly explores this novel functionality of this type of feedstock.

In addition to the pigment tested, there will be other commercial ceramic pigments that can give the ceramic material anti-bacterial properties, which should be exploited in future actions. The industrial production of the product developed is easy because it does not need any equipment beyond that the factories that produce stoneware usually possess. The present invention has been tested for the indicated bacteria. However, one should not rule out the need to optimize its performance, extend its application to other bacteria and measure its reproducibility and longevity. LISBON, APRIL 1, 2011

Claims (6)

A process for the production of porcelain grains having an anti-bacterial activity, high chemical resistance and staining characterized by the following steps: (a) Addition of black pigment to the porcelain stoneware paste with the composition (in% atomic): Chromium 35.6; Iron 42.8; Aluminum 8.5; Magnesium 5.8; Titanium 0.7 and Oxygen 6.6); (b) Atomization or filter-pressing of the pulp obtained; (c) Conformation of the material by dry pressing or extrusion; (d) Drying; (e) Spray application of 130-150 g / m @ 3 of a commercial clear glass with a density of 1280-1300 g / l; (f) Cooking. A PROCESS FOR OBTAINING PORCELAIN BODY WITH ANTIBACTERIAL ACTIVITY, HIGH CHEMICAL RESISTANCE AND STAINING, according to the preceding claim, characterized in that the ceramic pieces obtained have antibacterial activity which varies with the amount of black pigment used in the composition of the slurry being the reduction rate of 77 and 63% E. coli and S. aureus of 81 and 67% to 2.5 and 0.5% (by weight) of dye. 3 - acids and bases at low concentrations: hydrochloric acid solution (3% v / v), potassium hydroxide (30 g / L) and citric acid (100 g / L), without surface defects after contact. LISBON, APRIL 1, 2011 2 3. OBTAINING CERAMIC PARTS PRESENTING ANTIBACTERIAL PROPERTIES, HIGH CHEMICAL RESISTANCE AND PLUMBLING, which involves the following steps: (a) Spraying 18-23 g / m 2 of an aqueous solution of sodium nitrate and silver nitrate with a density of 1200-1220 g / L; (b) Heat treatment at 430 ° C. 4. USE OF CERAMIC PARTS, obtained according to the previous claims, characterized by reducing the number of bacteria E. coli and S. aureus when they are in direct contact with said parts. The use of the ceramic parts obtained according to the preceding claims characterized by high stain resistance achieving the removal of stains of green chromium, olive oil and iodine solution after cleaning with tap water. The use of the ceramic parts obtained according to the previous claims, characterized by high resistance to: - common household chemicals: ammonium chloride, 100 g / l; chemical solution for use in swimming pools: sodium hypochlorite, 20 mg / L;