RU2216525C1 - Method for microbiological treatment of sewage from industrial plants from heavy metal ions: zinc, cadmium and lead - Google Patents

Abstract

FIELD: microbiology, ecology. SUBSTANCE: invention relates to protection of environment (reservoirs). For treatment of effluents from heavy metals method involves using bacterial mixture of microorganisms consisting of the following strains of Rhodococcus ruber: IEGM AS 219; IEGM AS 220; IEGM AS 221; IEGM AS 222; (IEGM AS 338; IEGM AS 347). Bacterial mixture shows great functional variety and the whole complex of strategic possibilities to bioaccumulation of different spectrum of heavy metal ions. Invention can be used for biotechnological treatment of industrial effluents polluted with heavy metals. EFFECT: improved treatment method. 1 dwg, 2 tbl, 6 ex

Description

 The invention relates to environmental protection and hygiene and can be used in the process of sanitation of wastewater from heavy metals and, as a result, in preventing pollution of open water bodies with these toxicants.

 The invention is intended for use in wastewater treatment plants and biological treatment ponds.

 Heavy metals are always present in the biosphere. Small amounts of many of them are necessary for the normal functioning of organisms. In water basins as a result of anthropogenic impact, the content of individual metals is continuously increasing. One of the sources of pollution of water bodies leading to deterioration of water quality and violating the living conditions of aquatic organisms in them is sewage from plants containing diluted solutions of heavy metals, the composition of which is extremely diverse.

 By toxicity, heavy metals are arranged in the following sequence: mercury, silver, copper, cadmium, zinc, lead, chromium, nickel, cobalt (Avakyan, 1967 [1]; Erlich, 1981 [2]).

 Heavy metals suppress the vital activity of all higher and lower organisms: they block enzyme systems and violate the integrity of cell walls.

According to Marier and Takino (1981 [3]), toxic concentrations of zooplankton and fish are (mg / dm ³ ): Cu - 0.05-0.09; Pb - 0.05-0.1; Ni - 0.03-0.04; Zn 0.06-0.3; Al 0.2-1.49; Cd - 0.02-0.03. A great danger is the ability of aquatic organisms to accumulate high concentrations of individual metals in their bodies. Their ions, falling along the trophic chain into the human body, can cause allergic diseases, bronchial asthma and pulmonary enthysema, impaired generative functions and redox processes, tumors.

 Despite the fact that the microbiological transformation and detoxification of individual metals and their compounds has already been fully studied, the biological treatment of industrial wastewater from them is at the development and establishment stage (Yakovlev et al., 1974 [4]; Romanenko et al., 1976 [ 5]; Warr LH, 1980 [6]; Yurovskaya, 1984 [7]).

 Currently, wastewater treatment from heavy metals is carried out by chemical, physical and electrochemical methods. It is expensive, bulky, and a high degree of cleaning is not always ensured. In recent years, the leading role in cleaning processes belongs to the biological, and the main role in it is played by microorganisms, especially bacteria.

 In the problem of clean water, one of the promising areas is the use of natural factors of self-purification and rhodococci occupy a special place in the preservation of pure natural water.

 Alkanotrophic rhodococci isolated from various natural substrates (soil, groundwater and surface water, air, snow, bottom sediments and deep rocks), contrasting ecological and geographical zones (Ivshina, 1982 [8]; Goodfellow, 1989 [9]), have a high potential, and therefore become an increasingly significant object of their possible industrial use.

 The ability of Rhodococci to metabolize a wide range of organic pollutants and synthesize useful compounds such as surfactonites, flocculants, amino acids, polymers, makes them useful in various fields of biotechnology and environmental protection (Samsonova, Slimen, 1989 [10]; Slimen et al., 1989 [11]; Bekhi et al., 1993 [12]; 1994 [13]; Mulbry, 1994 [14]).

 About 80 patents using rhodococci in the purification of hydrocarbons of various kinds are listed in the last three years of the World Patent Index (Derwent Patent Citation Index (DPCI), Derwent Information Ltd., London, UK). Many researchers have noted the high resistance of alkanotrophic rhodococci to adverse and even extreme environmental conditions, such as low temperature and oxygen pressure, lack of nutrient substrates, increased salinity, the presence of inhibitors and antibiotics in the medium (Ivshina et al., 1981 [15]; Milko and et al., 1991 [16]; Coronelli et al., 1994 [17]).

The ability of Rhodococci to accumulate metals from contaminated natural habitats is noted in Tomioka et al., (1994 [18]). As proposed by Tomioko et al. (1994 [18]) a method for the extraction of cesium metal, the author uses the species Rhodococcus erythropolis CS 98 and Rhodococcus sp. strain CS 402. Peshkur (2000 [19]) solved the problem of selecting optimal conditions for the efficient extraction of cesium taking into account temperature, pH, carbon source, and the ratio of K ⁺ and Cs ⁺ ions in the cultivation medium. The proposed work assesses the possibility of using rhodococci for bioaccumulation of cesium. The optimal conditions for the effective extraction of cesium are selected taking into account these conditions.

The object of the study were strains belonging to different species of Rhodococcus (R.) from the Regional profiled collection of alkanotrophic microorganisms, ed. Ivshina [20] (R. fascians, R. erythropolis, R. "longus" and R. ruber). The bioaccumulation of Cs ⁺ was judged by the degree of disappearance of cesium ions from the culture fluid. The author offers the most active bioaccumulators Cs ⁺ , R. erythropolis IEGS AC 270 strains (R. fascians IEGM AC 173, R. "longus" (IEGM AC 32, IEGM AC 69) and R. ruber IEGM AC 326. In this method, all selected the strains are proposed as bioaccumulators of cesium, and it is the experience of using these microorganisms that shows the promise of including rhodococci in the purification of heavy metals, since this is currently one of the most urgent biotechnological problems, and this method was taken as a prototype.

 However, a significant drawback of the method proposed by the author is the very narrow destructive effect of selected species (only with respect to cesium), while it is known that a large variety of pollutants is noted in industrial wastewater polluting water and soil. All this makes us search for microorganisms with wider possibilities of bioaccumulation of metals, in order to use them in the disinfection of water bodies and soils contaminated with different metals at the same time. And based on the ever-increasing pollution of natural water bodies by metals such as Zn, Cd and Pb, which are highly toxic components of the natural environment, the search for microorganisms with a wide spectrum of accumulative action in relation to them is highly relevant.

 The novelty of the proposed method is that the biological object used to clean fresh water from heavy metals, offers species of Rhodococcus, with the ability to effectively extract from wastewater Cd, Zn, Pb at the same time.

 A significant difference of the proposed method is that they use a bacterial mixture of Rhodococcus, consisting of R. ruber (IEGM AC 219; IEGM AC 220; IEGM AC 221; IEGM AC 222; IEGM AC 338; IEGM AC 347).

 The proposed technical solution is used for the first time in the biotechnological treatment of industrial wastewater, since the biological microbiological community of the Rhodococcus, with its great functional diversity and a whole range of strategic opportunities for bioaccumulation of a different spectrum of heavy metals, is proposed as biological treatment factors.

 The method of growing Rhodococcus ruber used for wastewater treatment from heavy metal ions: Zn, Cd, Pb.

 1. At the first stage, a daily culture of R. ruber is grown on 1.5% meat-peptone agar (MPA) without heavy metals.

2. Then, a suspension of the grown culture with a volume of 1 ml (initial optical density D ₅₄₀ = 0.6 at 37 ^° C and an optical path length of 10 mm on an SF-46 spectrophotometer) was added to the autoclaved mixture of Kiev medium containing, g / dm ³ : MgSO ₄ • 7H ₂ O - 0.2; K ₂ HPO ₄ - 1.0; KNO ₃ - 1.0; KH ₂ PO ₄ - 1.0; NaCl - 1.0; CaCl ₂ • H ₂ O - 0.02; FeCl ₃ - 0.001 and ammonium acetate as a source of carbon and energy at a concentration of 2 g / dm ³ (see Peshkur, 2000 [19]). Metal salts were also added to this medium: acetate Cd, acetate Zn, acetate Pb (in the selection of salts, it was assumed that they were readily soluble in an aqueous medium, and acetate was an additional food source for Rhodococcus). The concentration of metal salts (in mg / DM ³ ) was taken for cadmium in the range of 0.3-2.5; for zinc 0.5–2.5 and for lead 0.5–2.5, which corresponded to the maximum concentrations of heavy metals (Zn, Cd, Pb) in water bodies. In the control took Kiev environment, ammonium acetate at a concentration of 2 g / DM ³ and a suspension of Rhodococcus culture (1 ml).

In order to ensure optimal conditions for the life of bacteria, it is recommended to grow them in Erlenmeyer glass flasks with a capacity of 250 ml, containing 100 ml of culture medium, on orbital shakers (130 rpm) at a temperature of 25-28 ^o C.

 From prepared autoclaved solutions without suspension of culture, 50 ml of solution is taken for analysis of the initial metal content.

3. From experimental flasks (that is, culture + metal) and control, control seeding was performed at 1.5% MPA, in order to take into account the initial content of rhodococci (total microbial number, TBC _ref ).

4. The experimental flasks were cultured at a temperature of 25-27 ^° C for 72 h, and after 72 h, 50 ml of culture liquid was filtered through a biofilter to remove microbial mass, and the filtrate was analyzed for heavy metals using an ASSlN atomic absorption spectrophotometer.

 5. The ability of Rhodococci to bioaccumulate the studied metals was judged by the degree of disappearance of the metal ion from the culture fluid.

6. Simultaneously, in the process of 72-hour culture was carried out control of the microflora by seeding the culture suspension in 1.5% IPA TBC _ref at the zero point of reference, and then after 18, 24, 48 and 72 hours.

 In laboratory conditions, we optimized the conditions for growing selected crops for use in wastewater treatment.

The optimal conditions under which there is an intensive (from 49 to 70%) extraction of Zn, Cd, Pb metals from the medium were the following: temperature 25-28 ^o C; pH 7.8-8.0; carbon source ammonium acetate; the presence of metals (Pb, Zn or Cd) in a concentration of from 0.29 to 2.47 mg / DM ³ . According to the data obtained, the most active bioaccumulators of Zn, Pb, and Cd are collection strains of R. ruber (IEGM AC 219, IEGM AC 220, IEGM AC 221, IEGM AC 222, IEGM AC 338, IEGM AC 347).

 The claimed method for the neutralization of industrial effluents from Zn, Cd and Pb uses a bacterial mixture of Rhodococcus, consisting of R. ruber (IEGM AC 221, IEGM AC 222, IEGM AC 347, IEGM AC 219, IEGM AC 220, IEGM AC 338).

The creation of the proposed method was made possible thanks to the following points - from 12 strains of rhodococcus 6 strains were able to accumulate metals:
1. Rhodococcus ruber IEGM AC 219 has the ability to accumulate Zn, Cd.

 2. Rhodococcus ruber IEGM AC 220 has the ability to accumulate Cd.

 3. Rhodococcus ruber IEGM AC 221 according to our data has the ability to accumulate Zn.

 4. Rhodococcus ruber IEGM AC 222 has the ability to accumulate Pb and Cd.

 5. Rhodococcus ruber IEGM AC 338 has the ability to accumulate Pb and Cd.

 6. Rhodococcus ruber IEGM AC 347 has the ability to accumulate Zn, Pb.

 The experimental substantiation of the fact of microbiological treatment of wastewater from heavy metal ions with a mixture of rhodococci is presented in table 1. Examples are offered as an illustration.

Example 1
Wastewater containing heavy metals in a concentration (mg / dm ³ ) was placed in a flask: Zn - 1.81; Cd 0.3; Pb - 0.91 and ammonium acetate at a concentration of 2 g / l, and then a culture of Rhodococcus ruber IEGM AC 219. was added to it. The analysis after 72 hours of cultivation of this strain in wastewater containing heavy metals showed that its concentration of these metals decreased to (mg / dm ³ ): Zn - 0.54; Cd - 0.08, that is, the concentration of zinc decreased 3.4 times, cadmium 3.6 times, the concentration of lead did not change.

Example 2
In wastewater containing the following metal concentrations in (mg / dm ³ ): Zn - 0.5; Cd - 2.4, introduced a culture of Rhodococcus ruber IEGM AC 220 and ammonium acetate at a concentration of 2 g / l, analysis of the metal content after 72 h showed that the concentration of metal metals in (mg / dm ³ ): Zn - 0.5; Cd - 0.72 (cadmium concentration decreased by 3.3 times).

Example 3
Microorganisms Rhodococcus ruber IEGM AC 221 was introduced into wastewater containing heavy metals in (mg / dm ³ ): Zn - 1.03; Cd - 1.38 and ammonium acetate at a concentration of 2 g / l, after 72 hours the zinc content decreased by 2.5 times (to 0.4), and the cadmium content decreased to 1.03 mg / dm ³ .

Example 4
To wastewater containing heavy metals in (mg / dm ³ ): Zn - 2.3; Cd - 2.0 and Pb - 1.07, added Rhodococcus ruber IEGM AC 347 and ammonium acetate at a concentration of 2 g / l, after 72 hours of cultivation, metal concentrations decreased in zinc by 3.3 times, in lead by 3.1 times.

Example 5
To wastewater containing heavy metals in (mg / dm ³ ): Zn - 1.4; Pb - 1.8; Cd - 2.02, introduced cultures of Rhodococcus ruber (IEGM AC 219, IEGM AC 220, IEGM AC 221, IEGM AC 222, IEGM AC 338, IEGM AC 347). An analysis of the metal content after 72 h showed that the concentration of steel metals in (mg / dm ³ ): Zn - 0.56, Pb - 0.9; Cd - 1.18, that is, the concentration of zinc decreased by 2.5 times, the concentration of lead by 2 times, and cadmium by 1.7 times (see drawing).

 An analysis of experiments in which a different amount of the proposed Rhodococcus cultures was introduced into the bacterial mixture for purification showed that the ratio of the Rhodococcus communities taken into the mixture is not significant, since with different variations in the quantitative ratios of these cultures in the mixture, the percentage of metal loss was relatively the same.

Example 6
Wastewater with the metal content in it (mg / dm ³ ) was poured into two flasks: Zn - 1.5; Pb - 2.0; Cd is 2.5. Then, a mixture of the Rhodococcus culture community was introduced into one flask in the following proportions: IEGM AC 219 - 5 ml; IEGM AC 220 - 10 ml; IEGM AC 221 - 5 ml; IEGM AC 222 - 5 ml; IEGM AC 338 - 10 ml; IEGM AC 347 - 10 ml.

 In the second flask, the same cultures were introduced in a different ratio: IEGM AC 219 - 10 ml; IEGM AC 220 - 5 ml; IEGM AC 221 - 10 ml; IEGM AC 222 - 10 ml; IEGM AC 338 - 5 ml; IEGM AC 347 - 5 ml. Analysis of the metal content after 72 hours showed that the decrease in the metal content in both flasks is comparable (Table 2).

 We should not be afraid that the microflora of domestic wastewater entering the wastewater can suppress the development of rhodococci, since ordinary saprophytic microflora is not resistant to high concentrations of heavy metals and quickly dies.

 A distinctive property of the proposed rhodococcal strains is their high activity to the accumulation of Zn, Cd, Pb, as well as the ability to develop on a wide range of hydrocarbons.

 The cleaning process can be carried out continuously during the operation of bioreactors.

 The selected cultures of Rhodococcus ruber (IEGM AC 219, IEGM AC 220, IEGM AC 221, IEGM AC 222, IEGM AC 338, IEGM AC 347), pre-grown in the laboratory according to the proposed method, are introduced into the bioreactor together with activated sludge, which receives industrial sludge drains. As an additional power source, a small amount of hydrocarbons is added containing components suitable for the nutrition of the bacteria used, but lacking toxic substances. In addition, a wide range of hydrocarbons from wastewater is also a source of nutrition for the development of these microorganisms, since rhodococci are organisms that can use a wide range of organic substances as a carbon source. Therefore, mixing industrial wastewater containing heavy metals with domestic wastewater containing organic substances has a stimulating effect on the development of these microorganisms, since they can use various organic compounds as energy and nutrition, as well as accumulate heavy metals.

Literature
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Claims (1)

 The method of microbiological treatment of industrial wastewater from heavy metal ions: zinc, cadmium and lead by using rhodococcus strains as microbiological factors, characterized in that they use a bacterial mixture of rhodococcus consisting of strains of Rhodococcus ruber (IEGM AC 219; IEGM AC 220; IEGM AC 221; IEGM AC 222; (IEGM AC 338; IEGM AC 347).

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