RU2064500C1 - Fungus strain aspergillus species used for water treatment from floating oil and petroleum products - Google Patents

Abstract

FIELD: microbiology, ecology. SUBSTANCE: new strain of fungus Aspergillus sp. HI deposited in the State Concern "Biopreparation" is proposed for water treatment from floating oil and petroleum product. EFFECT: enhanced effectiveness of water treatment. 1 tbl

Description

 The invention relates to microbiology and relates to the production of a strain of micromycete suitable for cleaning the surface of water from floating oil and oil products.

 Two approaches are used to clean floating water bodies and marine areas from floating oil products. Sorbent preparations of various origins are traditionally used: polyurethane foam, perlite, vermiculite, coal dust, rubber crumb, sawdust, pumice, peat moss [1] These sorbents are quite effective and absorb 40–80 mg of oil per mg dry weight of the sorbent.

 However, the listed materials have the following disadvantages: they quickly settle to the bottom, which complicates their use, many of them are more toxic in ecosystems than the toxic pollutant itself. On the other hand, biological preparations are often used to clean up oil pollution.

Known strains of micromycetes-biodestructors of oil Streptomyces alboasialis "C", Aspergillus amstelodami, capable of destroying oil and oil products in wastewater with an efficiency of up to 50 [2 and 3]
However, these strains operate in a narrow temperature range (25-30 ^o C) and are used only for wastewater treatment.

 Widely used strain Pseudomonas putida [4] with high characteristics for biodegradation of oil and oil products.

However, the disadvantage of this strain is that it grows and utilizes oil only at a relatively high temperature (28 42 ^o C). On the 30th day, Preudomonas Putida utilizes 65 74 oil.

 The aim of the invention is to obtain a strain of micromycete, with the ability to clean fresh and sea water from the surface of contamination with oil and oil products in a wide temperature range in a relatively short time.

 The proposed strain Aspergillus sp.H1 isolated from a sample of crude oil of the West Siberian field. The strain is deposited by the Central collection of microorganisms of the State concern "Biological product".

 The proposed strain of Aspergillus sp. H1 is non-toxic, capable of self-reproduction, develops from seed on a mineral medium, using hydrocarbons of oil and oil products as carbon sources, stays on the surface of the water for a long time, and forms a strong and easily removable film. The micromycete culture successfully combines the properties of a biodestructor and a biosorbent of oil and oil products, which gives a high total effect when cleaning water from oil pollution (up to 99).

 The resulting strain is characterized by the following features.

Morphological features
On Chapek-Dox agar with sucrose, after 48 hours, it shows moderate growth. Columns of dark green color up to 1 2 mm in diameter are formed with a developed substrate and scarce aerial white mycelium. With aging, the aerial mycelium becomes marsh.

 On carrot agar, after 48 h, large, convex colonies with a raised center of colonies develop up to 6–8 mm in diameter. The colonies have a developed aerial mycelium of light marsh color, framed by a white okat. Reverse yellow-brown. The mycelium is segmented, with inclusions. The conidial head has a club shape, two-tier sterigms, spherical conidia with small spikes. On meat and peptone broth it grows, forming a fragile film and a parietal ring.

Physiological and biochemical characteristics
The strain Aspergillus spH1 consumes glucose, galactose, does not ferment lactose, ramnose, arabinose and sucrose. The lack of enzymes for the utilization of sucrose explains the very moderate growth in the Chapek-Doks medium containing this carbohydrate. It develops in meat and peptone broth containing 2.5 and 6.5 NaCl. It has a weak proteolytic activity, liquefies gelatin.

 Synthesizes amylase and hydrolyzes starch. It has catalase activity. Absorbs hydrocarbon oil and petroleum products. In a liquid mineral medium it develops in the form of a strong film located at the interface between the water and oil phases.

Storage conditions: in sterile soil under liquid paraffin at 4 ^o C.

 The strain of the fungus Aspergillus sp. H1 is able to grow in aqueous mineral media containing oil, fuel oil, diesel fuel as a carbon source. By assimilating the hydrocarbon substrate, micromycete forms a massive mycelium located at the interface between two phases: oil-water, in the form of a strong film.

 In the process of micromycete growth, oil or oil products initially located on the surface of the water undergo the following changes: light fractions evaporate, some hydrocarbons undergo biodegradation, are absorbed by micromycete, and are used to build mycelium. The remaining substrate is absorbed by the mycelium, is sorbed in its cavities and is firmly held in this biological sorbent. Mushroom film, impregnated with oil or oil products, and representing a biosorbent, is mechanically removed from the surface of the water, leaving a liquid practically free of oil.

Multiple experiments conducted in the laboratory with this micromycete revealed the following patterns. In the temperature range from 10 to 37 ^o C on the surface of fresh and sea water contaminated with an oil slick (film thickness 0.5 6.0 mm), at a level of pollution of 1 5 from spores within 7 - 14 days a mushroom film sorbing oil develops . Using the weighted method of chemical extraction with chloroform, it was found that during the growth of the micromycete it is utilized up to 15-20%, evaporates and is lost during manipulations up to 20-30% sorbed up to 86% of the hydrocarbon substrate from the initial level of contamination.

As a result, pollution of the water surface with oil and oil products is eliminated by 80 99
The test was carried out at 10 and 25 ^o C in tap and sea water containing disubstituted ammonium phosphate at a concentration of 0.35 g / l as a mineral additive.

PRI me R 1. The strain Aspergillus sp. H1 was grown in 100 ml flasks containing 25 ml of sterile medium. A 0.5 mm thick oil film was layered on the surface of the liquid, which was about 1 by weight. Oil, fuel oil, diesel fuel was pre-sterilized. Then the medium was infected with micromycete spores at the rate of 10 ⁷ spores / ml. Uninfected flasks were used as a control. The experiment was carried out at a temperature of 25 ^o C and 10 ^o C in stationary conditions.

 At the end of the experiment, the method of oil extraction with chloroform, followed by weighing the dry residue, evaluated the quantitative contribution to the purification of the biosorption process, biodegradation, and natural losses. The biosorption coefficient was determined, i.e., the amount (mg) of sorbed substrate per unit weight (mg) of dry weight of micromycete. The results of experiments on cleaning the surface of the water from oil pollution are presented in the table.

Observing the micromycete growth dynamics, we were convinced that already at 7 o’clock at 25 ^o C a mushroom film was developed at the oil-fresh water interface, capable of sorbing up to 57.1 floating oil. The cleaning efficiency was 74.2. With an increase in the observation period to 14 days, the biosorbent mass increased, the film became stronger, and the proportion of biodegradation and cleaning efficiency increased by 10.9 and 8.9, respectively. A further increase in exposure time to 21 days practically did not lead to an increase in cleaning efficiency. The biosorption coefficient during the observation period varied slightly within 8.2 ^o C11.8.

Thus, at 25 ^o C in fresh water, an oil slick of 0.5 mm thickness is subjected to effective purification (up to 80%) of Aspergillum sp. H1 for 7 to 14 days. With a decrease in temperature to 10 ^o C, the micromycete development process lengthens, and the cleaning efficiency decreased slightly (up to 76.9%).

Strain Aspergillus sp. H1 removes oil pollution of sea water both at 25 ^o C and at 10 ^o C with an efficiency of 78.4 and 57.4, respectively.

 In addition to oil stains, the proposed strain with high efficiency (up to 97) cleans fresh water pollution with fuel oil and diesel fuel. It should be noted that at a relatively high level of fuel oil contamination (1.8), the biosorbent absorbed 44.0 mg of substrate per 1 mg of dry weight, which significantly exceeded the biosorption coefficient when cleaning water from stains of diesel fuel and oil.

PRI me R 2. The strain Aspergillus sp. H1 was grown under conditions simulating an oil spill. The experiment was carried out in two versions. In the first case, 0.75 L was poured into the desiccator onto the surface of an oil slick measuring 153 cm ² x1.0 mm. In another case, the desiccator was filled with three liters of fresh water and an oil slick of 490 cm ² x 3.0 mm was applied. The medium was infected with spores at the rate of 10 ⁷ spores / cm ² . Incubation was carried out at 25 ^o C. the Formation of a strong mushroom film ended by the end of two weeks. However, we continued the experiment until 45 days and made sure that the biosorbent, saturated with oil, remains on the surface of the water during this period. At the end of the experiment, the biosorbent film was mechanically removed from the water surface and the efficiency of oil pollution purification was determined using the chloroform extraction method. The results of the experiment are presented in the table. The cleaning efficiency was excellent and amounted to 89.9 in the first desiccator and 99.6 in the second, and the biosorption coefficient was 21.8 and 18.2, respectively.

 Comparison of the proposed micromycete strain with known bacterial preparations (for example, Putidul) is difficult due to the different principles underlying the mechanism of cleaning water surfaces from oil pollution from mushroom and bacterial preparations. A bacterial preparation purifies oil pollution only due to the biochemical oxidation of the oil substrate, i.e. in the process of biodegradation. The action of micromycete is based on two interrelated processes, namely, the process of biodegradation of oil, and the formation of the body of the fungus associated with it, and the process of biosorption of almost all remaining unoxidized oil. If we compare the bacterial and fungal strains in terms of biodegradation, the first is superior to the second (30–40). However, if we compare the preparation by the final result, i.e., by the efficiency of cleaning the water surface from oil pollution, the mushroom strain is more effective and gives excellent (up to 99 cleaning) results.

 Biosorbent based on the Aspergillus sp. H1 is able to efficiently dispose and collect floating oil, fuel oil and diesel from water surfaces. The proposed biosorbent successfully combines the properties inherent in micromycetes biodestructors [1 and 2] and chemical oil sorbents [3] The result of the combined action is manifested in the extremely high (up to 99) efficiency of cleaning water surfaces from oil pollution, which exceeds the efficiency of the action of these micromycetes biodestructors on 40 50 When comparing the indicator of sorption coefficient, it should be noted that the proposed biosorbent is not inferior to chemical analogues. Comparison with known preparations of bacteria-biodegradable oils based on the strain Pseudomonas putida 36/4 and the strain Micrococeus sp. IM [4] reveals a higher effectiveness (20 more) of the proposed biosorbent.

 The proposed strain is promising for obtaining on its basis a biosorbent suitable for purification of floating oil and oil products in sedimentation tanks, treatment facilities and during oil spills on the surface of fresh and marine bodies of water.

Claims (1)

The strain of the fungus Aspergillus species CCM F _σ -525 "B" 2 (State concern "Biological product") used to purify water from floating oil and oil products.

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