GR1009585B - Method for the production of high-purity bio-surfactants from sea microorganisms degrading heavy crude oil fractions - Google Patents

Abstract

The invention relates to the production of high-purity bio-surfactants from sea microorganisms capable of degrading hydrocarbons. There are presented herein, in details, the methodology of the production of said bio-surfactants as well as the features of the smart substrate which, being produced at laboratory or industrial scale, is destined to serve as food for said microorganisms. The invention aims at fighting spills, boosting oil recovery and cleaning up the soil from mineral oils, in an environmentally friendly manner. Furthermore, the invention finds application in the industry of cleaning products, personal hygiene products and cosmetics.

Description

DESCRIPTION

METHOD OF PRODUCTION OF HIGH BIO-SURFACE-ACTIVE SUBSTANCES

CLEANLINESS BY MARINE DECOMPOSING MICRO-ORGANISMS

HEAVY ARGO OIL FRACTIONS

The present invention relates to the production of highly purified biosurfactants from marine microorganisms that degrade heavy fractions of crude oil, using a 'smart' carbon source, and consists of the method of producing the product on a laboratory or industrial scale, the 'smart' substrate, as well and the product whose application is in the field for combating oil spills, and is used in enhanced oil recovery, by the cleaning, personal care and cosmetic industries.

The use of biodegradation has emerged in recent years as a promising "green" complementary method to the physicochemical methods of decontamination of the marine environment from oil spills. The bacteria of the marine environment itself as they break down the oil produce a mixture of bio-surfactant lipids with the help of which they disperse the oil thus increasing the bioavailability of organic pollutants. Biosurfactants are "green" amphiphilic polymers biodegradable and of low toxicity which makes them a promising alternative to synthetics for use in oil spill response, enhanced oil recovery, detergent and personal care products industries.

While a multitude of microorganisms have been shown to have the ability to break down petroleum hydrocarbons, the natural process is very slow as the initial populations of these microorganisms in the water column are at a very low concentration. Thus, one possible way to speed up the process is to add dispersants to increase the availability of the pollutant to microorganisms in the water column. Chemical dispersants are usually used which, if used recklessly, are toxic to the environment. The use of biological dispersants is the solution. The main problems that arise during the production of biosurfactants are their production at a high cost and the presence of impurities in the product from the carbon substrate. This additional process of purifying the product from impurities is an expensive and time-consuming process that makes the production of high-purity biosurfactants even more unprofitable.

The present invention solves the problem of impurities in the final product and the avoidance of an entire processing step, both on a laboratory and industrial scale, that of chromatographic separation, making the production of such substances economically advantageous.

The production method of the biosurfactant lipid mixture described in claim 1 is graphically presented in Figure 1, and consists of the following steps: a) incubation of hydrocarbon-degrading microorganisms in the presence of nutrients and heavy oil fraction as a "smart" carbon source: isolated suitable microorganism genera that produces biosurfactants and degrades crude oil, incubated in a sterile, oven at 120°C for 20 min, open-top incubation chamber for at least 72h in sterile seawater, ONR7a which contains phosphates and nitrates in excess (e.g. KH2PO45 mg/l, KNO310 mg/l). The chamber is shaken either by means of a magnetic stirrer and application of a magnetic field, or by placing the chamber on a shaking bench. The population of the genus of microorganisms is determined by the method of serial dilutions and when it reaches 10<6>CFUs/ml (colony forming units) the culture is ready for use, b) production of biosurfactants in a Batch BioReactor with Batch Operation (Sequencing Batch Reactor, SBR (1)): which contains sterile medium suitable for the cultivation of marine bacteria with a "smart" carbon source (2), e.g. sterile seawater, ONR7a, and phosphate and nitrate as nutrients (3). The medium is then inoculated with a fresh or freeze-dried culture of marine bacterial strains or a mixture of strains with the ability to produce biosurfactants and degrade oil and is incubated in the reactor under agitation achieved by means of a rotary shaker for at least 96 hours. Air is pumped into the system through an air supply to adequately oxygenate it (35% dissolved oxygen). The temperature of the system is maintained by means of a water bath at 20°C c) isolation of biosurfactants by liquid-liquid extraction (4); When the system reaches 10<6>CFUs/ml, the production of biosurfactant molecules has begun and after three days, when the concentration has stabilized at 30 mg/L, we remove 60% of the liquid culture from the reactor ( 5) for the isolation of biosurfactants, with simultaneous replenishment with sterile seawater solution, ONR7a and phosphate and nitrate as nutrients. The solution is extracted three times with an equal volume of ethyl acetate (6). The extract is evaporated in a rotary evaporator (7) to remove the solvent (8). the solvent vapors (9) pass through a heat exchanger (11) are liquefied and the solvent is recycled (12) in the extraction process. The residue (10) is the pure mixture of biosurfactants. The product is sublimated under vacuum and low temperature (-50°C) and crystallizes into a powder.

The culture in the reactor is then re-incubated. In four days (96 hours) the biosurfactant concentration has been replenished to 30 mg/L, and the process is repeated. Figure 2 shows how the biosurfactant concentration changes (vertical axis, mg/L) with time (horizontal axis, days). The square dots represent the concentration of the substance every fourth day (before removal) and the diamonds the concentration after 60% of the culture has been removed.

The "smart" substrate is a heavy fraction of oil (refinery product) which consists of aromatic compounds in a percentage greater than 90%. At ambient temperature it has a solid sticky form, while it flows if the temperature rises above 80°C. This carbon source is very difficult to dissolve in the water phase by marine microorganisms, as a result of which the latter create biofilms on the surface of the substrate and produce biosurfactant compounds in order to achieve its solubilization. This inability to dissolve it is the advantage of this substrate, since it solves the problem of impurities in the final product from the carbon source.

The product consists of rhamnolipids and low molecular weight glycolipids in liquid or powder form and is used as the active substance in dispersion products to enhance the biodegradation of hydrocarbons in marine environments. The biological product is produced from pure strains or a mixture of bacteria with the ability to degrade. of oil and simultaneous production of bio-surfactants.

Claims (3)

1. The method of producing a biosurfactant lipid mixture using hydrocarbon-degrading microorganisms and a "smart" carbon source for their food. The method consists of the following steps: a) incubation of hydrocarbon-degrading marine microorganisms in the presence of nutrients and heavy oil fraction as a carbon source: b) production of biosurfactants in a batch bioreactor, c) bioactive isolation substances by liquid-liquid extraction and removal of the solvent from the extract on a rotary evaporator. The method eliminates a processing step, both on a laboratory and industrial scale, that of chromatographic separation, making the process economically viable. 2. The use of the substrate of claim 1: heavy fraction of crude oil (solid consisting of more than 90% of aromatic compounds) as a "smart" carbon source, for the production of biosurfactant lipid mixture. The "smart" carbon source does not dissolve in the aqueous phase during its degradation by marine microorganisms, thus avoiding impurities in the process. 3. The product of the method of claim 1, a mixture of biosurfactants consisting of rhamnolipids and low molecular weight glycolipids in liquid or powder form, obtained using the "smart" carbon source of claim 2.