R. Thavasi scite author profile

Criteria selected for screening of biosurfactant production by Bacillus megaterium were hemolytic assay, bacterial cell hydrophobicity and the drop-collapse test. The data on hemolytic activity, bacterial cell adherence with crude oil and the drop-collapse test confirmed the biosurfactant-producing ability of the strain. Accordingly, the strain was cultured at different temperatures, pH values, salinity and substrate (crude oil) concentration in mineral salt medium to establish the optimum culture conditions, and it was shown that 38°C, 2.0% of substrate concentration, pH 8.0 and 30% of salt concentration were optimal for maximum growth and biosurfactant production. Laboratory scale biosurfactant production in a fermentor was done with crude oil and cheaper carbon sources like waste motor lubricant oil and peanut oil cake, and the highest biosurfactant production was found with peanut oil cake. Characterization of partially purified biosurfactant inferred that it was a glycolipid with emulsification potential of waste motor lubricant oil, crude oil, peanut oil, diesel, kerosene, naphthalene, anthracene and xylene.

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Biosurfactant Production by Pseudomonas aeruginosa from Renewable Resources

Thavasi

Nambaru

Jayalakshmi

et al. 2011

Indian J Microbiol

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This study deals with production and characterization of biosurfactant from renewable resources by Pseudomonas aeruginosa. Biosurfactant production was carried out in 3L fermentor using waste motor lubricant oil and peanut oil cake. Maximum biomass (11.6 mg/ml) and biosurfactant production (8.6 mg/ml) occurred with peanut oil cake at 120 and 132 h respectively. Characterization of the biosurfactant revealed that, it is a lipopeptide with chemical composition of protein (50.2%) and lipid (49.8%). The biosurfactant (1 mg/ml) was able to emulsify waste motor lubricant oil, crude oil, peanut oil, kerosene, diesel, xylene, naphthalene and anthracene, comparatively the emulsification activity was higher than the activity found with Triton X-100 (1 mg/ml). Results obtained in the present study showed the possibility of biosurfactant production using renewable, relatively inexpensive and easily available resources. Emulsification activity found with the biosurfactant against different hydrocarbons showed its possible application in bioremediation of environments polluted with various hydrocarbons.

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Biosurfactant production by Corynebacterium kutscheri from waste motor lubricant oil and peanut oil cake

Thavasi

Jayalakshmi

Balasubramanian

et al. 2007

Lett Appl Microbiol

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Aim: Production and characterization of biosurfactant from renewable sources. Methods and Results: Biosurfactant production was carried out in 3‐l fermentor using waste motor lubricant oil and peanut oil cake. Maximum biomass (9·8 mg ml–l) and biosurfactant production (6·4 mg ml–l) occurred with peanut oil cake at 120 and 132 h, respectively. Chemical characterization of the biosurfactant revealed that it is a glycolipopeptide with chemical composition of carbohydrate (40%), lipid (27%) and protein (29%). The biosurfactant is able to emulsify waste motor lubricant oil, crude oil, peanut oil, kerosene, diesel, xylene, naphthalene and anthracene; the emulsification activity was comparatively higher than the activity found with Triton X‐100. Conclusion: This study indicates the possibility of biosurfactant production using renewable, relatively inexpensive and easily available resources like waste motor lubricant oil and peanut oil cake. Emulsification activity found with the biosurfactant against different hydrocarbons showed the possibility of the application of biosurfactants against diverse hydrocarbon pollution. Significance and Impact of the Study: The data obtained from the study could be useful for large‐scale biosurfactant production using economically cheaper substrates. Information obtained in emulsification activity and laboratory‐scale experiment on bioremediation inferred that bioremediation of hydrocarbon‐polluted sites may be treated with biosurfactants or the bacteria that produces it.

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Biosurfactant Production by Azotobacter chroococcum Isolated from the Marine Environment

et al. 2008

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Preliminary characterization of a biosurfactant-producing Azotobacter chroococcum isolated from marine environment showed maximum biomass and biosurfactant production at 120 and 132 h, respectively, at pH 8.0, 38 degrees C, and 30 per thousand salinity utilizing a 2% carbon substrate. It grew and produced biosurfactant on crude oil, waste motor lubricant oil, and peanut oil cake. Peanut oil cake gave the highest biosurfactant production (4.6 mg/mL) under fermentation conditions. The biosurfactant product emulsified waste motor lubricant oil, crude oil, diesel, kerosene, naphthalene, anthracene, and xylene. Preliminary characterization of the biosurfactant using biochemical, Fourier transform infrared spectroscopy, and mass spectral analysis indicated that the biosurfactant was a lipopeptide with percentage lipid and protein proportion of 31.3:68.7.

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R. Thavasi

Production and characterization of a glycolipid biosurfactant from Bacillus megaterium using economically cheaper sources

Biosurfactant Production by Pseudomonas aeruginosa from Renewable Resources

Biosurfactant production by Corynebacterium kutscheri from waste motor lubricant oil and peanut oil cake

Biosurfactant Production by Azotobacter chroococcum Isolated from the Marine Environment

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