Morphology and Release Profiles of Biodegradable Microparticles Containing Rhamnolipid Biosurfactant

In an effort to expand the technology of bioremediation of hydrophobic organic compounds, microencapsulation technology was investigated as a method of biosurfactant delivery to contaminated sites. Microparticles are composed of active or inactive materials encapsulated in a polymer coating designed...

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Bibliographic Details
Published in:Bioremediation journal 2005-07, Vol.9 (3-4), p.121-128
Main Authors: Henry, Natasha D., Abazinge, Michael, Johnson, Elijah, Jackson, Tanise
Format: Article
Language:English
Subjects:
Aquatic life
Atmospheric pressure
Biodegradation of pollutants
Biological and medical sciences
Bioremediation
biosurfactant
Biotechnology
Brackish
Chemicals
Efficiency
encapsulation efficiency
Environment and pollution
Environmental engineering
Environmental science
Evaporation
Fundamental and applied biological sciences. Psychology
Hazardous materials
Health hazards
Industrial applications and implications. Economical aspects
Marine pollution
Methods
microencapsulation
Molecular weight
Organic contaminants
Polyvinyl alcohol
Rhamnolipids
Surfactants
Technological change
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Summary:In an effort to expand the technology of bioremediation of hydrophobic organic compounds, microencapsulation technology was investigated as a method of biosurfactant delivery to contaminated sites. Microparticles are composed of active or inactive materials encapsulated in a polymer coating designed for controlled release of the encapsulated substance. Surface morphology and release profiles of microparticles containing rhamnolipid biosurfactant were investigated for development of a controlled release bioremediation scheme. The evaluation was conducted under laboratory conditions with 45 mg/ml concentration of biosurfactant and a representative environmental medium; using artificial salt water (35 ppt) and deionized water medium as a control. The microparticles were prepared by the water-in-oil-in-water double emulsion solvent evaporation method. The surface morphology was examined after initial preparation, at 0, 15 and 31 days incubation, using light microscopy. Light microscopic images revealed smooth, spherical microparticles that degraded over time in the media. Results indicated that microparticle degradation occurred mostly in the salt water environment, suggesting that the presence of salts (Na + and Cl − ions) in the water enhanced microparticle degradation. The deionized water environment achieved polymeric degradation that was similar to what was generally reported in the literature. Biosurfactant release was evaluated for polymer molecular weights (M w ) 40, 80, and 200 kDa, in salt water and deionized water media, each of which showed a high initial burst release of biosurfactant, followed by pulse releases that occurred over the 31 day period. The highest level of biosurfactant release of all the molecular weights tested occurred in the M w 80 kDa. The release from M w 40 kDa and M w 200 kDa was not significantly different (P > 0.05). The results showed that this technology may be useful for enhancing bioremediation of residual hydrophobic organic contaminants (HOC) in estuarine and marine environments.
ISSN:1088-9868
1547-6529
DOI:10.1080/10889860500541711