Surface-Active Agents from Two Bacillus Species
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TLDR
It is suggested that earlier reports of biopolymers which both stabilized emulsions and lowered surface tension were actually similar aggregates of lipid and bioemulsifier.Abstract:
Two Bacillus species were studied which produced bioemulsifiers; however, they were distinctly different compounds. Bacillus sp. strain IAF 343 produced unusually high yields of extracellular biosurfactant when grown on a medium containing only water-soluble substrates. The yield of 1 g/liter was appreciably better than those of most of the biosurfactants reported previously. This neutral lipid product, unlike most lipid biosurfactants, had significant emulsifying properties. It did not appreciably lower the surface tension of water. On the same medium, Bacillus cereus IAF 346 produced a more conventional polysaccharide bioemulsifier, but it also produced a monoglyceride biosurfactant. The bioemulsifier contained substantial amounts of glucosamine and originated as part of the capsule layer. The monoglyceride lowered the surface tension of water to 28 mN/m. It formed a strong association with the polysaccharide, and it was necessary to use ultrafiltration to effect complete separation. The removal of the monoglyceride caused the polysaccharide to precipitate. It is suggested that earlier reports of biopolymers which both stabilized emulsions and lowered surface tension were actually similar aggregates of lipid and bioemulsifier.read more
Citations
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References
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TL;DR: An economic comparison demonstrated that this biosurfactant could be produced significantly more cheaply than any of the previously reported microbial surfactants.
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Surface-Active Compounds from Microorganisms
David G. Cooper,J.E. Zajic +1 more
TL;DR: This chapter discusses the metabolites produced by microorganisms, which demonstrate surface activity, and focuses on systems in which the metabolite has been characterized and shown to be surface active.
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Purification and Characterization of Liposan, a Bioemulsifier from Candida lipolytica.
TL;DR: Liposan effected and stabilized oil-in-water emulsions with a variety of commercial vegetable oils and was compared to those of a number of commercial emulsifiers and stabilizers.
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Formation, Isolation and Characterization of Trehalose Dimycolates from Rhodococcus erythropolis Grown on n-Alkanes
TL;DR: Rhodococcus erythropolis DSM 43215 produced a surface-active trehalose lipid whose formation was induced by n-alkanes to a maximum of 2.1 g l-1 in a 50 l batch culture on 2% (w/v) n-alksanes of chain length C12 to C18.
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Emulsifier of Arthrobacter RAG-1: Chemical and Physical Properties
TL;DR: The extracellular emulsifier of Arthrobacter RAG-1 was deproteinized by hot phenol treatment and purified by fractional precipitation with (NH(4))(2)SO(4) and appeared to be homogeneous by immunodiffusion and sedimentation analysis.
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