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Peptides as functional surfactants / Annette F. Dexter in Industrial & engineering chemistry research, Vol. 47 N°17 (Septembre 2008) 

Public ISBD [article]  in Industrial & engineering chemistry research > Vol. 47 N°17 (Septembre 2008) . - p. 6391–6398 Titre : Peptides as functional surfactants Type de document : texte imprimé Auteurs : Annette F. Dexter, Auteur ; Anton P. J. Middelberg, Auteur Année de publication : 2008 Article en page(s) : p. 6391–6398 Note générale : Chemical engineering Langues : Anglais (eng) Mots-clés : Surface-active  peptides  Lipopeptides Résumé : Peptides offer interesting alternatives to conventional surfactants in applications where renewability, biocompatibility, or added functionality may be desired. This review offers a brief overview of different classes of surface-active peptides and lipopeptides, covering molecules obtained from natural sources as well as those obtained by design. Bacterial lipopeptides are cyclic molecules containing a single fatty acyl moiety, which can exhibit ultralow interfacial tension as well as antimicrobial activities. Bacterial lipopeptides have been proposed for industrial applications such as bioremediation and oil recovery, but they suffer the dual disadvantages of being difficult to bioproduce at low cost and not being easily genetically engineered. A class of synthetic molecules related to bacterial lipopeptides are the peptide amphiphiles, in which a peptide headgroup is combined with a peptide or nonpeptide hydrophobic tail. Self-assembly of peptide amphiphiles has largely been studied in bulk solution rather than at interfaces, meaning that very little information is available on the interfacial properties of these designer molecules. A larger body of information is available for protein hydrolysates, products of the partial breakdown of low-cost proteins (usually food proteins) into a complex mixture of small peptides. Partial hydrolysis can improve the functional properties of many proteins, but the outcomes are difficult to predict or control, and useful functional properties may be associated with only a few minor components in the digest mix. Finally, designed peptide surfactants (Pepfactants), recently reported by the authors, are facially amphipathic molecules that self-assemble at fluid interfaces to give cohesive films stabilizing foams and emulsions. A change in the bulk solution conditions can switch off the interfacial film, leading to rapid foam or emulsion collapse. Pepfactants can be genetically engineered and bioproduced using standard methods, which represents an advantage over bacterial lipopeptides. While peptides have not been widely used in surfactant applications so far, recent developments may facilitate the incorporation of these interesting molecules into industrial and consumer products in the near future. En ligne : http://pubs.acs.org/doi/abs/10.1021/ie800127f [article] Peptides as functional surfactants [texte imprimé] / Annette F. Dexter, Auteur ; Anton P. J. Middelberg, Auteur . - 2008 . - p. 6391–6398. Chemical engineering Langues : Anglais (eng) in Industrial & engineering chemistry research > Vol. 47 N°17 (Septembre 2008) . - p. 6391–6398 Mots-clés : Surface-active  peptides  Lipopeptides Résumé : Peptides offer interesting alternatives to conventional surfactants in applications where renewability, biocompatibility, or added functionality may be desired. This review offers a brief overview of different classes of surface-active peptides and lipopeptides, covering molecules obtained from natural sources as well as those obtained by design. Bacterial lipopeptides are cyclic molecules containing a single fatty acyl moiety, which can exhibit ultralow interfacial tension as well as antimicrobial activities. Bacterial lipopeptides have been proposed for industrial applications such as bioremediation and oil recovery, but they suffer the dual disadvantages of being difficult to bioproduce at low cost and not being easily genetically engineered. A class of synthetic molecules related to bacterial lipopeptides are the peptide amphiphiles, in which a peptide headgroup is combined with a peptide or nonpeptide hydrophobic tail. Self-assembly of peptide amphiphiles has largely been studied in bulk solution rather than at interfaces, meaning that very little information is available on the interfacial properties of these designer molecules. A larger body of information is available for protein hydrolysates, products of the partial breakdown of low-cost proteins (usually food proteins) into a complex mixture of small peptides. Partial hydrolysis can improve the functional properties of many proteins, but the outcomes are difficult to predict or control, and useful functional properties may be associated with only a few minor components in the digest mix. Finally, designed peptide surfactants (Pepfactants), recently reported by the authors, are facially amphipathic molecules that self-assemble at fluid interfaces to give cohesive films stabilizing foams and emulsions. A change in the bulk solution conditions can switch off the interfacial film, leading to rapid foam or emulsion collapse. Pepfactants can be genetically engineered and bioproduced using standard methods, which represents an advantage over bacterial lipopeptides. While peptides have not been widely used in surfactant applications so far, recent developments may facilitate the incorporation of these interesting molecules into industrial and consumer products in the near future. En ligne : http://pubs.acs.org/doi/abs/10.1021/ie800127f