Study of interaction between chitosan and sodium lauryl ether sulfate

“…In our previous study, several different techniques (turbidimetry, viscometry, tensiometry, electrophoretic mobility, etc.) were combined in order to investigate interaction mechanisms between Ch and SLES indicated the existence of different interaction mechanisms leading to the formation of complexes of different properties (19). It was observed that at relatively low concentration of SLES, soluble Ch/SLES complex occurs while a stable coacervate was formed at mass ratio of Ch:SLES 1:2.…”

“…At this mass ratio coacervate phase fully precipitated from solution. Further increase of SLES concentration leads to re-dissolution of coacervate phase (19). Since the formed complexes show different physicochemical characteristics depending on the mass ratio of chitosan and SLES, there were interesting to investigate the rheological properties of their aqueous solutions.…”

“…Based on previous studies mass ratios of Ch:SLES (140:1; 14:1; 7:1; 3:1; 1,4:1; 1:2; 1:3,5; 1:7) were chosen and they cover the region before and after insoluble coacervate formation (19). Chitosan concentration was 0.2% (w/w).…”

“…The application of coacervates depends greatly on their rheological properties systematically explored the mechanism involved in the rheological properties of coacervates (8). In our previous study (19) several different techniques were combined in order to investigate interaction mechanisms between Ch and sodium lauryl ether sulfate (SLES) and the influence of Ch concentration on the behavior of Ch/SLES complexes in the bulk and at the interfaces. These data were complemented by turbidity, viscosity, and electrophoretic mobility measurements, thus providing information on association in the bulk phase, which allowed a better understanding of their behavior at the air/water interface (19).…”

“…In our previous study (19) several different techniques were combined in order to investigate interaction mechanisms between Ch and sodium lauryl ether sulfate (SLES) and the influence of Ch concentration on the behavior of Ch/SLES complexes in the bulk and at the interfaces. These data were complemented by turbidity, viscosity, and electrophoretic mobility measurements, thus providing information on association in the bulk phase, which allowed a better understanding of their behavior at the air/water interface (19). Nevertheless, the rheological properties of the formed coacervates have not been investigated yet.…”

Rheological characterisation of chitosan/sodium lauryl ether sulfate complexes

“…In our previous study, several different techniques (turbidimetry, viscometry, tensiometry, electrophoretic mobility, etc.) were combined in order to investigate interaction mechanisms between Ch and SLES indicated the existence of different interaction mechanisms leading to the formation of complexes of different properties (19). It was observed that at relatively low concentration of SLES, soluble Ch/SLES complex occurs while a stable coacervate was formed at mass ratio of Ch:SLES 1:2.…”

“…At this mass ratio coacervate phase fully precipitated from solution. Further increase of SLES concentration leads to re-dissolution of coacervate phase (19). Since the formed complexes show different physicochemical characteristics depending on the mass ratio of chitosan and SLES, there were interesting to investigate the rheological properties of their aqueous solutions.…”

“…Based on previous studies mass ratios of Ch:SLES (140:1; 14:1; 7:1; 3:1; 1,4:1; 1:2; 1:3,5; 1:7) were chosen and they cover the region before and after insoluble coacervate formation (19). Chitosan concentration was 0.2% (w/w).…”

“…The application of coacervates depends greatly on their rheological properties systematically explored the mechanism involved in the rheological properties of coacervates (8). In our previous study (19) several different techniques were combined in order to investigate interaction mechanisms between Ch and sodium lauryl ether sulfate (SLES) and the influence of Ch concentration on the behavior of Ch/SLES complexes in the bulk and at the interfaces. These data were complemented by turbidity, viscosity, and electrophoretic mobility measurements, thus providing information on association in the bulk phase, which allowed a better understanding of their behavior at the air/water interface (19).…”

“…In our previous study (19) several different techniques were combined in order to investigate interaction mechanisms between Ch and sodium lauryl ether sulfate (SLES) and the influence of Ch concentration on the behavior of Ch/SLES complexes in the bulk and at the interfaces. These data were complemented by turbidity, viscosity, and electrophoretic mobility measurements, thus providing information on association in the bulk phase, which allowed a better understanding of their behavior at the air/water interface (19). Nevertheless, the rheological properties of the formed coacervates have not been investigated yet.…”

Rheological characterisation of chitosan/sodium lauryl ether sulfate complexes

Unusual Compatibility of N‐Reacetylated Oligochitosan with Sodium Dodecyl Sulfate in Aqueous Solution with a Wide Range of the Solution pH

CO2-switchable emulsion with controllable stability and viscosity based on chitosans and cetyltrimethylammonium bromide