INVESTIGADORES
ABRAHAM Analia Graciela
artículos
Título:
Comparative study of different methodologies to determine the exopolysaccharide produced by kefir grains in milk and whey
Autor/es:
RIMADA P S ,; ABRAHAM, ANALIA G
Revista:
LAIT
Editorial:
INRA EDP Science
Referencias:
Lugar: PARIS; Año: 2003 vol. 82 p. 79 - 87
ISSN:
0023-7302
Resumen:
Abstract Quantitative isolation of lactic acid bacteria exopolysaccharides (EPS) from dairy
products is an important step to determine small amounts of EPS (between 25 and 890 mg·L1) in
a medium that contains 30 to 50 g·L1 of lactose. Kefir grains CIDCA AGK1 are able to produce an
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
a medium that contains 30 to 50 g·L1 of lactose. Kefir grains CIDCA AGK1 are able to produce an
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
a medium that contains 30 to 50 g·L1 of lactose. Kefir grains CIDCA AGK1 are able to produce an
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was
obtained when samples were heated as a first step of isolation. Methods that contained two steps of
ethanol precipitation, one step of ethanol precipitation followed by dialysis or direct dialysis
(molecular weight cut-off lower than 6 000 to 8 000) gave the highest values of polysaccharide
concentration (218 mg·L1 of fermented milk and 247 mg·L1 of fermented whey). One step of
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
ethanol precipitation did not completely eliminate residual lactose. EPS was partially lost when
dialysis was carried out with membranes of cut-off of 12 000. About 50% of EPS was lost when
the method included a step of TCA precipitation. We conclude that polysaccharide quantified in
milk and deproteinised whey fermented with kefir grains strongly depends on the isolation
methodology used.
exopolysaccharide commonly known as kefiran when grown in milk and deproteinised whey.
Different methodologies were compared for kefiran isolation from milk and whey fermented for
96 h at 20 °C with 100 g·L1 of kefir grains. Methods that included one or two steps of ethanol
precipitation, one step of ethanol precipitation followed by dialysis, direct dialysis with membranes
of different cut-off (1 000, 6 000, 12 000), and a TCA precipitation step were evaluated. The effect
of a heat treatment of the milk on EPS recovery was also studied. The highest recovery of EPS was