INVESTIGADORES
PUPPO Maria Cecilia
artículos
Título:
Rheological characterization of amaranth protein gels
Autor/es:
AVANZA, M. V.; MARIA CECILIA PUPPO; AÑÓN, M. C.
Revista:
FOOD HYDROCOLLOIDS
Editorial:
Elsevier
Referencias:
Año: 2005 vol. 19 p. 889 - 898
ISSN:
0268-005X
Resumen:
Gel forming properties of amaranth proteins at different thermal conditions and protein concentration were studied. Gel point (G0 and G00G0 and G00
crossover) and gelation kinetics (G0 vs. time) were analyzed. The type of gel formed from the rheological point of view was studied analyzing
the rheograms obtained from frequency sweeps. Texture properties of cold-set gels were analyzed by TPA assays. Minimum conditions for
gelation were 7%, w/v and 70 8C. Elasticity of heated dispersions and gels increased with the increase of protein concentration. A high value
of the network structure index was observed. This behavior could be related to the great proportion of disulfide bonds formed during
amaranth protein gelation. At temperatures above 70 8C (80, 90 and 95 8C), gelation of dispersions (15%, w/v) took place at times less than
5 min. A first order kinetic gelation process with reaction rate specific constant values that increased with the increase of heating temperature
was observed. A rapid denaturation of globulins followed by sulfhydryl/disulfide interchange reactions between protein molecules conduced
to a gelation phenomenon enhanced by protein aggregation. Gels prepared over critical conditions (TO70 8C, protein concentration O7%,
w/v) presented a strong gel-like behavior. These type of gels were elastic in nature (tan d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
G0 vs. time) were analyzed. The type of gel formed from the rheological point of view was studied analyzing
the rheograms obtained from frequency sweeps. Texture properties of cold-set gels were analyzed by TPA assays. Minimum conditions for
gelation were 7%, w/v and 70 8C. Elasticity of heated dispersions and gels increased with the increase of protein concentration. A high value
of the network structure index was observed. This behavior could be related to the great proportion of disulfide bonds formed during
amaranth protein gelation. At temperatures above 70 8C (80, 90 and 95 8C), gelation of dispersions (15%, w/v) took place at times less than
5 min. A first order kinetic gelation process with reaction rate specific constant values that increased with the increase of heating temperature
was observed. A rapid denaturation of globulins followed by sulfhydryl/disulfide interchange reactions between protein molecules conduced
to a gelation phenomenon enhanced by protein aggregation. Gels prepared over critical conditions (TO70 8C, protein concentration O7%,
w/v) presented a strong gel-like behavior. These type of gels were elastic in nature (tan d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
8C. Elasticity of heated dispersions and gels increased with the increase of protein concentration. A high value
of the network structure index was observed. This behavior could be related to the great proportion of disulfide bonds formed during
amaranth protein gelation. At temperatures above 70 8C (80, 90 and 95 8C), gelation of dispersions (15%, w/v) took place at times less than
5 min. A first order kinetic gelation process with reaction rate specific constant values that increased with the increase of heating temperature
was observed. A rapid denaturation of globulins followed by sulfhydryl/disulfide interchange reactions between protein molecules conduced
to a gelation phenomenon enhanced by protein aggregation. Gels prepared over critical conditions (TO70 8C, protein concentration O7%,
w/v) presented a strong gel-like behavior. These type of gels were elastic in nature (tan d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
8C (80, 90 and 95 8C), gelation of dispersions (15%, w/v) took place at times less than
5 min. A first order kinetic gelation process with reaction rate specific constant values that increased with the increase of heating temperature
was observed. A rapid denaturation of globulins followed by sulfhydryl/disulfide interchange reactions between protein molecules conduced
to a gelation phenomenon enhanced by protein aggregation. Gels prepared over critical conditions (TO70 8C, protein concentration O7%,
w/v) presented a strong gel-like behavior. These type of gels were elastic in nature (tan d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
TO70 8C, protein concentration O7%,
w/v) presented a strong gel-like behavior. These type of gels were elastic in nature (tan d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
d!0.1), of high hardness, fracturability and
cohesiveness, although presented low adhesiveness. Depending on protein and thermal conditions, amaranth proteins were able to form selfsupporting
gels that could be applied in different gel-like foods.
