Biomedical Engineering Reference
In-Depth Information
83.
Roos, Y.H., Jouppila, K. and Zielasko, B. Nonenzymatic browning-induced water
plasticization: Glass transition temperature depression and reaction kinetics determi-
nation using differential scanning calorimetry.
J. Thermal Anal
. 1996.
84.
Dennison, D., Kirk, J., Bach, J., Kokoczka, P. and Heldman, D. 1977. Storage stability
of thiamin and riboflavin in a dehydrated food system.
J. Food Process. Preserv.
1,
43, 1977.
85.
Bell, L.N. and Hageman, M.J. Differentiating between the effects of water activity
and glass transition dependent mobility on a solid state chemical reaction: Aspartame
degradation.
J. Agric. Food Chem
. 42, 2398, 1994.
86.
Bell, L.N. and Hageman, M.J. Glass transition explanation for the effect of polyhydroxy
compounds on protein denaturation in dehydrated solids.
J. Food Sci
. 61, 372, 1996.
87.
Gejl-Hansen, F. and Flink, J.M. Freeze-dried carbohydrate containing oil-in-water
emulsions: Microstructure and fat distribution.
J. Food Sci.
42, 1049, 1977.
88.
Labrousse, S., Roos, Y. and Karel, M. Collapse and crystallization in amorphous
matrices with encapsulated compounds.
Sci. Aliments
12, 757, 1992.
89.
King, N. The physical structure of dried milk.
Dairy Sci. Abstr.
27, 91, 1965.
90.
Saltmarch, M. and Labuza, T.P. Influence of relative humidity on the physicochemical
state of lactose in spray-dried sweet whey powders.
J. Food Sci.
45: 1231, 1980.
91.
Labuza, T.P. and Saltmarch, M. The nonenzymatic browning reaction as affected by
water in foods. In
Water Activity: Influences on Food Quality
, L.B. Rockland and
G.F. Stewart, Eds., Academic Press, New York, 1981, 605-650.
92.
Saltmarch, M., Vagnini-Ferrari, M. and Labuza, T.P. Theoretical basis and application
of kinetics to browning in spray-dried whey food systems.
Prog. Food Nutr. Sci.
5,
331, 1981.
93.
Flink, J. and Karel, M. Mechanisms of retention of organic volatiles in freeze-dried
systems.
J. Food Technol.
7, 199, 1972.
94.
Shimada, Y., Roos, Y. and Karel, M. Oxidation of methyl linoleate encapsulated in
amorphous lactose-based food model.
J. Agric. Food Chem.
39, 637, 1991.
95.
Acker, L.W. Water activity and enzyme activity.
Food Technol.
23, 1257, 1969.
96.
Drapron, R. Réactions enzymatiques en milieu peu hydraté.
Ann. Technol. Agric
. 21,
487, 1972.
97.
Drapron, R. Enzyme activity as a function of water activity. In
Properties of Water
in Foods
, D. Simatos and J.L. Multon, Eds., Martinus Nijhoff Publishers, Dordrecht,
the Netherlands, 1985, 171-190.
98.
Careri, G., Gratton, E., Yang, P.H. and Rupley, J.A. Correlation of IR spectroscopic,
heat capacity, diamagnetic susceptibility and enzymatic measurements of lysozyme
powder.
Nature
284, 572, 1980.
99.
Silver, M. and Karel, M. The behavior of invertase in model systems at low moisture
contents.
J. Food Biochem
. 5, 283, 1981.
100.
Leistner, L., Rödel, W. and Krispien, K. Microbiology of meat and meat products in
high- and intermediate-moisture ranges. In
Water Activity: Influences on Food Quality
,
L.B. Rockland and G.F. Stewart, Eds., Academic Press, New York, 1981, 855-916.
101.
Chirife, J. and Buera, M.P. Water activity, glass transition and microbial stability in
concentrated/semimoist food systems.
J. Food Sci.
59, 92, 1994.
102.
Troller, J.A. Water activity and food quality. In
Water and Food Quality
, T.M. Hard-
man, Ed., Elsevier, London, 1989, 1-31.
103.
Sapru, V. and Labuza, T.P. Glassy state in bacterial spores predicted by polymer glass-
transition theory.
J. Food Sci.
58, 445, 1993.
Search WWH ::
Custom Search