Diffusion of Sucrose in Osmo-Dehydrofrozen Apple

REFERENCES

• Lewicki, P.P.; Lenart, A. Osmotic dehydration of fruits and vegetables. In: Handbook of Industrial Drying, 3rd Ed.; Mujumdar, A.S.; Ed.; Taylor & Francis: Boca Raton, FL, 2007; 665–687.
   Google Scholar
• Ferrando, M.; Spiess, W.E.L. Cellular response of plant tissue during the osmotic treatment with sucrose, maltose, and trehalose solutions. Journal of Food Engineering 2001, 49, 115–127.
   Web of Science ®Google Scholar
• Lewicki, P.P.; Porzecka-Pawlak, R. Effect of osmotic dewatering on apple tissue structure. Journal of Food Engineering 2005, 66, 43–50.
   Web of Science ®Google Scholar
• Tregunno, N.B.; Goff, H.D. Osmodehydrofreezing of apples: Structural and textural effects. Food Research International 1996, 29, 471–479.
   Web of Science ®Google Scholar
• Cornillon, P. Characterization of osmotic dehydrated apple by NMR and DSC. LWT–Food Science & Technology 2000, 33, 261–267.
   Google Scholar
• Lenart, A.; Lewicki, P.P. Water diffusion in apple tissue subjected to osmotic dehydration. Zeszyty Naukowe SGGW-AR. Technologia Rolno-Spożywcza 1981, 14, 33–47 (in Polish).
   Google Scholar
• Salvatori, D.; Andres, A.; Chiralt, A.; Fito, P. Osmotic dehydration progression in apple tissue. I. Spatial distribution of solutes and moisture content. Journal of Food Engineering 1999, 42, 124–132.
   Google Scholar
• Kamińska, A.; Lewicki, P.P.; Malczyk, P. Mass transfer in osmotically dehydrated apple stored at temperatures above zero. Journal of Food Engineering 2008, 86, 140–149.
   Web of Science ®Google Scholar
• Reid, D.S. Fruit freezing. In: Processing Fruits: Science and Technology, Vol. 1; Samogyi, L.P.; Ramaswamy, H.S.; Hui, Y.H.; Eds.; Technomic Publ. Comp.: New York, 1996; 275–286.
   Google Scholar
• Chassagne-Berces, S.; Poirier, C.; Devaux, M.-F.; Fonseca, F.; Lahaye, M.; Pigorini, G.; Girault, Ch.; Marin, M.; Guillon, F. Changes in texture, cellular structure and cell wall composition in apple tissue as a result of freezing. Food Research International 2009, 42, 788–797.
   Web of Science ®Google Scholar
• Acevedo, N.C.; Briones, V.; Buera, P.; Aguilera, J.M. Microstructure affects the rate of chemical, physical and color changes during storage of dried apple slices. Journal of Food Engineering 2008, 85, 222–231.
   Web of Science ®Google Scholar
• Garrote, R.L.; Silva, E.R.; Bertone, R.A. Effect of freezing on diffusion of ascorbic acid during water heating of potato tissue. Journal of Food Science 1988, 53, 473–474, 487.
   Web of Science ®Google Scholar
• Chassagne-Berces, S.; Fonseca, F.; Citeau, M.; Martin, M. Freezing protocol effect on quality properties of fruit tissue according to the fruit, the variety and stage of maturity. LWT–Food Science & Technology 2010, 43, 1441–1449.
   Web of Science ®Google Scholar
• Chirault, A.; Martinez-Navarrete, N.; Martinez-Monzo, J.; Talens, P.; Moraga, G.; Ayala, A.; Fito, P. Changes in mechanical properties throughaut osmotic processing: Cryoprotectant effect. Journal of Food Engineering 2001, 49, 129–135.
   Web of Science ®Google Scholar
• Marani, C.M.; Agnelli, M.E.; Mascheroni, R.H. Osmo-frozen fruits: Mass transfer and quality evaluation. Journal of Food Engineering 2007, 79, 1122–1130.
   Web of Science ®Google Scholar
• Buggenhout, S.V.; Lille, M.; Messagie, I.; Van Loey, A.; Autio, K.; Hendrickx, M. Impact of pretreatment and freezing conditions on the microstructure of frozen carrots: Quantification and relation to texture loss. European Food Research and Technology 2006, 222, 543–553.
   Web of Science ®Google Scholar
• Sousa, M.B.; Canet, W.; Alvarez, M.D.; Fernandez, C. Effect of processing on the texture and sensory attributes of strawberry (cv. Heritage) and blackberry (cv. Thornfree). Journal of Food Engineering 2007, 78, 9–21.
   Web of Science ®Google Scholar
• Delemos, B.R.; Singh, R.P. Texture of dehydrofrozen papaya. In: IFT Annual Meeting Book of Abstracts; Institute of Food Technologists: Chicago, IL, 1996.
   Google Scholar
• Pham, Q.T. Modeling heat and mass transfer in frozen foods: A review. International Journal of Refrigeration 2006, 29, 876–888.
   Web of Science ®Google Scholar
• Goldberg, L.D.; Chumak, I.G.; Churkin, A.A. Penetration of salt into vegetable products during freezing in brine; Kholodilnaya Tekhnika Publishing House; Moscow, Russia, 1976, (in Russian).
   Google Scholar
• Storey, R.M. The diffusion of water in frozen cod. Bulletin of the International Institute of Refrigeration 1970, 3, 235–238.
   Google Scholar
• Covarrubias-Cervantes, M.; Champion, D.; Debeaufort, F.; Voilley, A. Translational diffusion coefficients of volatile compounds in various aqueous solutions at low and subzero temperatures. Journal of Agricultural and Food Chemistry 2005, 53, 6771–6776.
   PubMed Web of Science ®Google Scholar
• Hagiwara, T.; Hartel, R.W.; Matsukawa, S. Relationship between recrystallization rate of ice crystals in sugar solutions and water mobility in freeze-concentrated matrix. Food Biophysics 2006, 1, 74–82.
   Web of Science ®Google Scholar
• Champion, D.; Lopez, E.C.; Blond, G.; Simatos, D.; Le Meste, M. Small-molecule translational diffusion in frozen products. Proceedings of the Second IDF International Symposium on Ice Cream; Thessaloniki, Greece, May 14–16, 2003; p. 409.
   Google Scholar
• Biliaderis, C.G.; Swan, R.S.; Arvanitoyannis, I. Physicochemical properties of commercial starch hydrolizates in the frozen state. Food Chemistry 1999, 64, 537–546.
   Web of Science ®Google Scholar
• Champion, D.; Simatos, D.; Le Meste, D. Diffusion-controlled reactions in frozen products. How state diagrams may be used for the prediction of storage stability. Proceedings of the Second IDF International Symposium on Ice Cream; Thessaloniki, Greece, May 14–16, 2003; pp. 264–275.
   Google Scholar
• Manzocco, L.; Nicoli, M.C.; Anese, M.; Pitotti, A.; Maltini, E. Polyphenoleoxidase and peroxidase activity in partially frozen systems with different physical properties. Food Research International 1999, 31, 363–370.
   Web of Science ®Google Scholar
• Champion, D.; Blond, G.; Le Meste, M.; Simatos, D. Reaction rate modeling in cryconcentrated solutions: Alkaline phosphatase catalyzed DNPP hydrolysis. Journal of Agricultural and Food Chemistry 2000, 48, 4942–4947.
   PubMed Web of Science ®Google Scholar
• Kaymak-Ertekin, F.; Sultanoglu, M. Modeling of mass transfer during osmotic dehydration of apples. Journal of Food Engineering 2000, 46, 243–250.
   Web of Science ®Google Scholar
• Panagiotou, N.M.; Karathanos, V.T.; Maroulis, Z.B. Effect of osmotic agent on osmotic dehydration of fruits. Drying Technology 1999, 17, 175–189.
   Web of Science ®Google Scholar
• Koocheki, A.; Azarpazhooh, E. Evaluation of mass exchange during osmotic dehydration of plum using response surface methodology. International Journal of Food Properties 2010, 13, 155–166.
   Web of Science ®Google Scholar
• Rahman, M.S.; Machado-Velasco, K.M.; Sosa-Morales, M.E.; Velez-Ruiz, J.F. Freezing point: Measurement, data and prediction. In: Food Properties Handbook, 2nd Ed.; Rahman, M.S.; Ed.; CRC Press: Boca Raton, FL, 2009; 153–192.
   Google Scholar
• Toczko, M.; Grzelińska, A. Biochemistry Exercises. Wydawnictwo SGGW: Warszawa, Poland, 1997 (in Polish).
   Google Scholar
• Li, H.; Ramaswamy, H.S. Osmotic dehydration: Dynamics of equilibrium and pseudo-equilibrium kinetics. International Journal of Food Properties 2010, 13, 234–250.
   Web of Science ®Google Scholar
• Rahman, M.S. Prediction of ice content in frozen foods. In: Food Properties Handbook; 2nd Ed.; Rahman, M.S.; Ed.; CRC Press: Boca Raton, FL, 2009; 193–206.
   Google Scholar
• Lerici, C.R.; Piva, M.; Dalla Rosa, M. Water activity and freezing point depression of aqueous solutions and liquid foods. Journal of Food Science 1983, 48, 1667–1669.
   Web of Science ®Google Scholar