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Abstract

There are many works in the field of osmotic dehydration of fruit where kinetic studies using a macroscopic approach are reported. However, very few studies have been developed from a microscopic point of view, taking into account the compartment structure of the cellular tissue and the complex cell to cell transport phenomena. The latter could allow a better understanding of the process and therefore a more accurate model, but in many cases it is not possible to establish an adequate bridge between microscopic models and practical applications. The analysis of the concentration profiles during mass transfer phenomena in structured foods, being a macroscopic approach, is a very useful tool to clarify the mass transfer mechanisms as well as to calculate the corresponding kinetics. In this paper the concentration profiles of water and solutes, developed throughout the fruit osmotic dehydration, are discussed as a function of the temperature and sample thickness for apple. The profile development is modeled in terms of a new mathematical model, which could avoid some of the restraints of the Fickian equations, usually utilized in this kind of modeling. Another aspect involved in this work is the equilibrium status of the fruit in the osmotic process. Equilibrium data are required to evaluate the true driving force of the mass transfer process. Nevertheless, a lack of studies in this area was detected. The results of extensive work on the behavior of samples until equilibrium is reached in osmotic treatments are also discussed.

Keywords

osmotic dehydration fruit equilibrium concentration profiles kinetics mass transfer

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References

Adambounou T.L. , Castaigne F. and Dillon J.C. (1983). Lowering the water activity of tropical vegetables by partial osmotic dehydration. Science des Aliments 3: 551-567.

Albors A. , Salvatori D. , Andrés A. , Chiralt A. and Fito P. (1997). Structure change profiles in apple tissue during mass transfer phenomena. In: Proceedings of the Meeting Process Optimisation and Minimal Processes of Foods. Warsaw, December 1996.

Anderson A. , Gekas V. , Lind I. , Oliveira F. and Öste R. (1994). Effect of preheating on potato tissue. Critical Reviews in Food Science and Nutrition 34: 229-235.

Barat J. (1997). Desarrollo de un modelo de la deshidratación osmótica como operación básica. PhD Thesis, Universidad Politécnica de Valencia.

Barat J.M. , Soro R. , Santos A. , Chiralt A. and Fito P. (1997). Equilibrium and pseudo-equilibrium situations in cellular food-osmotic solution systems. In: Proceedings of the Meeting Process Optimisation and Minimal Processes of Foods . Warsaw, December, 1996.

Barat J.M. , Chiralt A. and Fito P. (1998). Equilibrium in cellular food-osmotic systems: The role of the structure. Journal of Food Science (In press).

Biswal R.N. and Bozorgmehr K. (1991). Equilibrium data for osmotic concentration of potato in NaCl-water solution. Journal of Food Process Engineering 14: 237-245.

Fito P. ( 1994). Modelling of vacuum osmotic dehydration of food. Journal of Food Engineering 22: 313-328.

Fito P. and Chiralt A. (1996). Osmotic Dehydration. An approach of the modelling of solid food-liquid operations In: Fito P. , Ortega-Rodríguez E , Barbosa-Cánovas G.V. (eds), Food Engineering 2000. New York: Chapman and Hall. pp. 231-252.

10.

Fito P. , Andrés A. , Pastor R. and Chiralt A. (1993). Vacuum osmotic dehydration of fruits. In: Singh P. , Oliveira F. (eds), Process Optimization and Minimal Processing of Foods. Boca Raton, Florida: CRC Press. pp. 107-121.

11.

Hallström B. (1992). Mass transfer in foods. In: Heldman D.R. , Lund D.B. (eds), Handbook of Food Engineering. New York: Marcel Dekker, Inc. pp. 317-339.

12.

Le Maguer M. (1996). Mass transfer modeling in structured foods. In: Fito P. , Ortega-Rodriguez E. and Barbosa-Cánovas G.V. (eds), Food Engineering 2000. New York: Chapman and Hall. pp. 253-270.

13.

Le Maguer M. and Yao Z.M. (1995). Mass transfer during osmotic dehydration at the cellular level. In: Barbosa-Cánovas G.V. , Welti-Chaves, J. (eds). Food Preservation by Moisture Control: Fundamentals and Applications. Lancaster, Pennsylvania: Technomic Pub. Co., pp. 325-350.

14.

Lenart A. and Flink J.M. (1984a). Osmotic concentration of potato. II. Spatial distribution of the osmotic effect. Journal of Food and Technology 19: 65-69.

15.

Lenart A. and Flink J.M. (1984b). Osmotic concentration of potato. I. Criteria for the end-point of the osmosis process. Journal of Food and Technology 19: 45-63.

16.

Marcotte M. and Le Maguer M. (1992). Mass transfer in cellular tissues. Part II: Computer simulations vs experimental data. Journal Food Engineering 17: 177-199.

17.

Rault-Wack A.L. , Botz O. , Guilbert S. and Rios G. (1991). Simultaneous water and solute transport in shrinking media—Part 3: A tentative analysis of the spatial distribution of the impregnating solute in the model gel. Drying Technology 9: 630-642.

18.

Rault-Wack A.L. , Rios G. Saurel R. , Giroux F. and Guilbert S. (1994). Modelling of dewatering and impregnation soaking process (Osmotic dehydration). Food Research International 27: 207-209

19.

Salvatori D. (1997). Deshidratación osmótica de frutas: cambios composicionales y estructurales a temperaturas moderadas. PhD Thesis, Universidad Politécnica de Valencia.

20.

Salvatori D. , Andrés A. , Chiralt A. and Fito P. (1997a). Concentration profiles in apple tissue during osmotic dehydration. In: Jowitt, R. (ed.), Engineering & Food at ICEF 7. Part I, London: Sheffield Academic Press Ltd., pp. 77-80.

21.

Salvatori D. , Andrés A. , Chiralt A. and Fito P. (1997b). Fickian prediction of concentration profile in apple tissue subjected to osmotic dehydration. In: Proceedings of the Meeting Process Optimisation and Minimal Processes of Foods . Warsaw, December 1996.

22.

Stahl R. and Loncin M.L. (1979). Prediction of diffusion in solid foodstuffs. Journal Food of Process and Preservation 3: 213-223.

23.

Yamaki S. and Ino M. (1992). Alteration of cellular compartmentation and membrane permeability to sugars in immature and mature apple fruit. Journal of the American Society of Horticulture Science 117: 951-954.

Some advances in osmotic dehydration of fruit/Algunos avances en deshidratación osmótica de frutas

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