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Reducing sugars effective diffusivity and kinetic of texture changes during blanching of potato strips in hot water

Document Type : Research Article

Authors

1 Department of Food Science and Technology, Faculty of Agriculture, Isfahan University of Technology, Isfahan, Iran.

2 Department of Food Science and Technology, Ferdowsi University of Mashhad, Khorasan Razavi, Iran.

Abstract

Introduction: Heat treatment of potato tissue involves chemical, physical and structural changes. The magnitude of these changes will depend on the extent of thermal processing in terms of time and temperature. Blanching is a heating process that used to inactivate enzymes, de-aeration and modification of texture, preserving color, flavor and nutritional value of fruits and vegetables prior to freezing, canning, drying and frying. Temperature and time of blanching is largely determined by the amount of reducing sugars and textural characteristics of the species. In the previous studies performed on the changes of reducing sugars content in potatoes during blanching, some researchers found evidence that besides the mass transfer to the bath there exists an internal generation of reducing sugars, probably due to an enzymatic hydrolysis of starch. Therefore when predicting the concentration of reducing sugars changes, both mechanisms should be considered. Considering that no study has been done on the effect of internal generation of reducing sugars on their effective diffusivity during blanching and so far there is no comprehensive study on the kinetic of texture changes during blanching of potato at different temperatures and also direct relationship of reducing sugars with Maillard reaction and acrylamide formation in potato, therefore the aims of this study are: 1) determination of effective diffusivity of reducing sugars with and without consideration of them generation and 2) investigation of kinetic of texture changes during blanching of potato strips at the temperature range of 50-90 ºC and modeling of these phenomena.

Materials and methods: Potatoes (variety Agria, ~23 g/100g (dry basis)) was the raw material used in this study. Potatoes stored in a dark room at 20 ºC for 2 weeks were washed and peeled. Then, were striped into dimensions of 0.8×0.8×8 cm using an electric striping machine (Halldeh, model RG-100). Raw potato strips were rinsed immediately after cutting for 1 min in distilled water to eliminate the starch material adhering to the surface prior to blanching. Then, blanching was accomplished by immersing the potato strips in hot distilled water (ratio of mass of potato to water of 1:20) at 50, 60, 70, 80 and 90 ºC. To investigate the kinetic of generation of reducing sugars, strips packaged in duplex in the polyethylene (HDPE with 10 micron thickness) film were immersed in hot distilled water to blanching at the temperatures. Samples were withdrawn after 5, 10, 15, 20, 40, 60, 80, 100 and 120 minutes to measure the reducing sugars content and texture firmness. All experiments were done in triplicate. Maximum stress caused by penetrating of the probe (diameter of 2 mm) into strip texture was the texture evaluation index. To describe the mass transfer (extraction of reducing sugar) during blanching, a three dimensional numerical model based on finite difference method of solving Fick's Second Law has been developed in MATLAB software. The first order kinetic with production rate limiting effect was used to describe the potato strips texture changes during blanching. All experiments were done in triplicate as factorial based on completely randomized design. Data analysis and plotting of figures were performed in SAS and Excel software respectively.

Results and Discussion: The results showed that increasing of blanching temperature increase the reducing sugars effective diffusion coefficient significantly (P

Keywords

References
Aguilar, C., A, Anzaldua., R, Talamas., and G, Gastelom. 1997. Low- temperature blanch improves textural quality of French fries. Journal of Food Science. 62 (3): 568-571.
Anderson, A., V, Gekas., and I, Lind. 1994. Effect of preheating on potato texture. Journal of Food Science and Nutrition. 34: 229–251.
Anzaldua-Morales, A., A, Quintero., and R, Baladran. 1996. Kinetics of thermal softening of six legumes during cooking. Journal of Food Science. 61 (1): 167–170.
AOAC. 1984. Association Official Analytical Chemists. The official methods of analysis. Method 28.074. Arlington. VA: AOAC.
Bartolome, L.G., and G.E, Hoff. 1972. Firming of potatoes: biochemical effect of preheating. Agricaltural and Food Chemistry. 20: 266-270.
Bingol, G., B, Wang., A, Zang., Z, Pan., and T.H.M, Hugh. 2014. Comparison of water and infrared blanching methods for processing performance and final product quality of French fries. Journal of Food Engineering. 121: 135–142.
Califano, A.N., and A, Calvelo. 1983. Heat and mass transfer during the warm water blanching of potatoes. Journal of Food Science. 48: 220-225.
Canet, W., M.D, Alvarez., and C, Fernandez. 2005. Optimization of low-temperature blanching for retention of potato firmness: effect of previous storage time on compression properties. European Food Research and Technology. 221: 423–433.
Garrote, R.L., R.A, Bertone., and E.R, Silva. 1984. Effect of soaking-blanching conditions on glucose losses in potato slices. Journal of Canadian Instifute of Food Science and Technology. 17: 111-113.
Gekas, V., A, Danae Doulia., and K, Tzia. 2000. Aknowledge base for the apparent mass diffusion coefficient (DEFE) of foods. International Journal of Food Properties. 3: 1-14.
Gokmen, V., and T.K, Palazoglu. 2008. Acrylamide Formation in Foods during Thermal Processing with a Focus on Frying. Food Bioprocess Technology. 1: 35–42.
Goncalves, E.M., J, Pinheiro., M, Abreu., T.R.S, Brandao., and C.L.M, Silva. 2010. Carrot (Daucus carota L.) peroxidase inactivation, phenolic content and physical changes kinetics due to blanching. Journal of Food Engineering. 97: 574-581.
Kaymak, F., and N, Suzan Kincal. 1994. Apparent diffusivities of reducing sugars in potato strips blanched in water. International Journal of Food Science and technology. 29: 63-70.
Miller, G. 1959. Use of dinitrosalicylic acid reagent for determination of reducing Sugar. Analitical Chemistry. 31: 426–428.
Mottram, D.S., and B.L, Wedzicha. 2002. Acrylamide is formed in the Maillard reaction. Nature. 419: 448–449.
Moyano, P., E, Troncoso., and F, Pedreschi. 2007. Modeling texture kinetics during thermal processing of potato products. Journal of Food Science. 72: 102–107.
Moyano, P.C., E, Troncoso., and F, Pedreschi. 2007. Texture Kinetics during Thermal Processing of Potato Products. Journal of Food science. 72: 102-107.
Nisha, P., R.S, Singhal., and A.B, Pandit. 2006. Kinetic modeling of texture development in potato cubes (Solanum tuberosum), green gram whole (Vigna radiate L.). Journal of Food Engineering. 76: 524–530.
Pedreschi, F., K, Kaack., and K, Granby. 2004. Reduction of acrylamide formation in potato slices during frying. Lebensmittel-Wissenschaft and Technology. 37: 679–685.
Pedreschi, F., X, Travisany., C.R.E, Troncoso., and R, Pedreschi. 2009. Kinetics of extraction of reducing sugar during blanching of potato slices. Journal of Food Engineering. 91: 443–447.
Rahardjo, B., and S.K, Sastry. 1993. Kinetics of softening of foods. Journal of Food Processing and Preservation. 10: 311–329.
Richter Reis, F., M, Masson., and N, Waszezynskyj. 2007. Influence of blanching pretreatment on color oil uptake and water activity of potato sticks and its optimization. Journal of Food Process Engineering. 31: 833-852.
Sanny, M., S, Jinap., E.J, Bakker., M.A.J.S, Van Boekel., and P.A, Luning. 2012. Is lowering reducing sugars concentration in French fries an effective measure to reduce acrylamide concentration in food service establishments?. Journal of Food Chemistry. 135: 2012-2020.
Saravacos, G.D., and Z.B, Maroulis. 2001. Transport Properties of Foods. Drying Technology. New York. 19 (9): 2383-2384.
Stadler, R.H., I, Blank., N, Varga., F, Robert., J, Hau., A, Guy., P, Robert., and M.C, Riediker. 2002. Acrylamide from Maillard reaction products. Nature. 419: 449–450.
Stanly, D.W., M.C, Bourne., and A.P, Stone. 1995. Low temperature blanching effects on chemistry, firmness and structure of canned green beans and carrots. Journal of Food Science. 6: 327-333.
Stoneham, T.R., D.B, Lund., and C.H, Tong. 2000. The Use of Fractional Conversion Technique to Investigate the Effects of Testing Parameters on Texture Degradation Kinetics. Journal of Food Engineering and Physical Properties. 65 (6): 968-973.
Toledo, R.T. 2007. Fundamental of Food Process Engineering. 3rd de. Springer. (Athens). 8: 285-295.
Van Loon, W.A.M., J.P.H, Linssen., A, Legger., M.A, Posthumus., and A.G.J, Voragen. 2005. Identification and olfactometry of French fries flavour extracted at mouth conditions. Journal of Food Chemistry. 90: 417–425.
Verlinden, B., D, Yuksel., M, Baheri., J, De Baerdemaeker., and C, Van Dijik. 2000. Low temperature blanching effect on the changes in mechanical properties during subsequent cooking of three potato cultivars. International Journal of Food Science and Technology. 35: 331–333.
Welti-changes, J., F, Valez Ruiz., and G.V, Boarbosa-Canovas. 2003. Transport phenomena in Food processing. CRC press LLC. (Florida). 1: 18-38.
Zhiqiang Liu, E., and M, Scanlon. 2007. Modeling the Effect of Blanching Conditions on the Texture of Potato Strips. Journal of Food Engineering. 81: 292-297
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Iranian Food Science and Technology Research Journal
Volume 13, Issue 5 - Serial Number 47
November and December 2017
Pages 691-703
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History
  • Receive Date: 06 May 2016
  • Revise Date: 07 August 2016
  • Accept Date: 22 October 2016
  • First Publish Date: 22 November 2017
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