Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-27T21:37:59.112Z Has data issue: false hasContentIssue false

Shelf life of unpasteurized sour orange juice in Iran

Published online by Cambridge University Press:  24 January 2008

Sedigheh Amiri
Affiliation:
Department of Food Science and Technology, College of Agriculture, Shiraz University, Shiraz, 71345, Iran
Mehrdad Niakousari
Affiliation:
Department of Food Science and Technology, College of Agriculture, Shiraz University, Shiraz, 71345, Iran
Get access

Abstract

Introduction. In Iran, sour orange is available between mid-October and March. Frequently, consumers store a large volume of unpasteurized juice at room or low temperatures for consumption when the fresh fruit is not available. The aim of our research was to determine the shelf life of unpasteurized sour orange juice which was stored under conditions similar to those adopted by consumers at home. Materials andmethods. Sour orange juice was prepared by hand-squeezing fresh fruit; it was filtered, and then poured into clear or dark green glass bottles. Bottles were stored at room temperature [(28 ± 2) °C], in the refrigerator [(4 ± 1) °C] and in the freezer [(–12 ± 1) °C] for 12 weeks. Additional samples were prepared by supplementing juice with 2% (w/w) citric acid and they were stored in the refrigerator. Total soluble solids and pH values were measured every 2 weeks and analysis was carried out on ascorbic acid content by means of the titration method in the presence of 2,6–dichlorophenol indophenol. The study was performed for 12 weeks. Resultsand discussion. Total soluble solids content and pH value of the initial juice were 11.5 °Brix and 3.18, respectively. pH appeared not to be significantly influenced by storage time or conditions; however, total soluble solids content in a few samples was reduced to about 9.5 °Brix. The initial ascorbic acid content was 130 mg·100 mL–1; after 2 weeks, it was reduced by nearly 50% for all unfrozen samples. The final concentration of ascorbic acid in the juice was approximately 20 mg·100 mL–1, regardless of storage conditions. The deteriorative reaction of ascorbic acid in the juice at each temperature experienced followed a first-order kinetic model with activation energy of 2.67 kJ·mol–1.

Type
Research Article
Copyright
© CIRAD, EDP Sciences, 2008

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Hodgnos R.W., Horticultural varieties of citrus, in: Reuther W., Webber H.J., Dexter L. (Eds), The citrus industry, Centen. Publ. Univ. Calif., USA, 1967, pp. 4–25.
Harold H., Citrus fruits, Macmillan Co., Collier, Macmillan Ltd., New York, USA, 1957.
Salminen, J.P., Karonen, M., Lempa, K., Liimatainen, J., Sinkkonen, J., Lukkarinen, M., Pihlaja, K., Characterisation of proanthocyanidin aglycones and glycosides from rose hips by high-performance liquid chromatography–mass spectrometry, and their rapid quantification together with vitamin C, J. Chromatogr. Anal. 1077 (2005) 170 –180. CrossRef
Williams, P.G., Ross, H., Brand, J.C., Ascorbic acid and 5-methyltetrahydrofolate losses in vegetables with cook/chill or cook/hot-hold food service systems, J. Food Sci. 60 (1995) 541–546. CrossRef
Zerdin, K.L., Rooney, M., Vermue, J., The vitamin C content of orange juice packed in an oxygen scavenger material, Food Chem. 82 (2003) 387–395. CrossRef
Kimball D.A., Citrus processing quality control and technology, Chapman and Hall, New York, USA, 1991.
Lee, H.S., Nagy, S., Quality change and nonenzymic browning intermediates in grapefruit juice during storage, J. Food Sci. 53 (1988) 168–172. CrossRef
Burdurlu, H.S., Koca, N., Karadeniz, F., Degradation of vitamin C in citrus juice concentrates during storage, J. Food Eng. 74 (2006) 211–216. CrossRef
Handwerk, R.L., Coleman, R.L., Approaches to citrus browning problem, J. Agric. Food Chem. 36 (1988) 231–236. CrossRef
Ahmed, A.A., Watrous, G.H., Hargrove, G.L., Dimick, P.S., Effects of fluorescent light on flavor and ascorbic acid content in refrigerated orange juice and drinks, J. Milk Food Technol. 39 (1976) 332–336. CrossRef
Jiang, Y., Pen, L., Li, J., Use of citric acid for shelf life and quality maintenance of fresh-cut Chinese water chestnut, J. Food Eng. 63 (2004) 325–328. CrossRef
Santerre, C.R., Cash, J.N., Vannorman, D.J., Ascorbic acid/citric acid combination in the processing of frozen apple slices, J. Food Sci. 53 (1988) 1713 –1716. CrossRef
Horwitz W., Official methods of analysis, Assoc. Off. Agric. Chem., Inc., Washington, USA, 1975.
Kabasakalis, V., Siopidou, D., Moshatou, E., Ascorbic acid content of commercial fruit juices and its rate of loss upon storage, Food Chem. 70 (2000) 325–328. CrossRef
Nagy, S., Vitamin, C content of citrus fruit and their products, J. Agric. Food Chem. 28 (1980) 8–18. CrossRef
Choi, M.H., Kim, G.H., Lee, H.S., Effects of ascorbic acid retention on juice color and pigment stability in blood orange (Citrus sinensis) juice during refrigerated storage, Food Res. Int. 35 (2002) 753–759. CrossRef
Rouse, A.H., Atkins, C.D., Heat inactivation of pectinesterase in citrus juices, Food Technol. 63 (1952) 291–294.
Kavousi Chahak K., Accelerated shelf-life testing in lime juice, Shiraz Univ., Thesis, Shiraz, Iran, 1997, 89 p.
Nagy S., Smoot J.M., Temperature and storage effects on percent retention and percent US recommended dietary allowance of vitamin C in canned single-strength orange juice, J. Agric. Food Chem. 25 (1977)135–138.
Polydera, A.C., Stoforos, N.G., Taoukis, P.S., Comparative shelf life study and ascorbic acid loss kinetics in pasteurized and high pressure processed reconstituted orange juice, J. Food Eng. 60 (2003) 21–29. CrossRef
Laing, B.M., Schlueter, D.L., Labuza, T.P., Degradation kinetics of ascorbic acid at high temperature and water activity, J. Food Sci. 43 (1978) 1440–1443. CrossRef
Robertson, G.L., Samaniego, C.M.L., Effect of initial dissolved oxygen levels on the degradation of ascorbic acid and the browning of lemon juice during storage, J. Food Sci. 51 (1986) 184–187. CrossRef
Toledo R.T., Fundamentals of food process engineering, Van Nostrand Reinhold Publ., New York, USA, 1991.
Labuza, T.P., Riboz, D., Theory and application of Arrhenius kinetics to the prediction of nutrient losses in foods, Food Technol. 39 (1982) 66–74.