Optimal physicochemical properties of dried litchis for Thai consumers

Marcelo Precoppe, Marcus Nagle, Busarakorn Mahayothee, Patchimaporn Udomkun, Serm Janjai, Joachim Müller

Abstract


The litchi is a fruit essential for the economies of several Southeast Asian countries, but markets regularly reject it, mainly due to spoilage. Drying extends the shelf-life of litchis, but in Thailand the optimal characteristics of the dried product have not yet been determined. The purpose of this study was to determine the optimum physicochemical properties of dried litchis – those suitable for Thai consumers. The dried fruits were submitted to physicochemical measurement and consumer evaluation, with datasets subsequently integrated using circular ideal-point regression analysis. Response surface methodology was then used to predict the optimum physicochemical properties of the fruits. It was found that Thai consumer preferences with regard to dried litchis are for the fruits to be of golden-yellow color (L* ranging around 54; H ranging around 79°), to have a soft flesh (SMF ranging between 13 and 14 kN/100 g) and to have a sweet taste (TSS:TA ranging between 25 and 28). The results may be used in the future to prescribe pretreatments and drying conditions.
Keywords: consumer preference, response surface methodology, circular ideal-point regression, product optimization, market acceptance, lychee
DOI: 10.3965/j.ijabe.20140705.011

Citation: Precoppe M, Nagle M, Mahayothee B, Udomkun P, Janjai S, Müller J. Optimal physicochemical properties of dried litchis for Thai consumers. Int J Agric & Biol Eng, 2014; 7(5): 103-110.

Keywords


consumer preference, response surface methodology, circular ideal-point regression, product optimization, market acceptance, lychee

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References


Jiang Y M, Wang Y, Song L, Liu H, Lichter A, Kerdchoechuen O, et al. Postharvest characteristics and handling of litchi fruit – An overview. Australian Journal of Experimental Agriculture, 2006; 46(12): 1541–1556.

Jiang Y M, Yao L H, Lichter A, Li J R. Postharvest biology and technology of litchi fruit. J Food Agric Environ, 2003; 1(2): 76–81.

Holcroft D M, Mitcham E J. Postharvest physiology and handling of litchi (Litchi chinensis Sonn.). Postharvest Biol Technol, 1996; 9(3): 265–281.

Jiang Y M, Li Y B. Effects of low-temperature acclimation on browning of litchi fruit in relation to shelf life. Journal of Horticultural Science and Biotechnology, 2003; 78(4): 437–440.

Mitra S, Pathak P K. Litchi production in the Asia-Pacific region. Acta Horticulturae (ISHS), 2010; 863: 29–36.

Agarwal N, Nath N. Effect of pretreatments on quality characteristics and water activity of air-dried litchis (Litchi chinensis Sonn.) cv. Rose Scented. Food/Nahrung, 1990; 34(3): 255–63.

Chen H B, Huang H B. China litchi industry: Development, achievements and problems. Acta Horticulturae (ISHS), 2001; 558: 31–9.

Kuhn G. Dehydration studies of lychee fruit. Florida Agricultural Experiment Stations Journal Series, 1962; 1581: 273–7.

Subhadrabandhu S, Yapwattanaphun C. Lychee and longan production in Thailand. Acta Horticulturae (ISHS), 2001; 558: 49–57.

Tippayawong N, Tantakitti C, Thavornun S, Peerawanitkul V. Energy conservation in drying of peeled longan by forced convection and hot air recirculation. Biosys Eng. 2009; 104(2): 199–204.

ASABE. ASAE S358.2 DEC1988 (R2008) Moisture measurements – Forages. In: American Society of Agricultural and Biological Engineers, editor. ASABE Standards 2008: Standards Engineering Practices Data. St. Joseph, MO: ASABE, 2008. pp. 670–672.

AOAC. Water activity of canned vegetables (method 978.18). Gaithersburg, MD: AOAC International; 1998.

Harker F R, Redgwell R J, Hallett I C, Murray S H. Texture of fresh fruit. In: Janic J, editor. Horticultural reviews. 20. New York, NY: John Wiley & Sons, 1997. pp. 121–224.

AOAC. Solids (soluble) in fruits and fruit products (method 932.12). Gaithersburg, MD: AOAC International, 1998.

AOAC. Acidity (titratable) of fruit product (method 942.15). Gaithersburg, MD: AOAC International; 1998.

Piepho HP. An algorithm for a letter-based representation of all-pairwise comparisons. Journal of Computational and Graphical Statistics, 2004; 13(2): 456–466.

Moskowitz H, Beckley J H, Resurreccion A V A. Sensory and Consumer Research in Food Product Design and Development. 1st ed. Oxford, UK: Blackwell Publishing, 2006. pp. 368.

Gacula M C, Singh J. Statistical Methods in Food and Consumer Research. Orlando, FL: Academic Press, 1984.

Moskowitz H. Food Concepts and Products: Just in Time Development. Trumbull, CT: Food & Nutrition Press, 1994.

Carroll J D. Individual differences and multidimensional scaling. In: Shepard R N, Romney A K, Nerlove S B, editors. Multidimensional Scaling: Theory and Applications in the Behavioral Sciences. 1. New York, NY: Seminar Press, 1972. pp. 105–155.

Moskowitz H. Product testing 2: Modeling versus mapping and their integration. J Sens Stud. 1994; 9: 323–336.

Beuchat L R. Microbial stability as affected by water activity. Cereal Foods World, 1981; 26(7): 345–349.

Janjai S, Precoppe M, Lamlert N, Mahayothee B, Bala B K, Nagle M, et al. Thin-layer drying of litchi (Litchi chinensis Sonn.). Food Bioprod Process, 2011; 89(3): 194–201.

Mahayothee B, Udomkun P, Nagle M, Haewsungcharoen M, Janjai S, Mueller J. Effects of pretreatments on colour alterations of litchi during drying and storage. Eur Food Res Technol, 2009; 229 (2): 329–337.

Hoppe S, Neidhart S, Zunker K, Hutasingh P, Carle R, Steinhart H, et al. The influences of cultivar and thermal processing on the allergenic potency of lychees (Litchi chinensis Sonn.). Food Chem, 2006; 96(2): 209–219.

Ekpong A, Ngarmsak T, Winger R J. Comparing sensory methods for the optimisation of mango gel snacks. Food Quality and Preference, 2006; 17(7-8): 622–628.

Yeh L L, Kim K O, Chompreeda P, Rimkeeree H, Yau N J N, Lundahl D S. Comparison in use of the 9-point hedonic scale between Americans, Chinese, Koreans, and Thai. Food Quality and Preference, 1998; 9(6): 413–419.

Popper R, Rosenstock W, Schraidt M, Kroll B J. The effect of attribute questions on overall liking ratings. Food Quality and Preference, 2004; 15(7-8 SPEC.ISS.): 853–858.

Bower J A, Boyd R. Effect of health concern and consumption patterns on measures of sweetness by hedonic and just-about-right scales. J Sens Stud, 2003; 18(3): 235–48.

Epler S, Chambers IV E, Kemp K E. Hedonic scales are a better predictor than just-about-right scales of optimal sweetness in lemonade. J Sens Stud, 1998; 13(2): 191–197.

Achariyaviriya S, Puttakarn B (Editors). A mathematical model of effective moisture diffusivity for lychee drying. Proceedings of the International Conference on Crop Harvesting and Processing, Louisvilley, KY: ASAE, 2003.




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