The microwave coupled with hot air (MCHA) drying method was used in this test to dry hawthorn slices The effect of initial microwave power density level (6 W/g to 12 W/g), hot air temperature (55°C to 70°C), and hot air velocity (1 m/s to 3 m/s) on the quality attributes of rehydration ratio (Rf), organic acid (OA) and ascorbic acid (AA) of the dehydrated hawthorn slices was analyzed using a response surface methodology. An orthogonal rotatable central composite with three factors and at five levels was used to develop predictive regression models for the responses. The prediction mathematical model of Rf, OA and AA of the hawthorn slice was determined by analysis of variance. Factor and response variables as well as the prediction mathematical model, the optimal drying process of Rf, OA and AA of the hawthorn slice were determined by using the Design-Expert software. The comprehensive optimal conditions were as follows: initial microwave power density 12 W/g, hot air temperature 55°C and hot air velocity 1.56 m/s.
Keywords: parameter optimization, response surface methodology, hot air drying, microwave, hawthorn slice
DOI: 10.3965/j.ijabe.20150802.1596

parameter optimization, response surface methodology, hot air drying, microwave, hawthorn slice

Liu T, Cao Y, Zhao M. Extraction optimization, purification and antioxidant activity of procyanidins from hawthorn (C. pinnatifida Bge. var. major) fruits. Food Chemistry, 2010; 119(4): 1656–1662.

Liu P, Yang B, Kallio H. Characterization of phenolic compounds in Chinese hawthorn (Crataegus pinnatifida Bge. var. major) fruit by high performance liquid chromatography- electrospray ionization mass spectrometry. Food Chemistry, 2010; 121(4): 1188–1197.

Belščak-Cvitanović A, Durgo K, Bušić A, Franekić J, Komes D. Phytochemical attributes of four conventionally extracted medicinal plants and cytotoxic evaluation of their extracts on human laryngeal carcinoma (HEp2) cells. J Med Food, 2014; 17(2): 206–17.

Unal H G, Sacilik K. Drying characteristics of hawthorn fruits in a convective hot-air dryer. Journal of Food Processing and Preservation, 2011; 35(2): 272–279.

Argyropoulos D, Heindl A, Müller J. Assessment of convection, hot-air combined with microwave-vacuum and freeze-drying methods for mushrooms with regard to product quality. International Journal of Food Science & Technology, 2011; 46(2): 333–342.

Sarimeseli A, Coskun M A, Yuceer M. Modeling microwave drying kinetics of thyme (Thymus Vulgaris L.) leaves using ANN methodology and dried product quality. Journal of Food Processing and Preservation, 2014; 38(1): 558–564.

Chauhan A K S, Srivastava A K. Optimizing drying conditions for vacuum-assisted microwave drying of green peas (Pisum sativum L.). Drying Technology, 2009; 27(6): 761–769.

Sadeghi M, Mirzabeigi Kesbi O, Mireei S A. Mass transfer characteristics during convective, microwave and combined microwave-convective drying of lemon slices. J Sci Food Agric, 2013; 93 (3): 471–478.

Zielinska M, Zapotoczny P, Alves-Filho O, Eikevik T M, Blaszczak W. Microwave vacuum–assisted drying of green peas using heat pump and fluidized bed: A comparative study between atmospheric freeze drying and hot air convective drying. Drying Technology, 2013; 31(6): 633–642.

de Jesus S S, Filho R M. Optimizing drying conditions for the microwave vacuum drying of enzymes. Drying Technology, 2011; 29(15): 1828–1835.

Mosqueda M R, Tabil L G and Meda V. Physico-chemical characteristics of microwave-dried wheat distillers grain with solubles. J Microw Power Electromagn Energy, 2013; 47(3): 155–176.

Figiel A. Drying kinetics and quality of beetroots dehydrated by combination of convective and vacuum- microwave methods. Journal of Food Engineering, 2010; 98(4): 461–470.

Wojdylo A, Figiel A, Oszmianski J. Effect of drying methods with the application of vacuum microwaves on the bioactive compounds, color, and antioxidant activity of strawberry fruits. J Agric Food Chem, 2009; 57(4): 1337–1343.

Han Q H, Yin L J, Li S J, Yang B N, Ma J W. Optimization of process parameters for microwave vacuum drying of apple slices using response surface method. Drying Technology, 2010; 28(4): 523–532.

Leusink G J, Kitts D D, Yaghmaee P, Durance T. Retention of antioxidant capacity of vacuum microwave dried cranberry. J Food Sci, 2010; 75(3): C311–C316.

Songül Gürsoy R C, Dennis G. Watson. Microwave drying kinetics and quality characteristics of corn. Int J Agric & Biol Eng, 2013; 6(1): 90–99.

Pande R, Mishra H N, Singh M N. Microwave drying for safe storage and improved nutritional quality of green gram seed (Vigna radiata). J Agric Food Chem, 2012; 60(14): 3809–3816.

Sarimeseli A. Microwave drying characteristics of coriander (Coriandrum sativum L.) leaves. Energy Conversion and Management, 2011; 52(2): 1449–1453.

Vongpradubchai S, Rattanadecho P. Microwave and hot air drying of wood using a rectangular waveguide. Drying Technology, 2011; 29 (4): 451–460.

Wang Z F, Fang S Z, Hu X S. Effective diffusivities and energy donsumption of whole fruit Chinese jujube (Zizyphus jujubaMiller) in microwave drying. Drying Technology, 2009; 27 (10): 1097–1104.

Jiang H, Zhang M, Mujumdar A S, Lim R X. Comparison of the effect of microwave freeze drying and microwave vacuum drying upon the process and quality characteristics of potato/banana re-structured chips. International Journal of Food Science & Technology, 2011; 46 (3): 570–576.

Zhang M, Jiang H, Lim R X. Recent developments in microwave-assisted drying of vegetables, fruits, and aquatic products—drying kinetics and quality considerations. Drying Technology, 2010; 28(11): 1307–1316.

Zhao D D, Zhao C P, Tao H Y, An K J. The effect of osmosis pretreatment on hot-air drying and microwave drying characteristics of chili (Capsicum annuum L.) flesh. International Journal of Food Science & Technology, 2013; 48(8): 1589–1595. doi: 10.1111/ijfs.12128

Zielinska M, Zapotoczny P, Alves-Filho O, Eikevikb T M, Blaszczakc W. A multi-stage combined heat pump and microwave vacuum drying of green peas. Journal of Food Engineering, 2013; 115(3): 347–356.

Chandrasekaran S, Ramanathan S, Basak T. Microwave food processing—A review. Food Research International, 2013; 52(1): 243–261.

Gong G L D, Huang Y. Microwave-assisted organic acid pretreatment for enzymatic hydrolysis of rice straw. Biosystems Engineering, 2010; 78(2): 67–73.

Bondaruk J, Markowski M, Błaszczak W. Effect of drying conditions on the quality of vacuum-microwave dried potato cubes. Journal of Food Engineering, 2007; 81(2): 306–312.

Reyes A, Cerón S, Zúñiga R,Moyano P. A comparative study of microwave-assisted air drying of potato slices. Biosystems Engineering, 2007; 98(3): 310–318.

Gowen A, Abu-Ghannam N, Frias J, Oliveira J. Optimisation of dehydration and rehydration properties of cooked chickpeas (Cicer arietinum L.) undergoing microwave–hot air combination drying. Trends in Food Science & Technology, 2006; 17(4): 177–183.

Andrés A, Fito P, Heredia A, Rosa E M. Combined drying technologies for development of high-quality shelf-stable mango products. Drying Technology, 2007; 25(11): 1857–1866.

Gowen A A, Abu-Ghannam N, Frias J, Oliveira J. Modeling dehydration and rehydration of cooked soybeans subjected to combined microwave–hot-air drying. Innovative Food Science & Emerging Technologies, 2008; 9(1): 129–137.

Vadivambal R, Jayas D S. Changes in quality of microwave-treated agricultural products—a review. Biosystems Engineering, 2007; 98 (1): 1–16.

Sharma G P, Prasad S. Drying of garlic (Allium sativum) cloves by microwave–hot air combination. Journal of Food Engineering, 2001; 50(2): 99–105.

Soysal Y, Ayhan Z, Eştürk O, Arıkan M F. Intermittent microwave–convective drying of red pepper: Drying kinetics, physical (colour and texture) and sensory quality. Biosystems Engineering, 2009; 103(4): 455–463.

Karaaslan S N, Tunçer İ K. Development of a drying model for combined microwave–fan-assisted convection drying of spinach. Biosystems Engineering, 2008; 100 (1): 44–52.

Alibas I. Microwave, air and combined microwave–air- drying parameters of pumpkin slices. LWT- Food Science and Technology, 2007; 40(8): 1445–1451.

Sangani V P, Patel N C, Bhatt V M, Davara P R, Antala D K. Optimization of enzymatic hydrolysis of pigeon peafor cooking quality of dhal. Int J Agric & Biol Eng, 2014; 7(5): 123–132.

Li L, Z J, Zhou Q C. Optimization of microwave-assisted extraction of polysaccharides in the flower of Platycodon grandiflorum by response surface methodology. Int J Agric & Biol Eng, 2009; 2(2): 65–74.

Mu Y Q, Z X, Liu B X, Liu C H, Zheng X Z. Influences of microwave vacuum puffing conditions on anthocyanin content of raspberry snack. Int J Agric & Biol Eng, 2013; 6(3): 80–87.

Wu W. Fuel ethanol production using novel carbon sources and fermentation medium optimization with response surface methodology. Int J Agric & Biol Eng, 2013; 6(2): 42–53.

Zhang L J, Y J, Ma L W, Tan H S. Optimization of fermentation process of papaya sauerkraut using response surface method. Int J Agric & Biol Eng, 2014; 7(3): 102–106.

Giri S K, Prasad S. Optimization of microwave-vacuum drying of button mushrooms using response-surface methodology. Drying Technology, 2007; 25(5): 901–911.

Giri S K, Prasad S. Drying kinetics and rehydration characteristics of microwave-vacuum and convective hot-air dried mushrooms. Journal of Food Engineering, 2007; 78(2): 512–521.

Yu H M, Wang C, Han Z X, Sun Y, Zhang W, Hu J, et al. Optimization of steam drying conditions for seedling- growing tray made of paddy-straw. Transactions of the CSAE, 2013; 29(21): 40–49.

Varith J, Dijkanarukkul P, Achariyaviriya A, Achariyaviriya S. Combined microwave-hot air drying of peeled longan. Journal of Food Engineering, 2007; 81(2): 459–468.

Zhou Y S C, Cui Z W. Coupled hot air and microwave drying technology for carrot slices dehydration. Transactions of the CSAE, 2011; 27 (2): 382–386.

Wu H H, Han Q H, Yang B N, Zhao D L, Li Y F, Bai L F. Experiment on combining hot air and microwave vacuum to dry lyeium. Transactions of the Chinese SSAM, 2010; 41(9): 178–181.

Chen G F S C, Cui Z W. Optimizing of coupled hot-air and microwave drying of tea camellia seeds by response surface analysis. Science and Technology of Food Industry, 2012; 33(3): 272–275.