Changes in Quality of Dried Rice Cake Using Perforation Process and Drying Methods

Ready-to-eat tteokguk was manufactured according to the methods described by Kim et al. (2013). The rice was pulverized twice in a roller mill (KM-18, Kyungchang Machine, Seoul, Korea) using wet milling method. To homogenize the particles, the rice flour was filtered through a 20-mesh sieve. Garaeddeok was manufactured by re-sifting the rice powder for 20 min on a loose sieve while pouring water over it, followed by 20 min of steaming. The heat was dissipated for an additional 10 min. The steam-cooked rice dough was injected into a juicer (NJE-3570, NUC, Daegu, Korea) to form garaeddeok. Then, garaeddeok (diameter: 2.8 cm) was cooled at room temperature (25oC) for 3 h. Garaeddeok was sliced to make tteokguk (thickness: 0.4 cm) and packaged in a 0.2-mm PE film. The moisture content, water activity, and color (Hunter L, a, b) of tteokguk were measured.

Pores were formed on the surface of the tteokguk after lowering the surface temperature. The pore size of tteokguk was 0.05 cm, and the number of pores varied; the control had zero pores and the treatments had 6 pores, 12 pores, and 18 pores. The pore pierced the hole using the 0.05 cm needle, and the position of hole was as follows. The samples were dried using hot-air drying (55oC, CT-FDO42, Coretech, Ansung, Korea).

Tteokguk with 0.05cm pore size and 18 pore numbers was dried using various methods: hot-air drying (55oC, CTFDO42, Coretech, Ansung, Korea), vacuum drying (55oC, VFD03, Bocholt, Germany), low-temperature drying (45oC, Sulzle Klein, Niederfischbach, Germany), and freeze-drying (-40oC, DC-41A, Yamato Scientific Co. Ltd., CA, USA). The pores were formed on the surface of the tteokguk and dried until the moisture content reached 45%. The physicochemical and sensory properties were then evaluated.

Rehydration experiments were performed by weighing dried samples and immersing them in hot water (100oC) for 3 min. At 0.5-min intervals, the samples were drained over a mesh and quickly blotted gently with paper towels to eliminate the surface water before samples were reweighed. The rehydration capacity, described as the percentage water gain, was calculated from the sample weight difference before and after rehydration.

The hardness value of the sliced sample (2 × 2 × 2 cm) was measured using a texture analyzer (TA-XT2i, Stable Micro Systems Ltd., Surrey, England). Samples were placed parallel to the center of the plate. A two-bite compression test was used to calculate the hardness (kg) of the sample. The analysis was performed at a maximum load of 2 kg, head speed of 2.0 mm/s, post-speed of 1.0 mm/s, deformation rate of 30%, probe (φ20 mm cylinder probe), distance of 8.0 mm, and force of 5 g.

Using a colorimeter (Chroma Meter, CR 210, Minolta, Osaka, Japan), the surface color of samples was determined. L-values (lightness), a-values (redness), and b-values (yellowness) were measured, and the color values of the calibration plate were as follows: L (97.83), a (-0.43), and b (1.98).

Five grams of sample were homogenized with 50 mL of distilled water at 8,000 rpm using Ultra-Turrax (Model NO. T25, Janken & Kunkel, Staufen, Germany), and pH was measured using a pH meter (Model 340, Mettler-Toledo, Greifensee, Switzerland).

Sensory characteristics were evaluated by selecting 12 panelists. Their preferences were evaluated with respect to the perforation process and drying methods. Tteokguk was sliced at a thickness of 0.5 cm. The evaluation was conducted using a 9-point scale in terms of appearance color, flavor, texture, taste, and overall acceptability. The degree of hardness was rated on a scale of 1 to 9, with 1 being very hard and 9 being very moist and soft. The degree of acceptability was also expressed on a scale of 1 to 9, with 1 indicating very bad and 9 indicating very good.

Each measurement of a physical characteristic was conducted in triplicate and mean values within the triplicates were obtained for statistical analyses. To determine the significance of the observed differences among the thawing methods, the general linear model (GLM) procedure of Statistics Analytical System (SAS) (version 9.12; SAS Inst., Inc., Cary, NC, USA) was used (p<0.05). Duncan’s multiple range test (p<0.05) was used to determine differences between treatment means.

Before tteokguk was perforated and dried, the moisture content of tteokguk was 48.52%, the water activity was 0.999, and the color (Hunter L, a, b) was 71.85, -1.72, and 5.95, respectively.

Changes in the physical properties in response to different pore numbers in tteokguk are summarized in Table 1. The rehydration capacity increased as the number of perforations increased. In contrast, the hardness of tteokguk tended to decrease as the number of perforations increased. The lightness value for the control tteokguk was significantly (p<0.05) lower values than those for the perforation treatments. The redness value for the control was the greater than those for the perforation treatments. The yellowness of tteokguk was lower in perforated samples than in the control. The pH of tteokguk did not differ among the perforation treatments (p>0.05). The sensory characteristics of tteokguk with various pore numbers are shown in Table 2. There was no significant difference in appearance color, and flavor scores between the control and perforation treatments. The texture, taste, and overall acceptability scores increased as the number of pores increased. There is no research on the perforation of starchy foods. Thus, a high number of pores improve the rehydration capacity, hardness, and overall acceptability, controlling for the external features of the tteokguk.

Table 1. Physicochemical properties of Korean sliced rice cakes (tteokguk) according to the perforation process

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Table 2. Sensory characteristics of Korean sliced rice cakes (tteokguk) according to the perforation process

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The physical properties of tteokguk treated by different drying methods are shown in Table 3. The rehydration capacity was greatest for samples subjected to vacuum drying. The hardness was greatest for low-temperature drying and was lowest for vacuum drying. The lightness values were significantly greater for hot-air drying than for the other treatments. The redness and yellowness values of tteokguk did not differ significantly among samples treated with different drying methods. The pH of tteokguk did not differ significantly with respect to the drying method. There were no differences in sensory characteristics (appearance color, flavor, texture, taste, and overall acceptability) among the drying methods. Lim et al. (1999) reported that the effects of drying type on the physical, chemical, and sensory properties of Korean rice cake. They are reported that a significant difference in hardness between microwave and hot air treated rice cake. Choi et al. (2007) reported that the change of quality characteristics of rice flour according to the drying method was not significant. Thus, vacuum drying is optimal for tteokguk and ready-to-eat rice cake tteokguk can be developed by combining the perforation process with vacuum drying. The sensory characteristics of tteokguk with treated by different drying methods are shown in Table 4. There was no significant difference in appearance color, flavor, texture, taste, and overall acceptability scores among the different drying methods. In conclusion, vacuum drying was the suitable drying method for physical properties of tteokguk, even though there was no significant difference in the sensory quality of tteokguk.

Table 3. Physicochemical properties of Korean sliced rice cakes (tteokguk) according to drying methods

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Table 4. Sensory characteristics of Korean sliced rice cakes (tteokguk) according to drying methods

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