• Journal of the Korean Society of Food Science and Nutrition
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• v.44 no.4
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• pp.579-585
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• 2015

The objective of this study was to investigate the quality characteristics of coffee soaked in Morus bombycis extract. Green coffee beans were soaked in M. bombycis extract for 2, 4, and 6 hours (sample codes: 2H, 4H, and 6H) at $4^{\circ}C$. Soaked green beans were dried and roasted for coffee extraction. Two controls, roasted with the same amount of heat (C1) and showed the same weight after roasting (C2), were used. Physicochemical characteristics (pH, total acidity, color, browning index, and total soluble solids), DPPH free radical scavenging activity (DPPH), ferric-reducing antioxidant power (FRAP), oxygen radical absorbance capacity (ORAC), total polyphenol content (TPC), and total flavonoid content (TFC) were investigated. Lower pH and higher total acidity were observed in 2H, 4H, and 6H (P<0.05), supporting evidence of sour taste. There were significant differences in DPPH between the controls (45.51~47.02%) and samples (50.67~55.25%, P<0.05), although 2H and 6H did not show significantly higher DPPH than the controls. 2H, 4H, and 6H showed significantly higher FRAP values ($0.320{\sim}0.331\;FeSO_4{\cdot}7H_2O\;mM\;FeSO_4/g$) than controls ($0.265{\sim}0.271\;mM\;FeSO_4/g$). ORAC values of samples [1,062.86~1,153.68 mM trolox equivalent (TE)/g] were significantly higher than those of controls (689.40~942.12 mM TE/g). 2H, 4H, and 6H showed significantly higher TPC [24.27~26.07 mg gallic acid equivalent (GAE)/g] and TFC [3.75~4.28 mg quercetin equivalent (QE)/g] than controls (19.79~22.77 mg GAE/g and 1.07~1.95 mg QE/g, respectively) (P<0.05). M. bombycis extracts soaked into green coffee beans showed polyphenol compounds from green coffee beans. Consumer acceptance of 4H (5.12) was the highest, followed by C2 (4.92). C1 (4.14) showed the lowest consumer acceptance. Consumers were segmented into two groups, those who preferred M. bombycis extract-soaked coffee (approximately 61%) and controls (approximately 39%).

• Journal of the Korean Society of Food Science and Nutrition
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• v.42 no.10
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• pp.1638-1648
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• 2013

To promote the utilization of wild edible plants, this study examined blanching, drying, and fermentation as methods for enhancing the functionality of Hemerocallis coreana Nakai. Specimens fermented for 24 hours at a fermentation temperature of $50^{\circ}C$, with a relative humidity of 65%, contained the highest amount of organic acid (18,109.82 mg/100 g). For the blanched; specimens, total organic acid content decreased about 30% compared with the freeze-dried specimens. The main organic acid of Hemerocallis coreana Nakai was confirmed as succinic acid. After fermentation, free sugars decreased; in particular, specimens fermented at a relative humidity of 80% showed a 32~75% reduction in free sugar compared with the freeze-dried specimens. In terms of amino acid content, Hemerocallis coreana Nakai was mainly composed of valine, isoleucine, and phenylalanine. In fermented specimens the total amino acid content was highest in a moderately fermented (17 hr) specimen, (1,010.71 mg/100 g fresh wt.), but decreased in the maximally fermented (24 hr) specimen. The longer the fermentation, the higher the decrease in non-essential amino acids content, while the content of more essential amino acids consistently increased. In conclusion, since seasoned Hemerocallis coreana Nakai contains a considerable amount of glutamine and asparagine, it has a fresh sour and sweet taste; thus, it will likely be a highly preferred wild edible plant. Also, with an increase of essential amino acids after fermentation, Hemerocallis coreana Nakai is excellent in terms of nutrition. Thus, it may be possible to utilize fermented Hemerocallis coreana Nakai in the development of diverse products.

• The Korean Journal of Food And Nutrition
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• v.16 no.2
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• pp.123-129
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• 2003

Kimchi made with the addition of 2 percent of boiled overgrown antler, raw overgrown antler, overgrown antler treated with lactic acid(acid treated overgrown antler) has been fermented for 15 days at 11 $^{\circ}C$. After 15 days of fermentation, the results show that pH of boiled overgrown antler Kimchi was 3.82, that of raw overgrown antler Kimchi was 4.07, acid treated overgrown antler Kimchi was 3.98 control Kimchi was 3.86, and acidity of boiled overgrown antler Kimchi was 7.2 that of raw overgrown antler Kimchi was 10.1, that of acid treated overgrown antler Kimchi was 8.6, control Kimchi was 6.9, respectively. After 15 days, total sugar content was 1.20% in boiled overgrown antler Kimchi, 0.46% in raw overgrown antler Kimchi, 1.15% in acid treated overgrown antler Kimchi, 1.46 % in control Kimchi, and reducing sugar was 0.47% in boiled overgrown antler Kimchi, 0.09% in raw overgrown antler Kimchi, 0.58% in acid treated overgrown antler Kimchi and 0.39% in control Kimchi, respectively. Amino acid content was 16.35${\mu}$mol/m1 in boiled overgrown antler Kimchi, 20.83${\mu}$mol/ml in raw overgrown antler Kimchi, 15.06${\mu}$mol/m1 in acid treated overgrown antler Kimchi, 17.60${\mu}$mol/m1 in control Kimchi, and protein was 1.830% in boiled overgrown antler Kimchi, 2.011% in raw overgrown antler Kimchi, 2.101% in acid treated overgrown antler Kimchi and 2.011% in control Kimchi, respectively. Lactic acid content was 2.036% in raw overgrown antler Kimchi, 1.485% in acid treated overgrown antler Kimchi, 0.954% in boiled overgrown antler Kimchi, 1,200% in control Kimchi, and the content of succinic acid and acetic acid was highest in acid treated overgrown antler Kimchi, and the result was 0.1531% and 0.188%, respectively. The number of microorganism was 0.96${\times}$10$\^$8/g∼3.05${\times}$10$\^$8/g. The number of microorganism was highest in raw overgrown antler Kimchi, and followed by acid treated overgrown antler Kimchi, control Kimchi, and boiled overgrown antler Kimchi, respectively, The results of test of the saltness, sour, aroma, color, texture through sensory evaluation reveal that boiled overgrown antler Kimchi and raw overgrown antler Kimchi has the excellent taste, and followed by control Kimchi, acid treated overgrown antler Kimchi, respectively.

• Journal of the Korean Society of Food Science and Nutrition
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• v.44 no.10
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• pp.1510-1516
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• 2015

The objective of this study was to investigate the quality and sensory characteristics of sweet persimmon mashes and spirits fermented by three different yeasts [Saccharomyces species, labeled as LB (Lalvin BM $4{\times}4$), LD (Lalvin DV10), and UC (Uvaferm CM)]. In the production of sweet persimmon wines, UC had the highest alcohol content of 10.20% (v/v) after 9 days of fermentation (P<0.05). The range of pH after fermentation was 3.63~3.75. The total aerobic bacteria and yeast contents increased until day 3 and then continuously decreased to approximately 8.60 log CFU/mL and 8.20 log CFU/mL, respectively. Reducing sugar contents were 3.37% in UC, 3.91% in LD, and 4.05% in LB after fermentation. Total sugar contents were 4.89% in UC, 6.24% in LD, and 5.47% in LB after fermentation. Two-stage single-pot distillation was conducted to produce sweet persimmon spirits. While conducting second distillation, spirits were collected every 100 mL fraction. The alcohol contents gradually decreased as more fractions were collected. The amounts of acetaldehyde were 226 mg/L for LD, 225 mg/L for LB, and 310 mg/L for UC in the first fraction. LD produced the highest volume (677.8 mL) of alcohol in its body part in comparison with LB (408.0 mL) and UC (445.4 mL). In the descriptive analysis, UC had stronger intensities of sweet aroma, sour aroma and taste, and persimmon flavor (P<0.05). Persimmon characteristics seemed to be well characterized by UC. In conclusion, LD was the most efficient in terms of production cost, whereas UC would be used to produce a more flavorful sweet persimmon spirit.

• Microbiology and Biotechnology Letters
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• v.41 no.3
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• pp.327-334
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• 2013

For the development of hardy kiwi wine, we arranged for the post-maturity of hardy kiwi fruit, treated them with calcium carbonate and a pectinase enzyme complex, investigated the resulting physicochemical properties and conducted a sensory evaluation. The period determined for creating post-maturity in the hardy kiwi fruit was determined as 5 days storage at room temperature following maturity. During this time the yield of fruit juice was increased from 22.1% to 53.5% using 0.1% (v/v) cytolase PCL5 for 2 h at room temperature. 0.1% (w/v) calcium carbonate was also added during the process of aging, for the reduction of the sour taste. The fermentation trial of the hardy kiwi wine was prepared using water (25% or 50%), sugar ($24^{\circ}brix$), 0.1% (w/v) $CaCO_3$, 0.1% (v/v) cytolase PCL5, $K_2S_2O_5$ (200 ppm), and yeast ($1.5{\times}10^7$ cell/ml). Fermentation then occurred for 2 weeks at $20^{\circ}C$. The pH value, total acidity, alcohol, and reducing sugar content of the resulting hardy kiwi wines of 25% (v/w) and 50% (v/w) water, were in a range of pH 3.4-3.7, 1.12-1.21%, 14.3-14.4%, and 15-16 g/l, respectively. Citric acid and fructose constituted the major organic acids and the free sugar of the 25% and 50% hardy kiwi wine, respectively. Volatile flavor components, including 10 kinds of esters, 8 kinds of alcohols, 5 kinds of acids, 3 kinds of others and aldehydes, were determined by GC analysis. The results of sensory evaluation demonstrated that 50% hardy kiwi wine is more palatable than 25% hardy kiwi wine.

• Food Science and Preservation
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• v.22 no.3
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• pp.369-376
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• 2015

This study was performed to develop the maufacturing processes of Makgeolli using red ginseng starch (RGS). After the fermentation of RGS with koji, nuruk, and yeast, the different temperature effects on the number of the yeast cells, the content of organic acid, free sugars, and total acid, and pH were investigated. There were no changes in the composition of the yeast cell number and content of organic acid amd during 20 days at $4^{\circ}C$. The content of free sugars (sucrose, glucose and mannose) and the pH value of red ginseng Makgeolli decreased during storage at $4^{\circ}C$. This meant that the total acid content and pH value increased after organic acid was produced from fermentation. Therefore, red ginseng Makgeolli is highly acidic and sour. Since high acidity helps improve storage conditions, so this developed red ginseng Makgeolli is considered safe for consumption. Furthermore, the total content of ginsenoside was 2.47 mg/mL, which was differentiate Makgeolli using red ginseng starch, with others. Therefore, new red ginseng Makgeolli is rich in organic acid, free sugars, and ginsenoside. As a result, its storage, taste, and flavor improved.

• Journal of Korean Society of Forest Science
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• v.108 no.4
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• pp.610-617
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• 2019

The effects of dippin treatments using Glycyrrhiza uralensis extract (0.5%, 1.0%, 2.0%) and calcium chloride (0.5%, 1.0%, 2.0%) on the quality of peeled chestnuts were investigated. Following dipping treatment, peeled chestnuts were vacuum-packed using a 75-㎛ polyethylene PE and nylon film, and stored in a 0 ℃ incubator for six weeks. The dipping treatments of the peeled chestnuts successfully achieved browning inhibition. The browning degree following 2.0% calcium chloride treatment was the lowest at 0.68 OD. The color change (ΔE) of the peeled chestnuts was the highest (6.0) in the control, and the lowest (3.5) for the 1.0% and 2.0% calcium chloride-treated samples. G. uralensis extract and calcium chloride treatments did not impact weight, moisture loss rate, firmness, or the soluble solid content of the peeled chestnuts following storage. The decay rate was 12.0% in the control group, and 11.0%, 11.5%, and 11.0% for G. uralensis treatment at 0.5%, 1.0%, and 2.0% calcium chloride treatment, respectively, and 13.0%, 9.5%, and 9.0% at 0.5%, 1.0%, and 2.0% calcium chloride treatment, respectively. Sensory evaluation (palatability, off-odor) showed that a 2.0% G. uralensis extract treatment presented excellent results during the storage period. Texture and color indicated no differences as a result of the browning inhibition treatments. Therefore, when considered comprehensively, a 2.0% G. uralensis extract treatment was shown to be effective for maintaining the quality and providing browning inhibition of peeled chestnuts. This result isexpected to solve the problem of quality deterioration in the form of sour taste, which is a problem in chemical processing.

• The Korean Journal of Community Living Science
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• v.16 no.4
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• pp.47-57
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• 2005

To investigate the characteristics of edible flowers as a food material, we have examined the kinds, colors, sizes, fresh weights, pigments and shipping periods of edible flowers marketed on the cropping farms, selling agencies and Internet shopping malls from February through September, 2005. Thirty six kinds of edible flowers were marketed in Korea, and all but the chrysanthemum were introduced species. The characteristics of edible flowers were shown differently by the varieties following the same kinds of flowers. Those colors were yellow (twenty five kinds), red (twenty three), pink (twenty), white (eighteen), and orange (sixteen). Flower diameters were measured and showed that seven kinds of edible flowers were 1.0 to 2.0cm, fourteen 2.0 to 3.0cm, sixteen 3.0 to 4.0cm, eight 4.0 to 5.0cm, and nine over 5.0cm. Flower fresh weights were measured as follows: twenty one kinds of edible flowers were under 0.5g ($58.3\%$), eight were $0.6\∼1.0g(22.2\%$), and six were $1.1{\∼}1.5g(16.7\%$). The taste of edible flowers was often bitter (twenty one kinds), sweet and sour (seven), somewhat fragrant (six), fishy (three), and others (nine). The pigments of edible flowers were anthoxanthin (twenty seven kinds), flavonoid (twenty three), carotenoid (seventeen), and betanidin (four).

• Food Science and Preservation
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• v.23 no.7
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• pp.1050-1057
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• 2016

This study was carried out to investigate the effectiveness of Leuconostoc mesenteroides isolated from octopus baechu kimchi as a potential starter for seafood kimchi. L. mesenteroides is lactic acid bacterium currently used as a starter for kimchi production. We selected the most effective L. mesenteroides strain from the 7 strains isolated from octopus baechu kimchi and, based on biochemical properties and 16S rRNA sequencing, identified the selected strain as L. mesenteroides SK-1. The SK-1 strain exhibited acid-tolerance, good survival capacity, and excellent dextran productivity. We investigated the effects the SK-1 of starter on seafood kimchi fermentation. Octopus baechu kimchi was fermented with L. mesenteroides SK-1 at $4^{\circ}C$ for 35 d. The decrease in pH and increase in acidity in octopus baechu kimchi fermented with the SK-1 starter occurred more quickly than that in the control kimchi indicating that. Octopus baechu kimchi with SK-1 starter has a relatively slow rate of increase in lactic acid production. As a result, octopus baechu kimchi prepared with L. mesenteroides SK-1 can be maintained at a suitable ripening degree over an extended period of time compared to that of the control kimchi, Moreover, the octopus baechu kimchi started with L. mesenteroides SK-1 has excellent sensory properties, including a refreshing taste, and a weak sour odor.

• The Korean Journal of Food And Nutrition
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• v.16 no.1
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• pp.22-28
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• 2003

Kimchi made with the addition of 2 percent of boiled young antler, raw young antler, young antler treated with lactic acid(acid treated young antler) has been fermented for 15 days at 11$^{\circ}C$. After 15 days of fermentation, the results show that pH of boiled young antler Kimchi was 3.87, that of raw young antler Kimchi was 4.04, acid treated young antler Kimchi was 3.97, control Kimchi was 3.86, and acidity of boiled young antler Kimchi was 7.4, that of raw young antler Kimchi was 10.5, that of acid treated young antler Kimchi was 10.7, control Kimchi was 6.9, respectively. After 15 days, total sugar content was 1.46% in boiled young antler Kimchi, 0.53% in raw young antler Kimchi, 0.92% in acid treated young antler Kimchi, 1.46% in control Kimchi, and reducing sugar was 0.50% in boiled young antler Kimchi, 0.14% in raw young antler Kimchi, 0.39% in acid treated young antler Kimchi and control Kimchi, respectively. Amino acid content was 13.42${\mu}$㏖/$m\ell$ in boiled young antler Kimchi, 17.83${\mu}$㏖/$m\ell$ in raw young antler Kimchi, 14.48${\mu}$㏖/$m\ell$ in acid treated young antler Kimchi, 17.60${\mu}$㏖/$m\ell$ in control Kimchi, and protein was 2.101% in boiled young antler Kimchi, 1.945% in raw young antler Kimchi, 1.722% in acid treated young antler Kimchi and 2.011% in control Kimchi, respectively. Lactic acid content was 2.021% in raw young antler Kimchi, 2.004% in acid treated young antler Kimchi, 1.950% in boiled young antler Kimchi, 1.200% in control Kimchi, and succinic acid was 0.081% in boiled young antler Kimchi, 0.086% in raw young antler Kimchi, 0.078% in acid treated young antler Kimchi and 0.111% in control Kimchi, respectively. Acetic acid was 0.080% in boiled young antler Kimchi, 0.092% in raw young antler Kimchi, 0.114% in acid treated young antler Kimchi, 0.086% in control Kimchi, respectively. The number of microorganism was 1.09${\times}$ 10$\^$8//g in boiled young antler Kimchi, 1.08${\times}$10$\^$8//g in control Kimchi, 9.88${\times}$10$\^$8//g in acid treated young antler Kimchi and 6.6${\times}$ 10$\^$8//g in raw young antler Kimchi. The number of microorganism was highest in acid treated young antler Kimchi, and followed by raw young antler Kimchi, and boiled young antler Kimchi, control Kimchi, respectively. The results of test of the saltness, sour, aroma, color, texture through sensory evaluation reveal that boiled young antler Kimchi has the excellent taste, and followed by raw young antler Kimchi and control Kimchi, acid treated young antler Kimchi, respectively.