• 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.

• 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.

• Toxicological Research
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• v.14 no.4
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• pp.475-481
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• 1998

This study was performed to investigate the modifying effect of the general (GPA) and the fermented pilose antler (FPA) on experimental hepatocarcinogenesis and Natural Killer cell activity in rats. Specific pathogen free, 5-week male Sprague-Dawley rats were divided into four groups. To induce hepatocarcinogenesis, diethylnitrosamine (DEN, 200 mg/kg, i.p.) was used as a tumor initiator and was given in a single dose at experimental onset. All rats were given a partial hepatectomy (PH) at 3 weeks after experimental onset. Sodium phenobarbital (PB, 0.05% in diet), GPA (0.075% in diet) and FPA (0. 075% in diet) were given from 2 to 8 weeks. Group I of the initiation control group was only given DEN. As initiation-promotion group, Group II was given DEN and then PB. Group III and IV were given DEN-PB-GPA and DEN-PB-FPA, respectively. In hematological analysis, as compared with Group I. the number of white blood cells were significantly increased in the GPA (p<0.01) and the FPA treated group (p<0.05), respectively. Natural killer (NK) cell activity by flow cytometer (FCM) analysis was higher in group of treated with the GPA (35%) than that of the FPA (27.5%), but not significant. Result of the immunohistochemical staining of the glutathione S-transferase placental form (GST-p) indicated that the number of and area of the pre-neoplastic lesions was not significantly changed in Group III and IV compared Group II, respectively. In conclusion, the GPA and the FPA treatment significantly increased the number od WBC in peripheral blood, but the enhancing NK activity and the modifying effect on the experimental hepatocarcinogenesis were not observed.

• Korean Journal of Food Science and Technology
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• v.50 no.1
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• pp.37-43
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• 2018

Optimization of the lactic acid fermentation process was carried out to produce an old antler extract fortified with ${\gamma}$-aminobutyric acid (GABA). An old antler extract (OAE; 5%, w/v) obtained using a herbal extractor showed the highest contents of solids (1.75%) and proteins ($980{\mu}g/mL$). It also showed the highest total amino acid contents of $13,659{\mu}g/mL$, with glycine, proline, and glutamine concentrations of 1,945, 3,405, and $1,641{\mu}g/mL$, respectively. For the over-production of GABA, OAE was fermented with Lactobacillus plantarum EJ2014 in the presence of 0.5%, 1.5% glucose, and 3.5% MSG at $30^{\circ}C$ for 7 days. The fermented OAE showed high viable cell count of $2.0{\times}10^8CFU/mL$, pH of 6.56 and 0.77% acidity after 7 days. In particular, the acidity was greatly decreased by fermentation for 3 days, and 1.4% GABA was produced by the efficient conversion of the substrate, mono sodium glutamate.

• International journal of advanced smart convergence
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• v.10 no.1
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• pp.197-208
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• 2021

The deer antler has been used as a major drug in oriental medicine for a long time. Recently, the demand for easy-to-take health functional foods is increasing due to economic development and changes in diet. As part of research on the development of functional materials for antlers, lactic acid fermentation of antler extract was performed. It was intended to develop a functional material with enhanced total polyphenol and flavonoid content and enhanced antioxidant activity. Lactic acid bacteria fermentation was performed by adding 4 types of lactic acid bacteria starter products, B. longum, Lb. Plantarum, Lb. acidophilus and mixture of 8 types of lactic acid bacteria to the antler water extract substrate, respectively. During the fermentation of lactic acid bacteria, the number of proliferation, total polyphenol and total flavonoid content, DPPH radical scavenging and antioxidant activity were quantified and evaluated. As a result of adding these four types of lactic acid bacteria to the antler water extract substrate, the number of lactic acid bacteria measured was 2.04~5.00×107. Meanwhile, a protease (Baciullus amyloliquefaciens culture: Maxazyme NNP DS) was added to the antler extract to decompose the peptide bonds of the contained proteins. Then, these four types of lactic acid bacteria were added and the number of lactic acid bacteria increased to 2.84×107 ~ 2.21×108 as the result of culture. The total polyphenol contents were 4.82~6.26 ㎍/mL in the lactic acid bacteria fermentation extracts, and after the reaction of protease enzyme and lactic fermentation, increased to 14.27~20.58 ㎍/mL. The total flavonoid contents were 1.52~2.21 ㎍/ml in the lactic acid bacteria fermentation extracts, and after the protease reaction and fermentation, increased to 5.59 ~ 8.11 mg/mL. DPPH radical scavenging activities of lactic acid bacteria fermentation extracts was 17.03~22.75%, but after the protease reaction and fermentation, remarkably increased to 32.82~42.90%.

• Food Science and Preservation
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• v.24 no.2
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• pp.274-281
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• 2017

The optimization of lactic acid fermentation was conducted to produce an old antler fortified with functional ingredients. For the over-production of gamma aminobutyric acid (GABA), the extract of old antlers (OA) was fermented by Lactobacillus plantarum EJ2015 with 0.5% YE, 1.5% glucose, and 3.5% MSG at $30^{\circ}C$ for 7 days. The lactic acid fermented OA showed high viable cell counts of $2.0{\times}10^8CFU/mL$, pH 6.56 and 0.77% acidity after 7 days. Addition of Auricularia auricula-judae (AAJ) enhanced the cell growth of L. plantarum EJ2014, resulting in higher viable cell counts of $2.0{\times}10^9CFU/mL$ and acid production after fermentation for 1 day. In particular, acidity was greatly decreased after fermentation for 3 days and 1.4% GABA was produced by converting efficiently mono sodium glutamate as a substrate. Fermented OA/AAJ mixture indicated the reduced cytotoxicity compared with that of unfermented OA. The fermented OA/AAJ mixture indicated anti-inflammatory effect with less production of NO in microphage cells. The production of NO dropped to $17.75{\mu}M$ at 4 mg/mL, and to $5.58{\mu}M$ at 6 mg/mL old antler after fermentation. Thus, lactic acid fermented OA with AAJ could fortify GABA, probiotics and dietary fiber.

• 축산식품과학과 산업
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• v.11 no.1
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• pp.64-83
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• 2022