• Korean Journal of Soil Science and Fertilizer
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• v.30 no.3
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• pp.295-300
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• 1997

Flavor components of natively grown tea plant(Camellia sinensis O. kuntze) in Korea, collected from 12 locations, were analyzed by gas chromatograph and mass spectrometer. Seventy to eighty flavor components in tea leaves were separated by GC. Total 52 flavor components were identified by comparing gas chromatograhp retention time and mass spectral date. They were classified as 19 alcohols, 5 aldehydes, 2 hydrocarbons, 6 ketones, 4 esters, 3 lactones, 2 acids, 3 phenols, 4 pyrazines, and 4 nitrogenous compounds. Major compounds identified were geraniol, linalool oxide, 1-hexanol and ethanol.

• Journal of Sensor Science and Technology
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• v.21 no.5
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• pp.345-351
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• 2012

Biomimetic terpene sensors which have high sensitivity and stability have been fabricated using moleculary imprinted polymer (MIP) technology. Since it is impossible to make a resistive type sensor due to the high resistance of MIP, we improved the sensor by adding conductive polymers. We investigated the sensitivity of resistive type sensors with nano particles depending on the amount of conductive polymers. The MIP membrane contained the methacrylic acid as functional monomer and ethylene glycol dimethacrylate as cross linker, which formed specific cavities originated by the target terpene molecules. The mixture of MIP and the conductive polymer was coated on the patterns of interdigit electrodes on the alumina substrate. The fabricated sensors showed their highest specific sensitivities exposed to 500 ppm target gases : limonene 0.055 at 40% of amount of conductive polymers and geraniol $5.84{\times}10^{-4}$ at 20% of amount of conductive polymers. In conclusion, we found that the terpene sensors are affected by the target molecules, functional monomers and the conductive polymers.

• Journal of the Korean Society of Tobacco Science
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• v.25 no.1
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• pp.70-79
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• 2003

$\beta$ -Glucosidase-catalysed synthesis of glucosides with aromatic alcohols and monoterpene alcohols as accepters and cellobiose as a donor in the presence of various commercial $\beta$ -glucosidases were described. $\beta$ -Glucosidases from Aspergillus niger spp,. Trichoderma spp., Penicillium sup. and bitter almond have been shown to catalyze synthesis of $\beta$ -glucosides of benzyl alcohol, 2-hydroxybenzyl alcohol, 4-hydroxybenzyl alcohol, 2-phenylethyl alcohol, geraniol and citronellol in the presence of cellobiose as sugar donor. Among enzyme preparations tested, each $\beta$ -glucosides prepared from Aspergillus niger were isolated in the pure state by Diaion HP-20 and silica gel column chromatography. The products were identified as $\beta$ -glucosyl products of benzyl alcohol, 2-hydroxyhenzyl alcohol, 4-hydroxybenzyl alcohol, 2-phenyl ethyl alcohol, geraniol and citronellol by spectrometry (UV, IR, $^1$H-NMR, $^{13}$ C-NMR) and enzymatic hydrolysis with $\beta$ - glucosidase. Monoterpene alcohols with a sterically hindered hydroxyl group, such as linalool, $\ell$-menthol and $\alpha$-terpineol were not used as acceptors in transglycosylation reaction.

• Microbiology and Biotechnology Letters
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• v.19 no.5
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• pp.536-541
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• 1991

To enhance the productivity of fruit flavor compounds from whey by the lactose fermenting yeast, Kluyveromyces lactzs ATCC 8585 was treated with N-methyI-N'-nitro-N-nitrosoguanidine (NTG). After the NTG treatments, a mutant showing resistance to antifungal activity of geraniol, and strong fruity but low yeasty flavor was selected and named as K. lactis 450 K. Flavor compounds from 3-day culture broth were extracted with pentane-dichloromethane (2:l) and the concentrated oleoresins were analyzed by gas chromatography. The mutant strain produced more classes and larger amount of flavor compounds than the parent stlain. Tentatively identified volatile compounds from the culture of the mutant were: terpenes such as myrcenol; alcohols such as cis-3-hexenol, n-hexanol; esters such as ethyl isovalerate, cis- 3-hexenyl n-butyrate, n-amyl-n-hexanoate, phenyl ethyl n-propioate; ketones such as methyl vinyl ketones; other compounds such as vanillin, 3-methylcoumarin.

• Korean Journal of Food Science and Technology
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• v.31 no.5
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• pp.1153-1158
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• 1999

Propolis is a resinous bee-hive product that honeybees collect from plant exudates, flower and leaves. Flavor characteristics of two varieties of propolis collected from different plant origins, falseacacia(Robinia psedoacacia L.) and chestnut tree(Castanea crenata), were analyzed using Aroma Scan and GC/MS. Two varieties of propolis were grouped with quite different aroma profiles by Aroma Scan. Fifty five flavor compounds were identified by GC/MS, of which 44 compounds were found from the propolis of falseacacia and 47 compounds from chestnut tree. Five aldehydes, eight alcohols. five ketones, three esters, one fatty acid, twenty seven hydrocarbons. two terpenes and four phenolic derivatives were identified. Thirty six compounds including benzaldehyde, cinnamyl alcohol, eudesmol and benzyl benzoate were detected in both propolis, eight compounds including geraniol and n-undecane only in propolis of falseacacia and eleven compounds including piperitenone and valencene only in chestnut tree.

• Journal of Life Science
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• v.19 no.9
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• pp.1333-1336
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• 2009

The purpose of this study was to characterize the aromas of rose tea and rosehip tea. Aroma compounds were extracted by simultaneous distillation and extraction method using a Likens and Nickerson's extraction apparatus. The concentrated aroma extracts were analyzed and identified by GC and GC-MS. Thirty-eight compounds, including phenylethyl alcohol, citronellol, menthol, menthone, linalool and geraniol, were isolated and identified in rose tea. Thirty-six compounds, including menthol, $\alpha$-anethole, $\alpha$-terpinolene, menthone, linalool and 6-methyl-5-heptene-2-one, were isolated and identified in rosehip tea. Large amounts of phenyl ethyl alcohol and citronellol were found in rose tea, while large amounts of menthol and $\alpha$-anethole were found in rosehip tea.

• Journal of Life Science
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• v.17 no.8 s.88
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• pp.1111-1114
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• 2007

The volatile flavor components of buckwheat (Fagopyrum esculentum Moench)-green tea were analyzed and identified. To make tea having good flavor and functional property, parched buckwheat (50%) was mixed with green tea (50%). The extraction of volatile flavor compounds of buckwheat-green tea was accomplished by a simultaneous distillation and extraction method using a Likens and Nickerson's extraction apparatus. The concentrated extract was analyzed and identified by gas chromatography and GC-mass spectrometry. The main volatile flavor components of buckwheat-green tea were compounds that originated from parched buckwheat and the green tea. The former were 15 pyrazines having roasted and nutty aroma and methylbutanals and furfural having sweet-aroma. The latter were nerolidol, linalool, indole, ${\beta}-ionone$ and geraniol etc having flower-like odor in green tea.

• Journal of the Korean Society of Food Science and Nutrition
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• v.32 no.6
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• pp.801-805
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• 2003

Volatile flavor components in chestnut (Castanea crenate Sieb. et Zucc.) flower were collected by SDE method using the mixture of n-pentane and diethylether as an extract solvent and were identified by GC-FID and GC/MS. A total of 122 components including 35 alcohols,5 hydrocarbons,20 terpene and derivatives,7 ketones, 24 aldehydes, 12 esters, 4 acids, 3 furans, and 2 miscellaneous were identified from total volatile extract of chestnut. Alcohols were comprise 36.58% of volatile extract and dominant constituents and the main components of flower volatiles were 1-phenylethanol (18.6%), (E)-geraniol, tricosane, heneicosane, benzyl alcohol, acetophenone and 2-phenylethanol as aromatic alcohols and odd carbon hydrocarbons. Especially 1-phenylethanol and acetophenone would be applicable to the markers to ascertain floral origin of chestnut honey. The powerful animal and floral notes of chestnut flower were characterized by compounds including nonanal.

• Korean Journal of Food Science and Technology
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• v.27 no.5
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• pp.789-793
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• 1995

Chemical composition was determined to renew interest in acacia flower as food. The moisture content was 86.60%. The chemical composition showed 24.55% of protein, 8.51% of ash, 40.97% of total sugar and 160.44mg% of ascorbic acid on dry matter basis, respectively. Free sugar was mainly composed of fructose, sucrose and glucose. In fatty acid composition, the ratio of saturated and unsaturated fatty acids was 1.7 : 1. The unsaturated acids were primarily composed of polyenoic acid by more than 90%. The amino acid was distributed with a ratio 0.32 of essential to total amino acids. Important elements of acacia flower were K, Mg, Ca, Fe, and Na. Flavor components such as 24.19% of octadecanoic acid, 9.41% of benzyl alcohol, 7.05% of linalool, 5.43% of heptacosane and 4.28% of geraniol were identified as major volatile compounds of acacia flower.

• Korean Journal of Food Science and Technology
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• v.22 no.5
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• pp.543-548
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• 1990

Volatile components of fresh apricot (Prunus armeniaca var. ansu Max.) were isolated by simultaneous distillation-extraction at two different pH values of 3.1 and 7.0 and by headspace trapping method. The volatiles were analyzed by GC and GC-MS. A total of 80 components were identified in the three aroma concentrates, including 9 naphthalene derivatives that were not previously reported in apricot. Of components identified in native pH (3.1) sample, the major components were aliphatic $C_6$ aldehydes and alcohols, monoterpene alcohols, benzyl alcohol, ${\beta}-phenylethyl$ alcohol and naphthalene derivatives, while those in neutral pH(7.0) sample and headspace volatiles were aliphatic $C_6$ aldehydes and alcohols. Simultaneous distillation-extraction at pH 3.1 was significantly increased the concentration of n-hexanal, trans-2-hexenal, cis-3-hexen-1-ol, linalool oxide, linalool, ${\alpha}-terpineol$, nerol, geraniol, benzyl alcohol, ${\beta}-phenylethyl$ alcohol and naphthalene derivatives. These results demonstrate that above the components are present in glycosidically bound forms in apricot.