• The Korean Journal of Food And Nutrition
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• v.19 no.4
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• pp.374-380
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• 2006

For the improvement of Gulbi processing, yellow corvenia was salted by 2 different time (5 hours, low salted and 5 days, high salted) and then dried in the sun and stored for 5 and 21 days, respectively. Malonaldehyde contents and fatty acid composition were analyzed during Gulbi processing. The moisture contents of yellow corvenia were significantly decreased during processing procedure. The salt contents were 10 folds higher in 5 day-salted sample than in 5 hour-salted one. The salt contents showed reversed tendency to moisture contents. There was little change in pH during storage. The contents of malonaldehyde in yellow corvenia were increased during Gulbi processing and storage. Its contents were higher in 5 day-salted sample and exterior parts than 5 hour-salted sample and interior parts of Gulbi. The fatty acids composition showed higher oleic acid $(C_{18:1})$, palmitic acid $(C_{16:0})$ and docosahexaenoic acid $(C_{22:6})$ than any other fatty acids in Gulbi. Saturated fatty acids were increased but unsaturated fatty acids were decreased during Gulbi processing. After 21 days storage, unsaturated fatty acids remaining ratio in 5 hour-and 5 day-salted sample were 1.39 and 0.99 respectively. The contents of unsaturated fatty acids were dramatically changed as salt concentration increased during storage than in processing.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.18 no.4
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• pp.325-332
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• 1985

As a series of study for processing low salt fermented fish, this work was undertaken to investigate taste compounds of low sodium salt fermented anchovy and yellow corvenia comparing with conventional fermented fish ($20\%$ of salt contents) during the fermentation of 120 days at $25{\pm}3^{\circ}C$. The major amino acids in fermented anchovy at 60 day fermentation were lysine, alanine, leucine, valine, isoleucine, histidine, threonine and glycine, while those in fermented yellow corvenia at 90 day fermentation were lysine, leucine, alanine, valine, threonine, isoleucine, glutamic acid and methionine. These amino acids held $57\%$ of the total extractive nitrogen content for fermented anchovy and $41\%$ for fermented yellow corvenia, respectively. It was supposed from the results that principal taste compounds both for fermented anchovy and fermented yellow corvenia were free amino acids, and that nucleotides and their related compounds as well as total creatinine also played an assistant role. And also there was little difference between taste compounds of low salt fermented fish and those of conventional fermented fish irrespective of fish species.

• Korean Journal of Food Science and Technology
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• v.8 no.4
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• pp.225-229
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• 1976

Gulbi, salted and dried yellow corvenia, is one of widely consuming fish foods in this country. This study was attempted to establish the basic data for evaluating the taste compounds of Gulbi. The free amino acids were analysed by amino acid autoanalyser. In the free amino acid composition of raw yellow corvenia, abundant amino acids were glutamic acid, alanine and lysine and then leucine, glycine, serine and threonine in order. Such amino acids like proline, valine, methionine, tyrosine and phenylalanine were poor in content. The changes of free amino acid composition in the extract of yellow corvenia during Gulbi processing was not observed. In the extract of Gulbi product, glutamic acid, lysine, leucine, alanine and valine were dominant holding 20.0%, 12.9%, 11.1%, 10.1% and 8.5% of total amino acids respectively. The amounts of total free amino acids of yellow corvenia increased more than 3.6 times as compared with that of raw sample during Gulbi processing. It is convinced that the characteristic flavor of Gulbi was attributed to such amino acids like lysine and alanine known as kweet compounds, as glutamic acid with meaty taste, and as leucine known as bitter taste.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.18 no.3
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• pp.206-213
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• 1985

Since a long time ago, more than thirty kinds of fermented fish product have traditionally been favored and consumed in Korea. In general, they fermented with $20\%$ of sodium chloride. However, it has been currently known that sodium chloride is one of causative ingredient for adult diseases. For that reason, reduced sodium salt diet is recently recommended in developed countries. This study was attempted to process low sodium salt fermented fish using anchovy, Engraulis japonica, and yellow corvenia, Psedosciaena manchurica, as raw materials with partially replacing the sodium salt with potassium chloride. The most favorable taste for fermented anchovy and yellow corvenia were revealed at 60 and 90 days fermentation, respectively. Judging from sensory evaluation with variance of analysis and orthogonal contrast method, little difference of taste were found when sodium salt was replaced with KCl even by $50\%$ as compared with conventional fermented fish. Taste for low salt fermented anchovy and yellow corvenia were the most favorable when they were prepared with $4\%$ salt, $4\%$ KCl, $6\%$ sorbitol, $0.5\%$ lactic acid and $4\%$ alcohol extract of red pepper as preservatives and flavor enhancers.

• Journal of the Korean Society of Food Science and Nutrition
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• v.15 no.3
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• pp.263-275
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• 1986

Gulbi were processed by salting Yellow corvenia (Pseudosciaena manchurica) with in three ways: the dry salting method with bar salt, the dry salting method with purified salt or with the abdominal brine injection method with purified salt. The half of the sample was dried by the control system of temperature and humidity; the other part was dried by the natural condition. The moisture content of fresh Yellow corvenia muscle and eggs were 76.8%, and 68.2% while those of dried samples decreased to 57.7% and 45.3%, respectively. The total nitrogen content of fresh muscle and eggs were 11.0g% and 7.6g%, respectively (dry weight basis), which decreased slightly during salting and showed no significant changes during drying prosess. The protein nitrogen content of fresh muscle and eggs were 10.2g% and 7.5g%, which decreased during Gulbi processing. On the other hand, the nonprotein nitrogen content of both muscle and eggs increased. The content of free amino acids of fresh muscle and eggs were 508.8mg/100g and 1,110.6mg/100g, which increased to between 5.3 and 2.7 times, respectively after 25 days of drying. The composition patterns of free amino acids in muscle and eggs were similar to each other. The four amino acids - Ala, Glu, Lys and Leu - were most abundant in both fresh and dried samples. These amino acids are known as taste and flavour constituents.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.19 no.6
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• pp.529-536
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• 1986

By modified method yellow corvenia(called $Y_3$) was prepared with $4\%$ salt, $4\%$ KCl, $6\%$ sorbitol, $0.5\%$ lactic acid and $4\%$ alcohol extract of red pepper to improve the quality of fermented sea food. In this study, changes of volatile compounds and fatty acid composition obtained from modified fermented yellow corvenia($Y_3$) were experimented during fermentation, comparing with conventional fermented yellow corvenia(called $Y_1,\;20\%$ of salt contents). Total lipid of yellow corvenia was composed of $78.1\%$ of neutral lipid, $21.2\%$ of phospholipid and $0.7\%$ of glycolipid. And monoeonoic acid was held $37.4\%$ of fatty acid composition of total lipid and saturated fatty acid ($34.8\%$), polyenoic acid ($27.7\%$) were followed. Saturated fatty acid($C_{14:0},\;C_{16:0},\;C_{18:0}$) in $Y_1,\;Y_3$ increased, polyenoic acid ($C_{22:6}\;C_{22:5}\;C_{20:5}$) decreased while monoenoic acid($C_{16:1}\;C_{18:1}$) in those was little fluctuated during fermentation. Thirty-three kinds of volatile component in whole volatile compounds obtained from $Y_1,\;Y_3$ at 90 days fermentation were identified, and composed of some hydrocarbons (8 kinds), alcohols (7 kinds), acids (6 kinds), aldehydes(4 kinds), sulfides(2 kinds), ketones (2 kinds), one of phenol and 3 kinds of the other components. Among the whole volatile compounds 2-ethoxy ethanol and was held $79.35\%$ in $Y_3$, whereas nonadecane was held $75.85\%$ in $Y_1$. During fermentation 8 kinds of volatile acids, 5 kinds of amines and 9 kinds of carbonyl compounds were also detected. Those volatile acid such as acetic acid, isovaleric acid, n-caproic acid, n-butyric acid were the major portion of total volatile acids in $Y_3$ at 90 days fermentation. Meanwhile, carbonyl compounds such as ethanal, 2-butanone and butanal were the major ones, while TMA held the most part of volatile amines in $Y_3$ during fermentation. From the result of sniff test, the components which are believed to contribute to the characteristic flavor of fermented product $Y_1,\;Y_3$ are deduced to be volatile acid, carbonyl compounds and amines in order. Conclusively, there was little difference in composition of volatile components, but merely a little difference in content of those between $Y_3$ and $Y_1$.

• Journal of the Korean Society of Food Science and Nutrition
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• v.18 no.2
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• pp.143-152
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• 1989

Some sugars and proteins were mixed with yellow corvenia lipids, soybean lipids or see yolk lipids to study the influence of the sugars or proteins on lipid oxidation and browning in dry and wet system during kept at $40^{\circ}C$. In the yellow corvenia lipids mixed with various food components, peroxide value(POV), carbonyl value(COV) and brown pigments were much higher than the case that soybean lipids or egg folk lipids were mixed. In terms of the food components, they appealed high in glucose, sucrose and starch but low in albumin and casein. When the soybean lipids were mixed, POV appeared low in all these maxture. COV and brown pigments appeared high in glucose, sucrose and starch but low in albumin and casein. In the case of egg york lipids, POV appeared lower than that of soybean lipids but COV and brown pigments were similar. In the starch mixture of three lipids in wet system, POV and COV in yellow corvenia lipids appealed lower, but appeared higher in soybean lipids and egg yolk lipids than those in dry system. Brown pigments appeared similarly with the case in dry system. And the all mixtures of casein in wet system, POV and COV appealed lower thanthose of the dry system, but brown pigments appeared high.

• Korean journal of food and cookery science
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• v.2 no.2
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• pp.1-7
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• 1986

Gulbi were made by salting Yellow corvenia (Pseudosciaena manchurica) with the in three ways: the dry salting method with bay salt, the dry salting method with purified salt or with the abdominal brine injection method with purifie salt. The half of the sample was dried by the control system of temperature and humidity: the other part was dried by the natural condition. In fresh muscle, the content of IMP, hypoxanthine, inosine and AMP were $13.40,\;9.28,\;3.01{\mu}mole/g$ and trace amount, dry basis, respectively. In fresh egg, the content of AMP, hypoxanthine, inosine and IMP were 13.98, 6.56, 1.98 and $1.93{\mu}mole/g$, dry basis, respectively. During the drying process of Yellow corvenia, the content of hypoxanthine increased remarkably, while the content of AMP, IMP and inosine decreased ana remained as trace amount. It can be suggested that the characteristic flavor of Gulbi is not attributed to the nucleotides and their related compounds but rather to free amino acids.

• Applied Biological Chemistry
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• v.16 no.1
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• pp.49-52
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• 1973

The following is the test result of a clculation of the quantity of flavor content, that is, sixteen different kinds of free amino acid, found in both fresh and dried fish used widely as foodstuff here in Korea. 1. Throughout our test we were able to extract only a small amount of arginine though the amount of lysine, histidine, glycine, alanine and glutamic acid was comparatively large. 2. The test also showed that the amount of lysine decreased when a given fish dried up. The amount of methionine decreased in the case of Alaskan pollack though it increased in the case of Yellow corvenia. We also learned in our experiment that the amount of other flavor components increased though in varying degrees. 3. On the other hand, the content of free amino acid found in Yellow corvenia was much higher than in Alaskan pollack 4. And lastly, the test showed us that if and when the inflence of free amino acid is viewed strictly as a flavor-producing component, dried fish has much more flavor (and taste) than fresh fish.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.9 no.2
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• pp.129-142
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• 1976

Optimum doses The optimum dose that may be defined as the dose below the maximum permissible dose, yet would bring about a significant storage life extension at refrigerated temperatures, varied with species of fish as well as with the postirradiation storage temperatures. Thus the dose of 0. 1 Mrad was considered to be optimum for the croaker and yellow corvenia at $0^{\circ}C$, while at $5^{\circ}C$ the dose of 0.2 Mrad would be suitable for both species. The roundnose flounder was more radiosensitive and even at the dose of 0.1 Mrad a slight irradiation odor was detected immediately after the radiation treatment. Such degree of irradiation odor disappeared upon storage, therefore, the dose of 0.1 Mrad was considered to be optimum for the roundnose flounder at both $0^{\circ}\;and\;5^{\circ}C$. Storage life extension The croaker meats irradiated at 0.1 Mrad could be held at $0^{\circ}C$ as long as 5 weeks in good acceptable conditions, while the unirradiated control became unacceptable within 2 weeks-3-4 for extension of storage life at $0^{\circ}C$. At the storage temperature of $5^{\circ}C$, the storage life of 0.2 Mrad irradiated samples was extended from less than one week to 4 weeks--4-5 fold extension. The storage life extension of 0.1 Mrad irradiated yellow corvenia at $0^{\circ}C$ was from less than 2 weeks for the unirradiated to 4 weeks-approximately a-s folds and that of 0.2 Mrad irradiated samples stored at $5^{\circ}C$ was from 5 days to 3 weeks 4-5 folds. The roundnose flounder meats irradiated at 0.1 Mrad could held at $0^{\circ}C$ for 3-4 weeks as compared to less than 1 week for the unirradiated and at $5^{\circ}C$ the storage life could be extended from less than 3 days to up to 3 weeks. Thus the storage life extension by 4-5 folds and by 6-7 folds was possible at $0^{\circ}C\;and\;5^{\circ}C$ storage, respectively. Postirradiation storage microbiology and biochemistry In general 10 fold reduction of initial microflora was realized as a result of irradiating fish samples at 0.1 Mrad. The extent of microflora reduction increased with increasing doses applied, but not proportionately dependent. The microbial growth in the irradiated was severely retarded during the subsequent storage period, lagging far behind that of the irradiated control samples except in the late storage phase, when the levels of microflora of the irradiated either approached to or rose above the levels of the unirradiated. The microbiological changes caused by irradiation was reflected in the pronounced suppression of TVB and TMA accumulation during the storage period. This suggests that irradiation treatment brought about both quantitative and qualitative changes in microflora initially present and it is reasonable to suggest that the microflora removed by irradiation in fact represent most of the flora capable of producing TVB and TMA in normal fish spoilage process.