• Journal of the Korean Society of Food Science and Nutrition
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• v.26 no.2
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• pp.270-284
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• 1997

Effects of dietary carotenoids were investigated on the metaboβsm and body pigmentation of rainbow trout(Salmo gairdneri), masu salmon(Oncorhynchus macrostomos), eel(Anguilla japonica), rock fish(Sebastes inermis) and black rock fish(Sebastes schlegeli). Three weeks later after depletion, these fishes were fed diet supplemented with ${\beta}-carotene$, lutein, canthaxanthin', astaxanthin or ${\beta}-apo-8'-carotenal$ for 4 to 5 weeks, respectively. Carotenoids distributed to and changed in integument were analyzed. In the integument of rainbow trout. zeaxanthin, ${\beta}-carotene$ and canthaxanthin were found to be the major carotenoids, while lutein, isocryptoxanthin and salmoxanthin were the minor carotenoids. In the integument of masu salmon, zeaxanthin was found to be the major carotenoids, while triol, lutein, tunaxanthin, ${\beta}-carotene$, ${\beta}-cryptoxanthin$ and canthaxanthin were the minor carotenoids. In the integument of eel, ${\beta}-carotene$ was found to be the major carotenoids, while lutein, zeaxanthin and ${\beta}-cryptoxanthin$ were the minor carotenoids. In the integument of rock fish, zeaxanthin, ${\beta}-carotene$, tunaxanthin$(A{\sim}C)$ and lutein were found to be the major carotenoids, while ${\beta}-cryptoxanthin$, ${\alpha}-cryptoxanthin$ and astaxanthin were the minor carotenoids. Likely in the integument of black rock fish, ${\beta}-carotene$, astaxanthin and zeaxanthin were found to be the major carotenoids, whereas ${\alpha}-cryptoxanthin$, ${\beta}-cryptoxanthin$, lutein and canthaxanthin were the minor contributor. The efficacy of body pigmentation by the accumulation of carotenoids in the integument of rainbow trout and masu salmon were the most effectively shown in the canthaxanthin group and of eel, rock fish and black rock fish were the most effectively shown in the lutein group. Based on these results in the integument of each fish, dietary carotenoids were presumably biotransformed via oxidative and reductive pathways. In the rainbow trout, ${\beta}-carotene$ was oxidized to astaxanthin via successively isocryptoxanthin, echinenone and canthaxanthin. Lutein was oxidized to canthaxanthin. Canthaxanthin was reduced to ${\beta}-carotene$ via isozeaxanthin, and astaxanthin was reduced to zeaxanthin via triol. In the masu salmon, ${\beta}-carotene$ was oxidized to zeaxanthin. Lutein was reduced to zeaxanthin via tunaxanthin. Canthaxanthin was reduced to zeaxanthin via ${\beta}-carotene$. and astaxanthin was reduced to zeaxanthin via triol. In the eel, ${\beta}-carotene$ and lutein were directly deposited but canthaxanthin was reduced to ${\beta}-carotene$, and cholesterol lowering effect by Meju supplementation might be resulted from the modulation of fecal axanthin, astaxanthin and ${\beta}-apo-8'-carotenal$ were oxidized and reduced to tunaxanthin via zeaxanthin. In the black roch fish, ${\beta}-carotene$ was oxidized to ${\beta}-cryptoxanthin$. Lutein was reduced to ${\beta}-carotene$ via ${\alpha}-cryptoxanthin$. Canthaxanthin was reduced to ${\alpha}-cryptoxanthin$ via successively ${\beta}-cryptoxanthin$ and zeaxanthin. Astaxanthin converted to tunaxanthin via isocryptoxanthin and zeaxanthin, and ${\beta}-apo-8'-carotenal$ was reduced to ${\alpha}-cryptoxanthin$ via ${\beta}-cryptoxanthin$ and zeaxanthin.

• Preventive Nutrition and Food Science
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• v.10 no.3
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• pp.219-223
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• 2005

[ $\beta-Cryptoxanthin$ ] content was determined in Shiranuhi mandarin fruits harvested at monthly intervals from October to February in Jeju Island. Crude carotenoids were extracted from both peel and flesh of Shiranuhi mandarin fruits and analyzed using TLC and HPLC; $\beta-cryptoxanthin$ was indicated the Rr value of 3.2 and retention time of 23 min, respectively. $\beta-Cryptoxanthin$ contents in both peel and flesh were increased gradually as the citrus fruits ripened fully until harvesting season (February). According to the harvesting time, $\beta-cryptoxanthin$ contents in the peel were $0.15\;mg\%\;(October),\;0.28\;mg\%\;(November),\;0.38\;mg\%\;(December),\;1.23\;mg\%\;(January),\;and\;1.71\;mg\%\;(February).$In the flesh, $\beta-cryptoxanthin$ contents were lower than those of peels, having $0.06\;mg\%\;(October),\;0.08\;mg\%\;(November),\;0.19\;mg\%\;(December),\;0.26\;mg\%\;(January),\;and\;0.65\;mg\%\;(February).$ These results demonstrate that $\beta-cryptoxanthin$ in Shiranuhi mandarin fruits accumulated during ripening of the citrus fruits. In particular, the peels had much higher concentrations of $\beta-cryptoxanthin$ and have potential for use as a functional ingredient.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.27 no.3
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• pp.265-271
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• 1994

Differences in carotenoid composition in the integuments of wild and cultured chinese muddy loach Misgurnus mizolepis and muddy loach Misgurnus anguillicaudatus were compared. Total carotenoid contents in the integuments of the wild and cultured chinese muddy loach were $4.76mg\%\;and\;3.43mg\%$, respectively. The important carotenoids in the integuments of the wild chinese muddy loach were lutein($30.5\%$), ${\beta}$-cryptoxanthin($24.6\%$), ${\beta}$-carotene($20.6\%$) and cynthiaxanthin($11.7\%$). In addition, zeaxanthin($4.7\%$), tunaxanthin ($4.5\%$), and a-cryptoxanthin($1.0\%$) were present in small amounts. In the integuments of the cultured chinese muddy loach, lutein($35.4\%$), ${\beta}$-cryptoxanthin($17.9\%$), cynthiaxanthin($16.0\%$) and ${\beta}$-carotene($12.7\%$) were present as important carotenoids. In addition, zeaxanthin($8.1\%$), tunaxanthin($5.0\%$), a-cryptoxanthin($0.9\%$) were found in small amounts. Total carotenoid contents in the integuments of the wild and cultured muddy loach were $4.00mg\%\;and\;2.99mg\%$, respectively. The important carotenoids in the integuments of the wild muddy loach were lutein($32.9\%$), ${\beta}$-cryptoxanthin($18.8\%$), cynthiaxanthin($17.0\%$) and ${\beta}$-carotene($15.1\%$). In addition, zeaxanthin($6.5\%$), tunaxanthin($6.0\%$) and a-cryptoxanthin($1.5\%$) were found in small amounts. In the integuments of the cultured muddy loach, lutein($51.8\%$), cynthiaxanthin($19.9\%$) and ${\beta}$-cryptoxanthin($10.8\%$) were observed as important carotenoids. In addition, ${\beta}$-carotene($5.0\%$), zeaxanthin($4.8\%$), tunaxanthin($4.5\%$) and a-cryptoxanthin($0.2\%$) were found in small amounts.

• Food Science and Biotechnology
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• v.14 no.4
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• pp.533-536
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• 2005

[ ${\beta}$-Cryptoxanthin ] contents were determined from Citrus unshiu Markovich fruits grown in a greenhouse and open field of Jeju Island, off the southern coast of Korea. In a greenhouse and open field, the ${\beta}$-cryptoxanthin content in the peel was greatly increased by harvesting citrus fruits in the late season from August through November. However, ${\beta}$-cryptoxanthin content in the flesh was gradually increased and was superior to that of the citrus fruits grown in a greenhouse. ${\beta}$-Cryptoxanthin was efficiently purified from the flesh of citrus fruits harvested in the late harvesting season in November. The ${\beta}$-cryptoxanthin contents in the peel and flesh of citrus fruits harvested from a greenhouse in November were 0.89 mg% and 0.35 mg%, respectively, and in that obtained from an open field were 1.12 mg% and 0.35 mg%, respectively.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.31 no.2
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• pp.278-287
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• 1998

Carotenoids in integument of wild manchurian trout, Brachymystax lenok, and wild and cultured masu salmon Oncohynchus macrostomus, which are all the Korean native cold fresh water fish, were investigated by thin layer chromatography, column chromatography and HPLC. The total carotenoid contents of the wild manchurian trout were $3.72\;mg\%$ which is relatively higher compare to other species of salmonidae. The carotenoids were composed of $36.9\%$ zeaxanthin and $14.7\%$ $\beta-carotene$ as the major compounds, $7.8\%$ triol $7.3\%$ isocryptoxanthin, $5.7\%$ 4-hydroxy echinenone, $4.7\%$ lutein, $4.5\%$ salmoxanthin and $2.2\%$ astaxanthin as minor compounds, and other carotenoids such as canthaxanthin, tunaxanthin A, tunaxanthin B, tunaxanthin C, $\beta-cryptoxanthin$ and $\alpha-cryptoxanthin$ as minute carotenoids. Wild masu salmon contained more total carotenoids than cultured one and the contents were $0.82\;mg\%$ and $0.66\;mg\%$, respectively. The composition of the carotenoids from wild masu salmon were $20.7\%$ xeaxanthin, $17.0\%$ isocryptoxanthin and $15.8\%\;\beta-carotene$ as major compounds, and $6.2\%$ triol, $6.1\%$ 4-hydroxy echinenone, $6.1\%$ salmoxanthin, $5.9\%$ canthaxanthin, $5.8\%$ lutein, $4.9\%$ $\alpha-cryptoxanthin$ and $1.0\%$ astaxanthin as minor compounds. The composition of the carotenoids from cultured masu salmon were $19.7\%$ isocryptoxanthin, $18.0\%$ $\beta-carotene$ and $10.3\%$ zeaxanthin as the major compounds, and $8.9\%\;\beta-cryptoxanthin$, $8.5\%\;\alpha-cryptoxanthin$, $8.0\%$ lutein, $7.6\%$ canthaxanthin, $5.1\%$ triol and $2.0\%$ astaxanthin as minor carotenoids. Based on these data, wild masu salmon contained more zeaxanthin, salmoxanthin and 4-hydroxy echinenone while cultured masu salmon contained more $\alpha-cryptoxanthin$, indicating that carotenoid pigment of masu salmon depends on their living conditions. Unlike wild masu salmon, 4-hydroxy echinenone and salmoxanthin which are the characteristic carotenoids of salmons, were not found in the integument of cultured masu salmon. Unlike manchurian trout, both wild and cultured masu salmon did not contain tunaxanthin A, tunaxanthin B and tunaxanthin C.

• Korean Journal of Food Science and Technology
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• v.35 no.6
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• pp.1104-1109
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• 2003

Response surface methodology (RSM) was used to investigate the effects of the processing parameters on supercritical $CO_2\;(SC-CO_2)$. extraction of total carotenoids and ${\beta}$-cyptoxanthin from Citrus unshiu press cake. The parameters tested were $SC-CO_2$ pressure, dynamic extraction time, and concentration of ethanol added as the modifier to $CO_2$. Experimental data correlated well with the processing parameters (p<0.01), and there was a high statistically significant multiple regression relationship for the extraction of total carotenoids and ${\beta}-cyrptoxanthin$ ($R^2=0.9789$ and 0.9796, respectively). The optimal processing conditions were extraction pressure 33.4 and 37.3 MPa, extraction time 39.6 and 41.0 min, ethanol concentration 18.6 and 17.0% for total carotenoids and ${\beta}-cryptozanthin$, respectively. Maximum extraction yields predicted by RSM were 61.1 and 95.8% ppm, respectively. The extraction yield of total carotenoids increased asymptotically with the increase of the extraction pressure. It increased in proportion to extraction time and concentration of the cosolvent. The extraction yield of ${\beta}-cryptoxanthin$ increased with extraction pressure, extraction time, and concentration of the cosolvent. The extraction time and the concentration of the cosolvent, and the interaction between extraction time and the concentration of the cosolvent significantly affected the extraction yields of carotenoids from C. unshiu press cake.

• Journal of Nutrition and Health
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• v.42 no.5
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• pp.464-473
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• 2009

The serum levels of antioxidant materials (${\alpha}$-carotene, ${\beta}$-carotene, ${\beta}$-cryptoxanthin, lutein, lycopene, ${\alpha}$-tocopherol, ${\gamma}$-tocopherol, retinol) of the healthy Korean middle-aged adults (n = 373) were measured and their relationships with the serum lipids and anthropometric indices were analyzed. The serum levels of ${\beta}$-cryptoxanthin, ${\beta}$-carotene, lutein were higher than those of lycopene and ${\alpha}$-carotene. The levels of all measured carotenoids except lutein were significantly higher in females than in males, but retinol level was vice versa. There was a tendency of increase in serum levels of antioxidant vitamins with increasing age. The serum carotenoid levels had a positive correlation with serum cholesterol and a negative correlation with serum triglyceride. The serum levels of tocopherols or retinol showed a significantly positive relationship with blood cholesterol or triglyceride. In overall, anthropometric indices showed negative relations with serum carotenoids levels, but vice versa with serum tocopherol or retinol levels. Particularly, ${\beta}$-carotene and lutein levels showed a significantly negative relation with blood pressure in male subjects. The serum levels of ${\alpha}$-carotene, ${\beta}$-carotene and ${\beta}$-cryptoxanthin had significantly negative relations with body fat-related indices in female subjects. The results demonstrated that blood antioxidants levels differed by sex and age, and had significant relations with blood lipid levels and anthropometric indices. Therefore, the rationale and significance of the relationships need to be elucidated in the future study related to dietary intakes and life style.

• Journal of Nutrition and Health
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• v.30 no.5
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• pp.489-498
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• 1997

Recent researches suggest that carotenoids are important not only as provitamin A but also for prevention of chronic diseases. This study was conduction to determine levels and factors affecting serum levels of lutein + zeaxanthin, $\beta$-cryptoxanthin, and $\beta$-carotene in 93 adults living in rural area of Korea. Fasting blood samples were collected and serum carotenoid levels were measured by HPLC. Dietary intake was estimated by 24 hour recall method and frequency questionnare of major food groups. Mean serum concentration of lutein + zeaxanthin was 616.32 nmol/L, $\beta$-cryptoxanthin was 856.95nmol/L, and $\beta$-carotene was 242.90nmol/L. Serum $\beta$-carotene levels in study subjects were very low. Both $\beta$-cryptxanthin and $\beta$-carotene were negatively correlated with serum triglyceride and positively correlated with total-choesterol and LDL-cholesterol. Serum levels of female subjects were significantly higher than males in all carotenoids. For age groups, subjects in their 30's were shown to have the highest concentration of all carotenoids. Lutein + zeaxanthin were lowest in subjects in theri 40's while $\beta$-crytoxanthin and $\beta$-carotene levels were lowest in subjects in their 60's. The $\beta$-carotene levels in non-smokers were significantly higher than in drinkers. Lutein+zeaxanthin levels were significantly higher among subjects consuming more green and yellow vegetables by frequency questionnarie. In conclusion, serum carotenoids were affected by sex, age, serum lipids, smoking, and alcohol intake. Intake of vegetables and fruits could affect by sex, serum lipids, smoking, and alchol intake. Intake of vegetables and fruits could affect serum lutein+zeaxanthin level. This data indicated that compared to other studies, Korean adults in rural areas have high lutein+zeaxanthin concentratins and low $\beta$-carotene concentrations in serum. High lutein+zeaxanthin levels may be related to high consumption of vegetables in these subjects.

• Journal of the Korean Society of Food Science and Nutrition
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• v.21 no.4
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• pp.407-413
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• 1992

Difference of carotenoid pigments in integuments of the wild and cultured flounder, Paralichthys olivaceus and yellowtail, Seriola quinqueradiata were studied. Total carotenoid contents in integuments of the wild and cultured flounder were 1.38mg% and 1.l6mg%, respectively. The main carotenoids in integuments of the wild flonder were zeaxanthin (19.22%), $\beta$-carotene type triol (17.80%), tunaxanthin C (17.77％), lutein (16.44%) and tunaxanthin B (13.70%). In addition, tunaxanthin A (5.42%), $\alpha$-cryptoxanthin (4.80%), astaxanthin (0.69%) and $\beta$-cryptoxanthin (0.24%) were also contained in small amounts. But in the cultured flounder, lutein (38.21%) and zeaxanthin (29.69%) were contained as main carotenoids. In addition, $\beta$-carotene type triol (7.80%), tunaxanthin C (7.05%), $\alpha$-cryptoxanthin (4.34%), tunaxanthin B (4.21%), as-taxanthin (2.40%) and $\beta$-cryptoxanthin (1.30%) were present in small amounts. Consequently, the wild flounder contained higher amounts of tunaxanthin and trios but contained lower amounts of lutein and zeaxanthin than the cultured flonder. The contents of carotenoids from integuments of wild and cultured yellow-tail were 1.08mg% and 0.09mg%. Wild and cultured yellowtail have similar carotenoid patterns, consisting of tunaxanthin C (44.11%, 43.37％), tunaxanthin B (33.56%, 29.23%) and tunaxanthin A (18.22%, 21.68%), respectively.

• Journal of Nutrition and Health
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• v.34 no.4
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• pp.401-408
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• 2001

The spontaneous frequency of genetic damage and the possible relationship of this damage to total radical-trapping antioxidant potential(TRAP) and antioxidant vitamins, including plasma levels of $\alpha$-carotene, $\beta$-carotene, cryptoxanthin, retinol, $\alpha$-tocopherol and ${\gamma}$-tocopherol in humans were investigated in 57 subjects using two indices of genetic damage, SCE & HFC frequency. The mean of SCE and HFC frequencies were weakly correlated with plasma TRAP(r=-0.305, p<0.1 for SCEs: r=-0.297, p<0.1 for HFCs, respectively), but those were strongly negatively correlated with plasma $\beta$-carotence(r=-0.385, p<0.01 for SCEs : r=-0.392, p<0.01 for HFCs) and cryptoxanthin(r=-0.312, p<0.05 for SCEs : r=0.335, p<0.05 for HFCs, respectively) levels in the subjects. However, those DNA damage markers including SCE and HFC did not correlate with either plasma $\alpha$-carotene, $\alpha$-tocopherol or retinol concentrations. The mean of SCE and HFC frequencies were positively correlated with plasma ${\gamma}$-tocopherol level(r=0.421, p<0.01 for SCEs : r=0.399, p<0.01 for HFCs, respectively). These findings indicate that increased cytogenetic DNA changes, as determined by SCE and HFC frequencies are possibly associated with generation of free radicals in lymphocytes and decreased plasma antioxidant vitamin($\beta$-carotene and cryptoxanthin) status in the subjects. (Korean J Nutrition 34(4) : 401~08, 2001)