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1. |
Objectives |
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C R C Critical Reviews in Food Science and Nutrition,
Volume 17,
Issue 3,
1983,
Page 1-1
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PDF (44KB)
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ISSN:0099-0248
DOI:10.1080/10408398209527347
出版商:Taylor & Francis Group
年代:1983
数据来源: Taylor
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2. |
Ginger — chemistry, technology, and quality evaluation: Part 2 |
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C R C Critical Reviews in Food Science and Nutrition,
Volume 17,
Issue 3,
1983,
Page 189-258
V. S. Govindarajan,
D. W. Connell,
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PDF (4406KB)
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摘要:
Ginger is used in more ways than any other spice. This monograph, published in two parts, comprehensively reviews production, trade, processing, chemistry, and evaluation of quality. Botany, world varieties, agronomy, crop improvement, and potential are reviewed briefly with emphasis on the yield of functional components. Processing for the market, international trade patterns and factors influencing them are discussed. Derived products such as ginger powder, syruped ginger, volatile oil, and oleoresin are discussed in greater detail. The increasing world demand for quality products of added value such as the oleoresin and volatile oil show the prospects for their production in the growing countries. The chemistry of the components which contribute aroma and pungency that characterize ginger is critically reviewed. The second part deals with evaluation of quality. The physicochemical parameters prescribed as a measure of quality for ginger and its products in the existing standards, can assure only hygienic quality and purity, and possibly the source, when new parameters such as GC‐finger prints are included. The importance of sensorily evaluating flavor quality is emphasized to understand the variation in flavor quality required by the industrial and retail markets. Related areas, such as problems in sensory evaluation of intense flavored substances, objective flavor profile analysis, correlation of instrumental and sensory data are discussed, and our recent work in this area is summarized. Areas where more research is needed are indicated. Other areas briefly discussed are functional, physiological, and toxicological properties in use of ginger; biosynthetic aspects of the components stimulating flavor, structure and pungency and chemistry of spices from allied species and genera. A comprehensive bibliography is provided to aid in further study and research.
ISSN:0099-0248
DOI:10.1080/10408398209527348
出版商:Taylor & Francis Group
年代:1983
数据来源: Taylor
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3. |
Cassava as a food |
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C R C Critical Reviews in Food Science and Nutrition,
Volume 17,
Issue 3,
1983,
Page 259-275
B. Onuma Okezie,
FrankV. Kosikowski,
Pericles Markakis,
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摘要:
This review has attempted to examine information pertaining to the role of cassava(Manihot esculenta)as a major food source for a large part of the world population, particularly the countries of South America, Africa, and Asia, where it is primarily a major source of energy for 300 to 500 million people. Its cultivation, usually on small farms with little technology, is estimated to cover on an annual basis about 11 million hectares providing about 105 million tons, more than half of which is consumed by humans. The importance of cassava as an energy source can be seen by its growing demand in the European economic community countries where it forms up to 60% of the balanced diets for swine. Cassava is one of the crops that converts the greatest amount of solar energy into soluble carbohydrates per unit of area, thus 1 kg of moisture‐free cassava meal may yield up to about 3750 kcal which would mean that a yearly production of 15 tons of cassava meal per hectare would yield some 56 million kcal. The major limitations of cassava as food appear to be its poor protein content and quality and the rapid post harvest deterioration of its roots which usually prevents their storage in the fresh state for more than a few days. However, in addition to its use for culinary purposes, cassava finds application in industrial products such as an adhesive for laundry purposes, for manufacturing paper, alcohol, butanol, dextrin, adhesive tape, textile sizing, and glue.
ISSN:0099-0248
DOI:10.1080/10408398209527349
出版商:Taylor & Francis Group
年代:1983
数据来源: Taylor
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4. |
Chemical, biochemical, and biological significance of polyphenols in cereals and legumes |
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C R C Critical Reviews in Food Science and Nutrition,
Volume 17,
Issue 3,
1983,
Page 277-305
D. K. Salunkhe,
S. J. Jadhav,
S. S. Kadam,
J. K. Chavan,
B. S. Luh,
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摘要:
Polyphenols in cereals and legumes have been receiving considerable attention largely because of their adverse influence on color, flavor, and nutritional quality. These compounds belong to the flavonoid and tannin groups and are mostly located in the seed coat or pericarp of the grains. The pearl millet flavonoids have been identified as C‐glycosylflavones by the combined use of paper chromatography and UV spectroscopy. Although nontoxic, physiological and nutritional significance of these compounds occurring in high amounts in the pearl millet grain are still not clearly understood. In view of aesthetic quality, bleaching of the millet grains in acidic solution is recommended. A large proportion of current assays involves spectrophotometry of tannin or its chromogen and tannin‐protein interaction. Sorghum and legume tannins have been characterized as condensed tannins. Several factors such as plant type, age of the plant or plant parts, stage of development, and environmental conditions govern the polyphenol contents in plants. Polyphenols are known to interact with proteins and form tannin‐protein complexes leading to either inactivation of enzymes or making proteins insoluble. These are implicated in decreasing the activities of digestive enzymes, protein and amino acid availabilities, mineral uptake, vitamin metabolism, and depression of growth. Polyphenols are known to cause certain ultrastructural changes in the different parts of experimental animals. A correlation between dietary tannins and occurrence of esophageal cancer has been established. Bird resistance and seed germination in food crops have been correlated to high contents of polyphenols. The antinutritional activity of polyphenols can be reduced by removing polyphenols from the grains by chemical treatments or removing pericarp and testa by pearling. Treatment of alkaline reagents and ammonia can remove 90% of the polyphenols. Supplementation of polyphenols‐rich diet with protein can alleviate the growth‐depressing effect of polyphenols.
ISSN:0099-0248
DOI:10.1080/10408398209527350
出版商:Taylor & Francis Group
年代:1983
数据来源: Taylor
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