Muskmelon (Cucumis melo) is a vegetable much appreciated by the Cameroonian population. The aim of this study was to investigate the effect of development stage on morphological and physicochemical characteristics of the fruit. These parameters were studied from the third to the seventh week after fruit set. The average weight, fruit size and proportions of the different fractions (peel, mesocarp and endocarp) were evaluated. Some physicochemical and antioxidant properties were also determined. Results showed that morphological parameters increased significantly (p<0.05) during the development of the fruit of Cucumis melo. From the third to the seventh week after fruit set, the average weight varied from 105 to 404 g. During the maturation of fruit, the weight of mesocarp was higher than that of endocarp. The studied physicochemical parameters, varied from a fruit fraction to another and also depended on the development stage. Results showed that the weight ratio of mesocarp (44-42%) decreased meanwhile that of endocarp (41-44%) increased down the growth. During the maturation of fruit, the proteins content of peels decreased from 1.7 to 0.4 mg / g, while that of mesocarp and endocarp increased from 0.14 to 0.48 mg / g and from 1.38 to 4.26, respectively. At stage 1 of development, the peels were two times richer in vitamin C (14.9 µg / g) than the other fruit fractions (4.17-8.38). However, from stage 2 to stage 5 (full maturation), the mesocarp and endocarp appeared by far richer. The minerals requirements can be satisfy by the mesocarp or endocarp of Cucumis melo fruit harvested at five week after fruit set (stage 3). However, antioxidant capacity, carbohydrates, proteins and vitamin C are high in the fruit at stage 4 or 5.
| Published in | Journal of Food and Nutrition Sciences (Volume 4, Issue 1) |
| DOI | 10.11648/j.jfns.20160401.14 |
| Page(s) | 18-28 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Cucumis melo Fruit, Growing Stage, Morphological Parameters, Physicochemical Properties
| [1] | Judd W. S., Campbell C. S., Kellogg E. A., Stevens P. F. & Donoghue M. J. (2002). Sistemática de Plantas: A Phylogenetic Approach, 2nd ed. (Cucurbitales). Sinauer Associates, Sunderland, Massachusetts, Wallingford, UK, 576p. |
| [2] | Matthews M. L. & Endress P. K. (2004). Estructuras florales y sistemática comparada en Cucurbitales (Corynocarpaceae, Coriariaceae, Tetramelaceae, Datiscaceae, Begoniaceae, Cucurbitaceae, Anisophylleaceae), Botanical Journal of Linnean Society, 145(2), 129-185. |
| [3] | Lester R. N., Jaeger P. M. L., Bleijendaal-Spierings B. H. M., Bleijendaal H. P. O. & Holloway H. L. O. (1990). African eggplants: a review of collecting in West Africa, Plant Genetic Resources Newsletter, (81/82), 17-26. |
| [4] | Haldhar S. M., Bhargava R., Choudhary B. R., Pal G. & Kumar S. (2013). Allelochemical resistance traits of muskmelon (Cucumis melo) against the fruit fly (Bactrocera cucurbitae) in a hot arid region of India, Phytoparasitica, 41(4), 473-481. |
| [5] | Goodwin J. S. & Brodwick M. (1995). Diet, aging and cancer, Clinics in Geriatric Medicine 11, 577-589. |
| [6] | Rimm E. B., Klatsky A., Grobbee D. & Stampfer M. J. (1996). Review of moderate alcohol consumption and reduced risk of coronary heart disease: Is the effect due to beer, wine, or spirits? British Medical Journal, 312, 731-736. |
| [7] | Pitrat M. (2008). Melon, In: Prohens J., Nuez F. (Eds.), Vegetables 1 (pp. 283-315) USA: Springer. |
| [8] | Shalit M., Katzir N., Tadmor Y., Larkov O., Burger Y., Shalekhet F., Lastochkin E., Ravid U., Amar O., Edelsten M. & Lewinsolhn E. (2001). Acetyl CoA: alcohol acetyl transferase activity and aroma formation in ripening melon fruits, Journal Agricultural and Food Chemistry, 49, 794-799. |
| [9] | Yuan D. B., Yang X. Q., Tang C. H., Zheng Z. X., Min W., Ahmad I. & Yin S. W. (2009). Physicochemical and functional properties of acidic and basic polypeptides of soy glycinin, Food Research International, 42, 700-706. |
| [10] | Adams C. F. & Richardson M. (1981). Nutritive value of foods, USDA home and Garden Bul. 72. Government Printing Office, Washington D. C. |
| [11] | Al-Khalifa A. S. (1996). Physicochemical characteristics, fatty acid composition and lipoxygenase activity of crude pumpkin and melon seed oils, Journal of Agricultural and Food Chemistry, 44(4), 964-966. |
| [12] | Azhari S., Xu Y. S., Q. X. Jiang & W. S. Xia (2014). Physochemical properties and chemical composition of Seinat (Cucumus melo var Tibish) seeds oil and its antioxidant activity, Gracas Aceites, 65(1), e008. |
| [13] | AOAC. (1990). Official methods of analysis of AOAC International (15th Ed). In: Herwitz W. (Ed.), Association of Official Analytical Chemists. Washington DC, 132 pp. 125-126. |
| [14] | Kansci G., Koubala B. B. & Mbome L. I. (2003). Effect of ripening on the composition and the suitability for jam processing of different varieties of mango (Mangifera indica), African Journal of Biotechnology, 2 (9) 301-306. |
| [15] | Michel M. C. (1968). Dosage des acides aminés et amines par la ninhydrine. Amélioration pratique, Annal de Biologie Animale, Biochimie, Biophysique, 8, 557-563. |
| [16] | Devani M. B., Shishoo C. J., Shal S. A. & Suhagia B. N. (1989). Spectrophotometric method for microdetermination of nitrogen in Kjedahl digest, Journal of the Association of Official Agricultural Chemists, 72(6), 953-956. |
| [17] | AFNOR (Association Française pour la Normalisation) (1984). Produits alimentaires: directives générales pour le dosage de l’azote avec minéralisation selon la méthode de kjedahl. Dans: Godon, Pineau (Eds), Guide Pratique des Céréales, Apria, France, 4 263-266. |
| [18] | Tollier M. T. & Robin J. P. (1979). Adaptation de la méthode à l’orcinol sulfurique au dosage automatique des glucides neuters totaux. Conditions d’adaptation aux extraits d’origine végétale, Annales de Technologie Agricole, 28, 1-15. |
| [19] | Koubala B. B., Mbome L. I., Kansci G., Mbiapo F. T., Crépeau M. -J. & Thibault J. -F. (2008). Physicochemical properties of pectins from ambarella peels (Spondias cytherea) obtained using different extraction conditions, Food Chemistry, 106, 1202-1207. |
| [20] | Jarvis C. E. & Walker J. R. L. (1993). Stimultaneous, rapid, spectrophotemetric determination of total starch, amylolose and amylopectin, Journal of the Science Food and Agriculture, 63, 53-57. |
| [21] | Kuniak L. & Marchessault R. H. (1972). Study of cross-linking reaction between epichlorhydrine and starch, Starch-Starke, 4, 110-116. |
| [22] | Barakat M. Z. & Abdalla A. (1965). The Ascorbic Acid Content of Edible Liver, Journal of Food Science, 30(2), 185-187. |
| [23] | Singleton V. L., Orthofer R. & Lamuela-Raventos (1999). Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent, Methods in Enzymology, 299, 152-178. |
| [24] | Benzie I. F. F. & Strain J. J. (1996). The ferric reducing ability of plasma (FRAP) as a measure of “antioxidant power”: the FRAP assay, Analytical Biochemistry, 239, 70-76. |
| [25] | Sun T., Tang J. & Powers J. R. (2005). Effect of pectolytic enzyme preparations on the phenolic composition and antioxydant activiy of asparagus juice, Journal Agricultural and Food Chemistry, 113, 964-969. |
| [26] | Ahmed O. K. (2009). Evaluation of Objective Maturity Indices for Muskmelon (Cucumis melo) cv."Galia", Journal of King Abdulazi University-Science, 21 (2), 317-326. |
| [27] | Crane J. C. (1964). Growth substances in fruit setting and development, Annual Review of Plant Physiology, 15, 303-326. |
| [28] | Villanueva M. J., Tenorio M. D., Esteban M. A. & Mendoza M. C. (2004). Compositional changes during ripening of two cultivars of muskmelon fruits, Food Chemistry, 87, 179-185. |
| [29] | Bernadac A., Jean-Baptiste I., Bertoni G. & Morard P. (1996). Changes in calcium contents during melon (Cucumis melo L.) fruit development, Scientia Horticulturae, 66(3), 181-189. |
| [30] | Parveen S., Ali M. A., Asghar M., Khan A. R. & Salam A. (2012). Physico-chemical changes in muskmelon (Cucumis melo L.) as affected by harvest maturity stage, Journal of Agricultural Research, 50(2), 249-250. |
| [31] | Beaulieu J. C. & Lea J. M. (2007). Quality changes in cantaloupe during growth, maturation, and in stored fresh-cut cubes prepared from fruit harvested at various maturities, Journal of American Society for Horticultural Science, 132(5), 720-728. |
| [32] | Bianchi T., Guerrero L., Gratacós-Cubarsí M., Claret A., Argyris J., Gracia-Mas J. & Hortós M. (2016). Textural properties of different melon (Cucumis melo L.) fruit types: Sensory and physical-chemical evaluation. Scientia Horticulturae, 201, 46-56. |
| [33] | Ozawa T., Lilley T. H. & Haslam E. (1987). Polyphenol interactions: astringency and the loss of astringency on ripening fruit, Phytochemistry, 26, 2937-2942. |
| [34] | Cheftel J. C. & Cheftel H. (1992). Introduction à la Biochimie et à la Technologie des aliments, Technique et Documentation Ed., Paris 1, 147-241. |
| [35] | Moneruzzaman K. M., Hossain A. B. M. S., Sani W. & Saifuddin M. (2008). Effect of stages of maturity and ripening conditions on the physical characteristics of tomato, American Journal of Biochemistry and Biotechnology, 4(4), 329-335. |
| [36] | Nuñez-Palenius H. G., Gomez-Lim M. & Ochoa-Alejo N. (2008). Melon Fruits: Genetic Diversity, Physiology, and Biotechnology Features, Critical Reviews in Biotechnology, 28, 13-55. |
| [37] | De Souza P. A., Simões A. D. N., Puiatti M. & Junior J. G. (2013). Da Silva Vieira M. R. Carbohydrate metabolism and quality of fruits from the Cucumis genus, Academia Journal of Agricultural Research, 1(7), 101-105. |
| [38] | Rowan K. S., Mcglasson W. B. & Pratt H. K. (1969). Changes in Adenosine Pyrophosphates in Cantaloupe Fruit Ripening Normally and after Treatment with Ethylene, Journal of Experimental Botany, 20, 145-155. |
| [39] | Abu-Goukh A. -B. A., Baraka Al F. M. & Elballa M. M. A. (2011). Physico-chemical changes during growth and development of ‘Galia’ cantaloupes. II. Chemical changes, Agriculture and Biological Journal of North America, 2(6), 952-963. |
| [40] | Wills R., McGlasson B., Graham D. & Joyce D. (1998). Postharvest: An introduction to the physiology and handling of fruit, vegetables and ornamentals, Wallingford: CAB International, 262 p. |
| [41] | Mc Cartney L. & Knox J. P. (2002). Regulation of pectic polysaccharide domains in relation to cell development and cell properties in the pea testa, Journal of Experimental Botany, 533 (369), 707- 713. |
| [42] | Koubala B. B., Kansci G., Garnier C., Thibault J. -F. & Ralet M. -C. (2013). Physicochemical properties of dietary fibres prepared from ambarella (Spondias cytherea) and mango (Mangifera indica) peels, Food and Bioprocess Technology, 6(2), 591-597. |
| [43] | Leja M., Kamińska I., Kramer M., Maksylewicz-Kaul A., Kammerer D., Carle R. & Baranski R. (2013). The Content of Phenolic Compounds and Radical Scavenging Activity Varies with Carrot Origin and Root Color, Plant Foods for Human Nutrition, 68, 163-170. |
| [44] | Zozio S., Servent A., Cazal G., Mbéquié-A-Mbéquié D., Ravion S., Pallet D. & Abel H. (2013). Changes in antioxidant activity during the ripening of Jujube (Ziziphus mauritiana Lamk), Food Chemistry, 1(150), 448-456. |
| [45] | Abdou B. A., Njintang Y. N., Scher J. & Mbofung C. M. (2010). Phenolic compounds and radical scavenging potentials of twenty Cameroonian spices. Agriculture and Biological Journal of North America, 1(3), 213-224. |
| [46] | EFSA (2013). Panel on Dietetic Products, Nutrition and Allergies: Scientific Opinion on Dietary Reference Values for vitamin C, European Food Safety Authority Journal, 11(11), 3418, 68 pp. doi:10.2903/j.efsa.2013.3418. |
| [47] | Halliwell B. (1994). Free radicals, antioxidants, and human disease: curiosity, cause, or consequence? The Lancet, 344, 721-724. |
| [48] | Kalt W. (2005). Effects of production and processing factors on major fruit and vegetable antioxidants. Journal of Food Science, 70, 11-19. |
| [49] | Hajar I. I., Kim W. C., Abdalbasit A. M. & Maznah I. (2009). Phenolic content and antioxidant activity of cantaloupe (Cucumis melo) methanolic extract, Food Chemistry, 119(2), 643-647. |
APA Style
Benoît Bargui Koubala, Gabriel Bassang’na, Beda Marcel Yapo, Raihanatou Raihanatou. (2016). Morphological and Biochemical Changes During Muskmelon (Cucumis melo var. Tibish) Fruit Maturation. Journal of Food and Nutrition Sciences, 4(1), 18-28. https://doi.org/10.11648/j.jfns.20160401.14
ACS Style
Benoît Bargui Koubala; Gabriel Bassang’na; Beda Marcel Yapo; Raihanatou Raihanatou. Morphological and Biochemical Changes During Muskmelon (Cucumis melo var. Tibish) Fruit Maturation. J. Food Nutr. Sci. 2016, 4(1), 18-28. doi: 10.11648/j.jfns.20160401.14
AMA Style
Benoît Bargui Koubala, Gabriel Bassang’na, Beda Marcel Yapo, Raihanatou Raihanatou. Morphological and Biochemical Changes During Muskmelon (Cucumis melo var. Tibish) Fruit Maturation. J Food Nutr Sci. 2016;4(1):18-28. doi: 10.11648/j.jfns.20160401.14
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Download@article{10.11648/j.jfns.20160401.14,
author = {Benoît Bargui Koubala and Gabriel Bassang’na and Beda Marcel Yapo and Raihanatou Raihanatou},
title = {Morphological and Biochemical Changes During Muskmelon (Cucumis melo var. Tibish) Fruit Maturation},
journal = {Journal of Food and Nutrition Sciences},
volume = {4},
number = {1},
pages = {18-28},
doi = {10.11648/j.jfns.20160401.14},
url = {https://doi.org/10.11648/j.jfns.20160401.14},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jfns.20160401.14},
abstract = {Muskmelon (Cucumis melo) is a vegetable much appreciated by the Cameroonian population. The aim of this study was to investigate the effect of development stage on morphological and physicochemical characteristics of the fruit. These parameters were studied from the third to the seventh week after fruit set. The average weight, fruit size and proportions of the different fractions (peel, mesocarp and endocarp) were evaluated. Some physicochemical and antioxidant properties were also determined. Results showed that morphological parameters increased significantly (pCucumis melo. From the third to the seventh week after fruit set, the average weight varied from 105 to 404 g. During the maturation of fruit, the weight of mesocarp was higher than that of endocarp. The studied physicochemical parameters, varied from a fruit fraction to another and also depended on the development stage. Results showed that the weight ratio of mesocarp (44-42%) decreased meanwhile that of endocarp (41-44%) increased down the growth. During the maturation of fruit, the proteins content of peels decreased from 1.7 to 0.4 mg / g, while that of mesocarp and endocarp increased from 0.14 to 0.48 mg / g and from 1.38 to 4.26, respectively. At stage 1 of development, the peels were two times richer in vitamin C (14.9 µg / g) than the other fruit fractions (4.17-8.38). However, from stage 2 to stage 5 (full maturation), the mesocarp and endocarp appeared by far richer. The minerals requirements can be satisfy by the mesocarp or endocarp of Cucumis melo fruit harvested at five week after fruit set (stage 3). However, antioxidant capacity, carbohydrates, proteins and vitamin C are high in the fruit at stage 4 or 5.},
year = {2016}
}
TY - JOUR T1 - Morphological and Biochemical Changes During Muskmelon (Cucumis melo var. Tibish) Fruit Maturation AU - Benoît Bargui Koubala AU - Gabriel Bassang’na AU - Beda Marcel Yapo AU - Raihanatou Raihanatou Y1 - 2016/03/01 PY - 2016 N1 - https://doi.org/10.11648/j.jfns.20160401.14 DO - 10.11648/j.jfns.20160401.14 T2 - Journal of Food and Nutrition Sciences JF - Journal of Food and Nutrition Sciences JO - Journal of Food and Nutrition Sciences SP - 18 EP - 28 PB - Science Publishing Group SN - 2330-7293 UR - https://doi.org/10.11648/j.jfns.20160401.14 AB - Muskmelon (Cucumis melo) is a vegetable much appreciated by the Cameroonian population. The aim of this study was to investigate the effect of development stage on morphological and physicochemical characteristics of the fruit. These parameters were studied from the third to the seventh week after fruit set. The average weight, fruit size and proportions of the different fractions (peel, mesocarp and endocarp) were evaluated. Some physicochemical and antioxidant properties were also determined. Results showed that morphological parameters increased significantly (pCucumis melo. From the third to the seventh week after fruit set, the average weight varied from 105 to 404 g. During the maturation of fruit, the weight of mesocarp was higher than that of endocarp. The studied physicochemical parameters, varied from a fruit fraction to another and also depended on the development stage. Results showed that the weight ratio of mesocarp (44-42%) decreased meanwhile that of endocarp (41-44%) increased down the growth. During the maturation of fruit, the proteins content of peels decreased from 1.7 to 0.4 mg / g, while that of mesocarp and endocarp increased from 0.14 to 0.48 mg / g and from 1.38 to 4.26, respectively. At stage 1 of development, the peels were two times richer in vitamin C (14.9 µg / g) than the other fruit fractions (4.17-8.38). However, from stage 2 to stage 5 (full maturation), the mesocarp and endocarp appeared by far richer. The minerals requirements can be satisfy by the mesocarp or endocarp of Cucumis melo fruit harvested at five week after fruit set (stage 3). However, antioxidant capacity, carbohydrates, proteins and vitamin C are high in the fruit at stage 4 or 5. VL - 4 IS - 1 ER -
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