Nutritional Evaluation of the Seeds of Corchorus olitorius: A Neglected and Underutilized Species in Nigeria


Authors

  • C.C. Isuosuo Department of Plant Science and Biotechnology, Faculty of Biological Sciences, University of Nigeria, Nsukka, Nigeria
  • F.I. Akaneme Department of Plant Science and Biotechnology, Faculty of Biological Sciences, University of Nigeria, Nsukka, Nigeria
  • N.E. Abu Department of Plant Science and Biotechnology, Faculty of Biological Sciences, University of Nigeria, Nsukka, Nigeria

DOI:

https://doi.org/10.3923/pjn.2019.692.703

Keywords:

Corchorus, Corchorus olitorius seed, human diet, leafy vegetables, livestock feed

Abstract

Background and Objective: The seeds of Corchorus olitorius (C. olitorius), a neglected leafy vegetable in Nigeria, are usually discarded in the process of harvesting the leaves. This practice may result from a lack of knowledge regarding the nutritional content of the seeds as well as a lack of research interest. The aim of this study was therefore to evaluate the nutritional composition of the seeds of 14 accessions of C. olitorius. The results will help to determine the suitability of these seeds as a source of nutritious food for human consumption and of feed for the livestock industry. Materials and Methods: The seeds of the 14 accessions of C. olitorius were procured from the seed bank of the National Centre for Genetic Resources and Biotechnology, Moor Plantation, Ibadan, Nigeria. Standard food composition analysis techniques were employed to evaluate the proximate, mineral and vitamin contents of the seeds. The obtained data were analysed with Genstat and SPSS. Results: The proximate components were present in varying ranges, as follows: moisture (6.087-10.77 mg/100 g), ash (1.866-2.657%), fat (5.274-5.896%), protein (0.966-1.135%), fibre (0.973-1.913%) and carbohydrate (59.91-87.34%). The mineral contents were as follows: calcium (1.242-2.610%), iron (1.235-1.623 mg/100 g), potassium (0.320-1.232%), sodium (0.002-0.007%), lead (0.150-0.274 mg/100 g), tin (0.086-0.167 mg/100 g), zinc (0.090-0.942 μg/100 g), manganese (0.123-0.147%), magnesium (0.896-1.475 mg/100 g), copper (0.126-0.143 mg/100 g) and phosphorus (0.624-0.973 mg/100 g). The vitamin contents included the following: 2.155-2.838 mg/100 g of vitamin A, 0.519-0.884 mg/100 g of vitamin C and 0.357-0.394 mg/100 g of vitamin D. The Na/K ratio ranged from 0.005-0.016 and the Ca/P ratio ranged from 1.31-3.43. The highest positive correlation coefficient (<0.05) was obtained between vitamin A and vitamin C (r2 = 0.521, 52%) and the highest negative correlation was observed between tin and manganese (r2 = 0.581, 58%). Principal component analysis revealed that two principal components with eigenvalues ≥1 accounted for 90.09% of the total variability among the accessions. These two components were carbohydrates (57.12%) and the moisture composition (32.37%). Conclusion: Seeds of C. olitorius are nutritionally adequate and have acceptable limits of metal contents. Thus, they have the potential to be incorporated into the human diet and livestock feed.

References

Opabode, J.T. and C.O. Adebooye, 2005. Application of biotechnology for the improvement of Nigerian indigenous leaf vegetables. Afr. J. Biotechnol., 4: 138-142.

Ilhan, S., F. Savaroglu and F. Colak, 2007. Antibacterial and antifungal activity of Corchorus olitorius L. (Molokhia) extracts. Int. J. Nat. Eng. Sci., 1: 59-61.

Ogunkanmi, L.A., W.O. Okunowo, O.O. Oyelakin, B.O. Oboh, O.O. Adesina, K.O. Adekoya and O.T. Ogundipe, 2010. Assessment of genetic relationships between two species of jute plants using phenotypic and RAPD markers. Int. J. Bot., 6: 107-111.

AVRDC., 2004. Promoting utilization of indigenous vegetable for improved nutrition of resource poor household in Asia. Asian Vegetable Research Development Center, ADB Reta 6067. Bulletin, No. 3, pp: 7.

Oyedele, D.J., C. Asonugho and O.O. Awotoye, 2006. Heavy metals in soil and accumulation by edible vegetables after phosphate fertilizer application. Elect. J. Agric. Food Chem., 5: 1446-1453.

Abu-Khalaf, N., M. Almasri, A. Hajjaj, N. Abbadi and H. Salah et al., 2013. Effect of different plastic liners on the quality of fresh-cut Jew’s mallow leaves (Corchorus olitorius L.) during storage under different temperatures. Br. J. Applied Sci. Technol., 3: 462-471.

Akindahunsi, A.A. and S.O. Salawu, 2005. Phytochemical screening and nutrient-antinutrient composition of selected tropical green leafy vegetables. Afr. J. Biotechnol., 4: 497-501.

Sinha, M.K., C.S. Kar, A. Ramasubramanian, A. Kundu and B.S. Mahapatra, 2011. Corchorus. In: Wild Crop Relatives: Genomic and Breeding Resources, Industrial Crops, Kole, C. (Ed.)., Springer-Verlag, Berlin, Heidelberg, pp: 29-61.

Al-Snafi, A.E., 2016. The contents and pharmacological importance of Corchorus capsularis-A review. IOSR J. Pharm., 6: 58-63.

Idirs, S., J. Yisa and M.M. Ndamitso, 2009. Nutritional composition of Corchorus olitorius leaves. Anim. Prod. Res. Adv., 5: 83-87.

Mohammed, M.I. and N. Sharif, 2011. Mineral composition of some leafy vegetables consumed in Kano, Nigeria. Nig. J. Basic Applied Sci., 19: 208-212.

Zakaria, Z.A., M.N. Somchit, H. Zaiton, A.M. Mat Jais and M.R. Sulaiman et al., 2006. The in vitro antibacterial activity of Corchorus olitorius extracts. Int. J. Pharmacol., 2: 213-215.

Pal, D.K., M. Mandal, G.P. Senthilkumar and A. Padhiari, 2006. Antibacterial activity of Cuscuta reflexa stem and Corchorus olitorius seed. Fitoterapia, 77: 589-591.

Ibrahim, T.A. and E.D. Fagbohun, 2011. Physicochemical properties and in vitro anti-bacterial activity of Corchorus olitorius Linn. seed oil. Life Sci. Leaflets, 15: 499-505.

Oloye, D.A., O.T. Odeja, E.T. Faboya and T.A. Ibrahim, 2014. Proximate and mineral composition of wild Corchorous olitorius seed flour. Res. Rev.: J. Agric. Allied Sci., 3: 1-4.

Adebooye, O.C., S.A. Ajayi, J.J. Baidu-Forson and J.T. Opabode, 2005. Seed constraint to cultivation and productivity of African indigenous leaf vegetables. Afr. J. Biotechnol., 4: 1480-1484.

Ezeagu, I.E., 2009. Nutritional Value of Tropical Plant Seeds. In: Modification of Seed Composition to Promote Health and Nutrition, Agronomy Monograph, 51, Chapter 2, Krishnan, H. (Ed.)., American Society of Agronomy, Crop Science Society of America, Soil Science Society of America, USA., pp: 39-53.

Agatemor, C., 2006. Studies of selected physicochemical properties of fluted pumpkin (Telfairia occidentalis Hook F.) seed oil and tropical almond (Terminalia catappia L.) seed oil. Pak. J. Nutr., 5: 306-307.

Matsufuji, H., S. Saka, M. Chin, Y. Goda, M. Toyoda and M. Takeda, 2001. Relationship between cardiac glycoside contents and color of Corchorus olitorius seeds. J. Health Sci., 47: 87-93.

Pearson, D., 1976. The Chemical Analysis of Foods. 7th Edn., Churchill Livingstone, Edinburgh, UK., pp: 488-496.

AOAC., 1990. Official Methods of Analysis Association of Analytical Chemist. 14th Edn., Association of Official Analytical Chemists, Washington, DC., USA.

Kang, B.T. and B. Tripathi, 1992. Technical Paper 1: Soil Classification and Characterization. In: The AFNETA Alley Farming Training Manual. Volume 2, Source Book for Alley Farming Research, Tripathi, B.R. and P.J. Psychas (Eds.), IITA., Ibadan.

Eniscuola, 2018. Types of soil and classification. http://www.eniscuola.net/en/argomento/soil/soil-classification/types-of-soil-and-classification/.

NIPC., 2016. States snapshot. Nigerian Investment Promotion Commission. https://www.nipc.gov.ng/category/states/.

Cornell.edu, 2018. Soil classification. http://www.css.cornell.edu/courses/260/Taxonomy%20&%20Classification.pdf.

University of Georgia Extension, 2017. Cation exchange capacity and base saturation. Circular 1040. http://extension.uga.edu/publications/detail.html?number=C1040&title=Cation%20Exchange%20Capacity%20and%20Base%20Saturation.

Rainforest Conservation Fund, 2018. Tropical soils. http://www.rainforestconservation.org/rainforest-primer/rainforest-primer-table-of-contents/l-tropical-soils/.

Ekop, A.S., 2007. Determination of chemical composition of Gnetum africanum (AFANG) seeds. Pak. J. Nutr., 6: 40-43.

Emmanuel, T.V., J.T. Njoka, L.W. Catherine and H.V.M. Lyaruu, 2011. Nutritive and anti-nutritive qualities of mostly preferred edible woody plants in selected drylands of Iringa district, Tanzania. Pak. J. Nutr., 10: 786-791.

World Weather and Climate Information, 2016. Average humidity in Lagos. https://weather-and-climate.com/average-monthly-Humidity-perc,lagos-ng,Nigeria.

Esu, I.E. and A.U. Akpan-Idiok, 2012. Morphological characteristics and classification of mangrove swamp soils in the cross river Estuary, Southeast Nigeria. Proceedings of the 7th International Acid Sulfate Soil Conference, August 26-September 1, 2012, Vaasa, Finland.

Ukpong, I., 2018. Mangrove soils, species relationships and ecosystem management. https://www.academia.edu/6434568/Mangrove_Soils_Species_Relationships_and_Ecosystem_Management.

Plant and Soil Sciences eLibrary, 2018. Soil genesis and development, lesson 5-soil classification and geography. https://passel.unl.edu/pages/informationmodule.php?idinformationmodule=1130447032&topicorder=4&maxto=16&minto=1.

Thompson, C., 2018. Properties of alluvial soils. https://www.hunker.com/13406892/properties-of-alluvial-soils.

Alinnor, I.J. and R. Oze, 2011. Chemical evaluation of the nutritive value of Pentaclethra macrophylla benth (African oil bean) seeds. Pak. J. Nutr., 10: 355-359.

Akpabio, U.D., A.E. Akpakpan and G.N. Enin, 2012. Evaluation of proximate compositions and mineral elements in the star apple peel, pulp and seed. J. Basic. Applied Sci. Res., 2: 4839-4843.

Akinhanmi, T.F., V.N. Atasie and P.O. Akintokun, 2008. Chemical composition and physicochemical properties of cashew nut (Anarcadium occidentale) oil and cashew nut shell liquid. J. Agric. Food Environ. Sci., 2: 1-10.

Onwordi, C.T., A.M. Ogungbade and A.D. Wusu, 2009. The proximate and mineral composition of three leafy vegetables commonly consumed in Lagos, Nigeria. Afr. J. Pure Applied Chem., 3: 102-107.

Mensah, J.K., R.I. Okoli, J.O. Ohaju-Obodo and K. Eifediyi, 2008. Phytochemical, nutritional and medical properties of some leafy vegetables consumed by Edo people of Nigeria. Afr. J. Biotechnol., 7: 2304-2309.

Ranhotra, G.S., J.A. Gelroth, S.O. Leinen, M.A. Vinas and K.J. Lorenz, 1998. Nutritional profile of some edible plants from Mexico. J. Food Compo. Anal., 11: 298-304.

Balogun, I.O. and O.P. Olatidoye, 2012. Chemical composition and nutritional evaluation of velvet bean seeds (Mucuna utilis) for domestic consumption and industrial utilization in Nigeria. Pak. J. Nutr., 11: 116-122.

Elinge, C.M., A. Muhammad, F.A. Atiku, A.U. Itodo, I.J. Peni, O.M. Sanni and A.N. Mbongo, 2012. Proximate, mineral and anti-nutrient composition of pumpkin (Cucurbitapepo L) seeds extract. Int. J. Plant Res., 2: 146-150.

Hussain, J., N. ur Rehman, A. Al-Harrasi, L. Ali and R. Ullah et al., 2011. Nutritional prospects and mineral compositions of selected vegetables from Dhoda sharif Kohat. J. Med. Plants Res., 5: 6509-6514.

Eromosele, I.C., C.O. Eromosele and D.M. Kuzhkuzha, 1991. Evaluation of mineral elements and ascorbic acid contents in fruits of some wild plants. Plant Food Hum. Nutr., 41: 151-154.

Ndlovu, J. and A.J. Afolayan, 2008. Nutritional analysis of the south african wild vegetable Corchorus olitorius L. Asian J. Plant Sci., 7: 615-618.

Kamga, R.T., C. Kouamé, A.R. Atangana, T. Chagomoka and R. Ndango, 2013. Nutritional evaluation of five African indigenous vegetables. J. Hortic. Res., 21: 99-106.

Hays, V.W. and M.J. Swenson, 1985. Minerals and Bones. In: Dukes' Physiology of Domestic Animals, Dukes, H.H. and M.J. Swenson (Eds.). 10th Edn. Cornell University Press, Ithaca, NY., USA., pp: 449-466.

Institute of Medicine, 2005. Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein and Amino Acids. The National Academies Press, Washington, DC., Pages: 1358.

Shahidi, F., U.D. Chavan, A.K. Bal and D.B. McKenzie, 1999. Chemical composition of beach pea (Lathyrus maritimus L.) plant parts. Food Chem., 64: 39-44.

FAO. and WHO., 2001. Human vitamin and mineral requirements. Report of a Joint FAO/WHO Expert Consultation, Bangkok, Thailand, Food and Nutrition Division, FAO., Rome, pp: 1-303. http://www.fao.org/3/a-y2809e.pdf.

Brar, B., S. Jain, R. Singh and R.K. Jain, 2011. Genetic diversity for iron and zinc contents in a collection of 220 rice (Oryza sativa L.) genotypes. Indian J. Genet., 71: 67-73.

Nzikou, J.M., M. Mvoula-Tsieri, E. Matouba, J.M. Ouamba, C. Kapseu, M. Parmentier and S. Desobry, 2006. A study on gumbo seed grown in Congo Brazzaville for its food and industrial applications. Afr. J. Biotechnol., 5: 2469-2475.

Yusuf, A.A., B.M. Mofio and A.B. Ahmed, 2007. Nutrient contents of pride of barbados (Caesalpinia pulcherrima Linn.) seeds. Pak. J. Nutr., 6: 117-121.

Akinyeye, R.O., A. Oluwadunsi and A. Omoyeni, 2010. Proximate, mineral, anti-nutrients, phyto-chemical screening and amino acid compositions of the leaves of Pterocarpus mildbraedi harms. Electron. J. Environ. Agric. Food Chem., 9: 1322-1333.

Zaidi, M.I., A. Asrar, A. Mansoor and M.A. Farooqui, 2005. The heavy metal concentration along roadside trees of Quetta and its effects on public health. J. Applied Sci., 5: 708-711.

Asaolu, S.S. and M.F. Asaolu, 2010. Trace metal distribution in Nigerian leafy vegetables. Pak. J. Nutr., 9: 91-92.

WHO., 1998‎. Complementary feeding of young children in developing countries: A review of current scientific knowledge. World Health Organization, Geneva. http://www.who.int/iris/handle/10665/65932.

Kinser, A., 2010. The importance of trace mineral nutrition. http://www.vigortone.com/.

Walker, P.G., R. Viola, M. Woodhead, L. Jorgensen, S.L. Gordon, R.M. Brennan and R.D. Hancock, 2010. Ascorbic acid content of blackcurrant fruit is influenced by both genetic and environmental factors. Funct. Plant Sci. Biotechnol., 4: 40-52.

National Institute of Health, 2018. Vitamin D: Fact sheet for health professionals. https://ods.od.nih.gov/factsheets/VitaminD-HealthProfessional/.

Babayemi, J.O., K.T. Dauda, D.O. Nwude and A.A.A. Kayode, 2010. Evaluation of the composition and chemistry of ash and potash from various plant materials-a review. J. Applied Sci., 10: 1820-1824.

Iniaghe, O.M., S.O. Malomo and J.O. Adebayo, 2009. Proximate composition and phytochemical constituents of leaves of some Acalypha species. Pak. J. Nutr., 8: 256-258.

Agbaire, P.O., 2012. Levels of anti-nutritional factors in some common leafy edible vegetables of Southern Nigeria. Afr. J. Food Sci. Technol., 3: 99-101.

Sani, U.G., 2014. Chemical analysis of Ceratotheca sesamoides Endl, Vernonia amygdalina Del, Corchorus olitorius, C. tridens, Momordica charantia and Senna occidentalis Linn. Ph.D. Thesis, Ahmadu Bello University, Zaria, Nigeria.

Akaneme, F.I., D. Igata, H. Okafor and O. Anyanebechi, 2014. Breeding for nutritional quality for Corchorus olitorius, Annona muricata and Pentaclethra macrophylla 1: A study of their antinutritional contents. Afr. J. Agric. Res., 9: 1107-1112.

Downloads

Published

15.06.2019

Issue

Vol. 18 No. 7 (2019)

Section

Research Article

License

Copyright (c) 2019 The Author(s)

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

How to Cite

Isuosuo, C., Akaneme, F., & Abu, N. (2019). Nutritional Evaluation of the Seeds of Corchorus olitorius: A Neglected and Underutilized Species in Nigeria. Pakistan Journal of Nutrition, 18(7), 692–703. https://doi.org/10.3923/pjn.2019.692.703