Jasper Okoro Godwin Elechi scite author profile

Jasper Okoro Godwin Elechi

5Publications

12Citation Statements Received

570Citation Statements Given

How they've been cited

How they cite others

456

541

Affiliations

University of Calabria, University of Agriculture

Publications

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Global Food System Transformation for Resilience

Elechi¹,

Nwiyi²,

Adamu³

2022

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Our world is incredibly diverse and beautiful, everything we do has an impact on the environment, and our actions are intertwined. Recognizing how our actions affect the Earth on a global scale means, we need to change the way we do things. We must ensure that the value society derives from our actions comes at a low cost to the environment. A sustainable strategy to establish a resilient food system is to ensure that human demand for the Earth’s resources for food is kept within the supply of these resources. While more than 800 million people worldwide suffer from chronic malnutrition, our food systems emit roughly a third of all greenhouse emissions. Also, over 80% of our biodiversity gets lost. Hence, scaling up food system is simply not an option to feed nine to ten billion people by 2050 as we will need to produce more food in the next four decades than all of history’s farmers have harvested in the last eight thousand years. Therefore, rather than upscaling, the global food systems require transformation. Four critical aspects of this transformation include: “Boosting the small; Transforming the Big; Losing Less; and Eating Smarter.” Examining these four areas more deeply, it becomes evident that, while new technology will be critical to the transformation, government involvement, as well as better financial and behavioral change from residents and consumers, will be required. This chapter focuses on these four pillars that make up the global food system transformation for resilience.

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Food System Transformation and Gut Microbiota Transition: Evidence on Advancing Obesity, Cardiovascular Diseases, and Cancers—A Narrative Review

Elechi

Sirianni

Conforti

et al. 2023

Foods

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Food, a vital component of our daily life, is fundamental to our health and well-being, and the knowledge and practices relating to food have been passed down from countless generations of ancestors. Systems may be used to describe this extremely extensive and varied body of agricultural and gastronomic knowledge that has been gathered via evolutionary processes. The gut microbiota also underwent changes as the food system did, and these alterations had a variety of effects on human health. In recent decades, the gut microbiome has gained attention due to its health benefits as well as its pathological effects on human health. Many studies have shown that a person’s gut microbiota partially determines the nutritional value of food and that diet, in turn, shapes both the microbiota and the microbiome. The current narrative review aims to explain how changes in the food system over time affect the makeup and evolution of the gut microbiota, advancing obesity, cardiovascular disease (CVD), and cancer. After a brief discussion of the food system’s variety and the gut microbiota’s functions, we concentrate on the relationship between the evolution of food system transformation and gut microbiota system transition linked to the increase of non-communicable diseases (NCDs). Finally, we also describe sustainable food system transformation strategies to ensure healthy microbiota composition recovery and maintain the host gut barrier and immune functions to reverse advancing NCDs.

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The application of blends of bambaranut and millet vegetable milk in the development of plant-based yoghurt analogues: Proximate composition, physiochemical properties, microbial safety and consumer’s acceptability

Elechi¹,

ABU²,

EKE³

2023

Food Health

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This study aimed to produce plant-based yoghurt analogues from the blends of Bambaranut and millet milk. Yoghurt samples were produced from blends of Bambaranut milk and millet milk using Streptococcus thermophillus and Lactobacillus bulgaricus as starter cultures. Yoghurt samples were subjected to chemical, microbiological and organoleptic assessment. The results of the chemical analysis revealed moisture, protein, ash, fat, fibre, carbohydrates and energy contents ranged from 87.61-78.26%, 6.85-3.68%, 0.76-0.59%, 2.70-1.81%, 0.34-0.26%,12.88- 5.60 and 92.94-57.50% respectively Total solids of between 12.39 and 21.74% were obtained with titratable acidity of 0.21, 0.65, 0.21, 0.23, 0.23, 0.25, 0.30 and 0.90%, respectively. The syneresis of the samples ranged from 40.28 to 18.90% while all the samples showed fairly acidic levels. A viscosity of between 250 and 784cp was obtained. The microbiological examination revealed an acceptable level for all the samples. There were observable significant differences in terms of overall acceptability, taste, and flavour between cow milk yoghurt and the yoghurt analogues.

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Effect of fortification of defatted Moringa oleifera seed flour on consumers acceptability and nutritional characteristics of wheat bread

Elechi

2022

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Bread was enhanced with defatted moringa seed flour in various quantities (0-7.5%) in this investigation. The functional properties of the flour and the physical, proximate, mineral content and sensory attributes of the defatted moringa fortiﬁed bread samples were evaluated. The functional properties of the defatted moringa seed flour showed Bulk Density (0.75g/ml), Oil Absorption Capacity (88.45 %), Reconstitution index (76.28 %), Swelling index (8.25 g/vol), Solubility (8.63 %), Viscosity (342.60 cp), and Water Absorption Capacity (82.45 %). Results of the proximate analysis showed that defatted moringa seed flour addition signiﬁcantly (p < 0.05) increased the protein (13.82–15.39%), fat (1.25–1.56%), ash (1.51–1.61%) and ﬁbre content (0.13–0.18%) of the bread samples, while the moisture (7.85–7.60%), carbohydrates content (75.44–72.88%) and pH (8.05-7.8%) of the bread decreased. Addition of defatted moringa seed flour significantly (p

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Fermentation and diet diversity: Biochemical and functional properties of fermented mango (Mangifera Indica L) pulp flour

Elechi

Nwiyi

OBOH

2022

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Processing of plant foods has been in practice over a long period of time for various reasons; ranging from optimization of product quality, such as improvement in flavour, texture, nutrient density, and bioavailability as well as reduction in viscosity, bulkiness, and antinutritional factors/toxins or for improvement of functional properties for use in other food systems. Indigenous food fermentation is one of the oldest ‘food biotechnological processes’ dependent on the biological activity of microorganisms from which the development of fermented foods is achieved in the cultural history of human beings. Mango (Mangifera indica) is a tropical fruit plant that contains high levels of nutrients, fibre, macronutrients, micronutrients, and minerals as well as abundant bioactive compounds such as antioxidants and polyphenols reported to be an alternative to enhance body immunity. This study is to process fermented mango pulp flour and the effects of the period of fermentation time on the chemical composition and selected functional properties of mango pulp flours were examined. The fermentation time ranged from 0-72 h with Flour of the unfermented (0hr) Mango serving as control. Fermentation for 24hr to 72hrs significantly increased (p

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