Microgreens: from trendy vegetables to functional food and potential nutrition security resource

Starting as trendy high-value gourmet greens, today, microgreens have gained great popularity among consumers for their nutritional profile and high content of antioxidant compounds. Microgreens’ nutritional profile is associated with the rich variety of colors, shapes, textural properties, and flavors obtained from sprouting a multitude of edible vegetable species, including herbs, herbaceous crops, and neglected wild edible species. Grown in a variety of soilless production systems, over the last five years in many urban and peri-urban areas of the world, microgreens have literally exploded as a cash crop produced in various protected culture systems and especially indoors through the use of artificial lighting systems. The ability to grow microgreens indoors in very small space, the short growth cycle required, and only minimum inputs required to produce them may allow the micro-scale production of fresh and nutritious vegetables even in areas that are considered food deserts. The current COVID-19 pandemic revealed the vulnerability of our food system and the need to address malnutrition issues and nutrition security inequality which could be exacerbated by potential future situations of emergency or catastrophe. Microgreens have great potential as an efficient food resilience resource, since they can provide essential nutrients and antioxidants. Using simple soilless production systems, seeds, and minimal inputs, nutrient-dense microgreens and shoots may be produced under different lighting conditions ranging from darkness to full sunlight or under artificial lighting in controlled environmental conditions, providing a rich source of essential nutrients and antioxidant compounds in a very short time. Moreover, using simple agronomic techniques, it is possible to produce biofortified or tailored functional micro-vegetables that could address specific dietary needs and/or address micronutrient deficiencies and nutrition security issues in emergency situations or limiting environmental conditions.Contribution of F. Di Gioia have been supported by the Food Resilience in the Face of Catastrophic Global Events grant funded by Open Philanthropy and by the USDA National Institute of Food and Agriculture and Hatch Appropriations under Project #PEN04723 and Accession #1020664.info:eu-repo/semantics/publishedVersio

Microgreens: From trendy vegetables to functional food and potential nutrition security resource

Starting as trendy high-value gourmet greens, today, microgreens have gained great popularity among consumers for their nutritional profile and high content of antioxidant compounds. Microgreens' nutritional profile is associated with the rich variety of colors, shapes, textural properties, and flavors obtained from sprouting a multitude of edible vegetable species, including herbs, herbaceous crops, and neglected wild edible species. Grown in a variety of soilless production systems, over the last five years in many urban and peri-urban areas of the world, microgreens have literally exploded as a cash crop produced in various protected culture systems and especially indoors through the use of artificial lighting systems. The ability to grow microgreens indoors in very small space, the short growth cycle required, and only minimum inputs required to produce them may allow the micro-scale production of fresh and nutritious vegetables even in areas that are considered food deserts. The current COVID-19 pandemic revealed the vulnerability of our food system and the need to address malnutrition issues and nutrition security inequality which could be exacerbated by potential future situations of emergency or catastrophe. Microgreens have great potential as an efficient food resilience resource, since they can provide essential nutrients and antioxidants. Using simple soilless production systems, seeds, and minimal inputs, nutrient-dense microgreens and shoots may be produced under different lighting conditions ranging from darkness to full sunlight or under artificial lighting in controlled environmental conditions, providing a rich source of essential nutrients and antioxidant compounds in a very short time. Moreover, using simple agronomic techniques, it is possible to produce biofortified or tailored functional micro-vegetables that could address specific dietary needs and/or address micronutrient deficiencies and nutrition security issues in emergency situations or limiting environmental conditions. © 2021 International Society for Horticultural Science. All rights reserved

Zinc and iron agronomic biofortification of Brassicaceae microgreens

Insufficient or suboptimal dietary intake of iron (Fe) and zinc (Zn) represent a latent health issue affecting a large proportion of the global population, particularly among young children and women living in poor regions at high risk of malnutrition. Agronomic crop biofortification, which consists of increasing the accumulation of target nutrients in edible plant tissues through fertilization or other eliciting factors, has been proposed as a short-term approach to develop functional staple crops and vegetables to address micronutrient deficiency. The aim of the presented study was to evaluate the potential for biofortification of Brassicaceae microgreens through Zn and Fe enrichment. The effect of nutrient solutions supplemented with zinc sulfate (Exp-1; 0, 5, 10, 20 mg L−1) and iron sulfate (Exp-2; 0, 10, 20, 40 mg L−1) was tested on the growth, yield, and mineral concentration of arugula, red cabbage, and red mustard microgreens. Zn and Fe accumulation in all three species increased according to a quadratic model. However, significant interactions were observed between Zn or Fe level and the species examined, suggesting that the response to Zn and Fe enrichment was genotype specific. The application of Zn at 5 and 10 mg L−1 resulted in an increase in Zn concentration compared to the untreated control ranging from 75% to 281%, while solutions enriched with Fe at 10 and 20 mg L−1 increased Fe shoot concentration from 64% in arugula up to 278% in red cabbage. In conclusion, the tested Brassicaceae species grown in soilless systems are good targets to produce high quality Zn and Fe biofortified microgreens through the simple manipulation of nutrient solution composition. © 2019 by the authors

Integrating cover crops as a source of carbon for anaerobic soil disinfestation

The adoption of anaerobic soil disinfestation (ASD), a biologically-based method for the management of soilborne pests and pathogens at the commercial scale strictly depends on the availability of effective and low-cost sources of carbon (C). A three-phase pot study was conducted to evaluate the performance of twelve cover crop species as alternative sources of C in comparison to molasses. Buckwheat produced the greatest above-ground and total plant dry biomass and accumulated the largest amount of total C. In the second phase, simulating the application of ASD in a pot-in-pot system, molasses-amended soil achieved substantially higher levels of anaerobicity, and lowered soil pH at 3 and 7 days after treatment application compared to soil amended with the cover crops tested. In the third phase of the study, after the ASD simulation, lettuce was planted to assess the impact of cover crops and molasses-based ASD on lettuce yield and quality. The treatments had limited effects on lettuce plant growth and quality as none of the treatments caused plant stunting or phytotoxicity. Tested cover crop species and molasses had a significant impact on the availability of macro and micro-elements in the soil, which in turn influenced the uptake of minerals in lettuce. Fast growing cover crops like buckwheat or oat, capable of accumulating high levels of C in a relatively short time, may represent a viable alternative to substitute or be combined with standard C sources like molasses, which could provide an on-farm C source and reduce cost of application. Further research is needed to assess the performance of cover crops at the field scale and verify their decomposability and efficacy in managing soil-borne pests and pathogens