key: cord-0927727-2t98kw7q
authors: El-Ramady, Hassan; Abdalla, Neama; Elbasiouny, Heba; Elbehiry, Fathy; Elsakhawy, Tamer; Omara, Alaa El-Dein; Amer, Megahed; Bayoumi, Yousry; Shalaby, Tarek A.; Eid, Yahya; Zia-ur- Rehman, Muhammad
title: Nano-biofortification of different crops to immune against COVID-19: A review
date: 2021-10-01
journal: Ecotoxicol Environ Saf
DOI: 10.1016/j.ecoenv.2021.112500
sha: de2838e15a882103d696ccbae786f0ad9cb9a442
doc_id: 927727
cord_uid: 2t98kw7q

Human health and its improvement are the main target of several studies related to medical, agricultural and industrial sciences. The human health is the primary conclusion of many studies. The improving of human health may include supplying the people with enough and safe nutrients against malnutrition to fight against multiple diseases like COVID-19. Biofortification is a process by which the edible plants can be enriched with essential nutrients for human health against malnutrition. After the great success of biofortification approach in the human struggle against malnutrition, a new biotechnological tool in enriching the crops with essential nutrients in the form of nanoparticles to supplement human diet with balanced diet is called nano-biofortification. Nano biofortification can be achieved by applying the nano particles of essential nutrients (e.g., Cu, Fe, Se and Zn) foliar or their nano-fertilizers in soils or waters. Not all essential nutrients for human nutrition can be biofortified in the nano-form using all edible plants but there are several obstacles prevent this approach. These stumbling blocks are increased due to COVID-19 and its problems including the global trade, global breakdown between countries, and global crisis of food production. The main target of this review was to evaluate the nano-biofortification process and its using against malnutrition as a new approach in the era of COVID-19. This review also opens many questions, which are needed to be answered like is nano-biofortification a promising solution against malnutrition? Is COVID-19 will increase the global crisis of malnutrition? What is the best method of applied nano-nutrients to achieve nano-biofortification? What are the challenges of nano-biofortification during and post of the COVID-19?

Human health is of a great global issue, which was and still is the main objective of nearly all people all over the world. The human health is directly and indirectly linked with all environmental elements (e.g., soil, edible plants, drinking water and air) with absolute sharing of microbes in the agroecosystem (van Bruggen et al., 2019) . The supplying of nutrients to edible plants through fertilization or other approaches is call biofortification, which is a vital process for human health (Tiozon et al., 2021) . The most important biofortified food crops include rice (de Lima Lessa et al., 2020) , wheat (Shi et al., 2020) , maize (Cheah et al., 2020) , cassava (Okwuonu et al., 2021) and sweet potato (Siwela et al., 2020) or horticultural crops like pear (Pessoa et al., 2021) and strawberry (Budke et al., 2020) or pulse crops (Jha and Warkentin, 2020) . The major nutrients, which could be used in biofortification may include boron , copper (Grujcic et al., 2021) , iron (Okwuonu et al., 2021) , iodine (Dobosy et al., 2020) , calcium (Pessoa et al., 2021) , selenium (González-García et al., 2021) and zinc (Pal et al., 2021) . Not only nutrients could be biofortified in edible crops, but also some vitamins also can be applied like vitamin B1 (thiamine), B2 (riboflavin), B3 (e.g., niacin), B5 (pantothenate), B6 (e.g., pyridoxine), B7 (biotin), B9 (e.g., folates and their derivatives) and B12 (cobalamin) or vitamin C (ascorbate) or vitamin E (tocopherol) or carotenoids (Jiang et al., 2021; Tiozon et al., 2021) .

The nano-biofortification is a new approach which helps to enrich the crops with essential nutrients to supplement human diet with balanced diet using -nutrients against malnutrition. This new approach has several advantages and disadvantages like nano-fertilizers or nanoparticles-based nutrients (El-Ramady et al., 2020a , 2020c . These nano-nutrients like other nanomaterials have positive and negative impacts on the natural ecosystem and human health (Malakar et al., 2021; Silva et al., 2021) . The positive sides may include promoting crop production and the nano-remediation of soils and water, whereas the main negative impacts may include the toxicity and nano-pollution (Martínez et al., 2021; Rizwan et al., 2021) . The green synthesis of nanoparticles (NPs) could be achieved using plant extracts (i.e., leaves, roots, flowers and seeds), microbes (e.g., bacteria, yeast, fungi and algae) and biomolecules (enzymes, proteins, and carbohydrates), which represent biological substrates instead of chemical as solvents and stabilizing agents to reduce the harmful nature of the product (Bandeira et al., 2020; Abinaya et al., 2021) . The biogenic synthesis of nanoparticles is "a boon" to human health, more convenient, economical and environmentally-friendly process compared to physical and chemical methods (Stephen et al., 2021) . Many studies reported about the green synthesis of nanoparticles using plant extracts such as production of S-NPs using leaves of Ocimum basilicum (Ragab and Saad-Allah, 2020) , iron-NPs by green tea and black tea leaves (Mareedu et al., 2021) , Copper-NPs from Eucalyptus globulus and mint leaves (Iliger et al., 2021) , zinc oxide -NPs from Nilgiriantusciliantus leaf (Resmi et al., 2021) , nickel oxide-NPs from fennel (Nigella sativa) seeds (Boudiaf et al., 2021) and magnesium oxide-NPs from different plant extracts (Abinaya et al., 2021) . These nano-nutrients also can support the struggle of humanity against many diseases particularly COVID-19 like nano-selenium (He et al., 2021) , and ZnO-NPs (Gatadi et al., 2021) . On the other hand, nanotechnology has distinguished opportunities tools and approaches to treat COVID-19 including the promising use of nano-nutrients as anti-Covid-19 nanoparticles (Talebian and Conde, 2020; Gatadi et al., 2021) , or nanomedicine for COVID-19 (Medhi et al., 2020; Vahedifard and Chakravarthy, 2021) . Therefore, this review is an attempt to highlight nanobiofortification and human health in the era of COVID-19, and the links between nano-biofortification and human health. What are the expected environmental impacts of COVID-19 on biofortification process? Is there any direct or indirect relationship between COVID-19 pandemic and nano-biofortification?

Starting from 2008, the US Environmental Protection Agency focused on the environmental implications of engineered nanoparticles (NPs) or nanomaterials (ENMs) and their hazard assessment at cellular and molecular level of human beside the toxicity of ENMs to terrestrial and marine organisms, transport, fate, and life cycle assessment (Gomez et al., 2021) . However, the specific effects of NPs on human health are still missing, which resulted from the consumption of edible plants that exposed to -agro-chemicals (Gomez et al., 2021) . Beside the agricultural sector, distinguished applications of technology in biomedical sciences like neurotoxicity, neurological diseases, drug delivery, cancer diagnosis, and treatment of viral infections in particular corona virus infection (Mao et al., 2021) . There are potential risks could be noticed resulted from excess consumption of dietary mineral nutrients contained in plants such as Ca (kidney stones), K (heart abnormalities), Fe, (gastric upset), Mg (muscle spasms), Mn (affects central nervous system), and Mo (Gut-like symptoms), whereas the daily required amount of common nutrient for human is 1200 mg Ca, 20 mg of B, 8-18 mg Fe, 1400-2600 mg K, 310-320 mg Mg, 1.8-2.3 mg Mn, 45 μg Mo and 8-11 mg Zn mg per day (Gomez et al., 2021) .

Nutrients-based nanoparticles or nano-nutrients are an important source for supply cultivated plants with the enough and proper nutrients for plant nutrition, which are represent main source for human health. The engineered-NPs could be directly applied for human as food additives or food industry (Deng et al., 2021) like colorants, emulsifiers, flavor enhancers, artificial sweeteners, foaming and anti-foaming agents (Medina-Reyes et al., 2020) . The nanoparticles also in form of silver (Ag), titanium oxide (TiO2) and zinc oxide (e.g., Ag-NPs, TiO 2 -NPs and ZnO-NPs) could be utilized in packaging of foods as antimicrobial agents (C. . Although many nanoparticles have been applied as nano-fertilizers or nano-pesticides, which promote crop productivity, but might cause some problems in soil-plant interfaces particularly the over-doses (Ragab and Saad-Allah, 2020) . Several studies have depicted applied engineered-NPs as nano-fertilizers (e.g., Guo et al., 2018; Farshchi et al., 2021; Madzokere et al., 2021) to improve crop productivity under many stresses (Ye et al., 2019; Landa, 2021) like drought (Sreelakshmi et al., 2020; Ahmed et al., 2021; Ali et al., 2021) , salinity Zulfiqar and Ashraf, 2021) , pollution of heavy metals (Noman et al., 2020; Xin et al., 2020; Manzoor et al., 2021) , and biotic stress (Tauseef et al., 2021a (Tauseef et al., , 2021b . These nanoparticles can enhance cultivated plants under stress through many mechanisms such as improving antioxidant defense system, promoting photosynthesis, increasing water, nutrient and phytohormones (Zulfiqar and Ashraf, 2021) . The main positive effects of engineered nanoparticles on cultivated plants may include the applications as potential agents in agriculture (e.g., nanofertilizers, nano-pesticides and nano-growth enhancers), protecting plants from environmental stresses (e.g., salinity, water deficit and drought) and decreasing the accumulation and toxicity of heavy metals (Landa, 2021) . However, many negative environmental impacts of higher concentrations of these NPs were reported, which may cause the toxicity for all environmental compartments (i.e., plants, microorganisms, animals and human) (Landa, 2021) . The possible mechanisms of the engineered-NPs toxicity may include the induced cytotoxicity, genotoxicity, and cell death and many nanoparticles at higher concentrations also can damage the lungs, DNA of cell, oxidative damage, and the cell viability of human hepatoma (Jaswal and Gupta, 2021) . The positive mechanism effects of NPs may include (1) promoting some plant enzymes (e.g., nitrate reductase, phosphatase, amylase, and phytase), which are involved in the nutrient metabolism and its acquisition, (2) stimulating the biosynthesis of chlorophyll and photosynthetic activities, (3) enhancing the opening of stomata and assimilation rate of CO 2 , and (4) modulating the oxidative stress through stimulating of enzymatic antioxidants like catalase, superoxide dismutase, and peroxidases (Landa, 2021) . On the other hand, the negative mechanism effects of NPs may include reported the phytotoxic effects of NPs on plants, which induced the damage of chloroplast via inducing the oxidative stress conditions that ultimately obstructed photosynthesis process by disturbing photosystem I activity particularly under higher concentrations of these nanoparticles (Rastogi et al., 2019; Zulfiqar and Ashraf, 2021) .

On the other hand, natural nanoparticles in fossil or coal and mineral fuel sectors have serious impacts on human health and still need more studies about their mining and behavior, which could acquire through inhalation, oral ingestion and dermal absorption causing damage or diseases on heart, lung, kidney and brain particularly through inhalation . Due to the accumulation of the nanoparticles and its unsafe discharge in the environment especially soil-plant systems, human exposure becomes inevitable through direct touching or via edible plant tissues causing hazardous health impacts (Rajput et al., 2020) . The fate and behavior of nanoparticles in different environmental compartments was and still one of the most important issue, which totally linked to the human health like aquatic systems (Turan et al., 2019; Parsai and Kumar, 2021) , which need a remediation (Ebrahimbabaie et al., 2020) . Although, the engineered NPs could be used in remediation the polluted soil, water and air environments, the excess amounts of these NPs might cause serious hazards for the ecosystem and should be removed by proper remediation tools. This means NPs is double-edged sword (Srivastav et al., 2018; Zhang et al., 2019; Romeh and Saber, 2020; Gong et al., 2021; Ganie et al., 2021) . Common case studies are published about removing many heavy metals using NPs from contaminated media (i.e., water, soil and sediments) such as arsenic (Alka et al., 2021; Maity et al., 2021) , cadmium (Gong et al., 2021) , chromium (Azeez et al., 2021) , copper (Yin et al., 2020) , lead (Lian et al., 2021) , mercury (Kumari et al., 2020) , and zinc (Fajardo et al., 2020) .

Green-synthesized nanoparticles have been used successfully in human health issues, which included many approaches like solving, treatment and preventing these problems (Nkanga and Steinmetz, 2021; Paiva-Santos et al., 2021) . The green metal-NPs have several applications as antimicrobial agents (Banasiuk et al., 2020) , in cellular imaging, as catalysts (Modak et al., 2020) , for remediation of environmental pollutants (Bhavya et al., 2021; Orooji et al., 2021) , as alternative energy source, as sensors (Zamarchi and Vieira, 2021) and as anti-microfouling agents (Rana et al., 2020) . Many green synthesis nanoparticles have been applied for multifaceted applications for human health such as antimicrobial agents as reported for nanoparticles of MgO-NPs (Vidhya et al., 2021) , Zn-NPs and Ag-NPs (Munir et al., 2020) , and ZnO-NPs (Umavathi et al., 2021) .

The humanity faces several problems related to human health especially malnutrition and hidden hunger. These problems are representing in deficiency of minerals and vitamins even in individuals who are attaining healthy levels of calories (Tiozon et al., 2021) . This deficiency of minerals and vitamins could overcome through the biofortification. It could be defined as "biofortification is a process that enhances the bioavailable concentrations of enriched vitamins or minerals in staple diet like rice achieved through three different approaches, namely (a) agronomic biofortification, (b) conventional breeding or (c) transgenic and gene editing approaches" (Tiozon et al., 2021) . The applied nutrients in form of nanoparticles to enrich the edible plants for human health is called nano-biofortification as reported in many studies on Cu, Fe, Mn, and Zn oxide-NPs (Liu et al., 2016) , on ZnO-NPs (Abdel Latef et al., 2017; Thunugunta et al., 2018) , and nano-selenium (e.g., El-Ramady et al., 2020a , 2020c Seleiman et al., 2021) .

Copper-based NPs, iron-based-NPs, selenium-based-NPs and zinc oxide-NPs for biofortification have discussed in details in Tables 1-4. These Tables included different cases of nano-biofortification, which contain the applied nano-dose of each nano-nutrient, in which form applied and prepared these nutrients, the used growth media and most important findings of these studies. The data in Tables 1-4 confirmed that the main factors controlling the using of nano-nutrients (i.e., Cu, Fe, Se and Zn) may include:

1. Applied nano-dose: where the higher applied dose may cause the toxicity for cultivated plants and consequently toxicity for human Pots filled with perlite, coco peat and sand (5:7:23) as foliar applied

Se-NPs at 20 mg L − 1 mitigated soil salinity stress and improved plant tolerance to salinity Zahedi et al. (2019a) when these plants will be consumed by him. That means the proper applied dose of nutrient must be identified before biofortification. 2. The applied and prepared method of nutrients: it is well known that foliar application of nano-nutrients is better than soil application particularly when the used soil has problems like high or how pH, salinity and other. The prepared method of nutrients especially the biological ones are preferable due to its low toxicity and eco-friendly. 3. The used growth media: growing media may represent a crucial factor controlling the efficiency of biofortification process, where normal soil is preferrable at large scale of production but hydroponics and in vitro are most suitable under small scale. 4. There are many methods for biofortification like seed priming using engineered nanomaterials, which may consider a good pathway to alleviate malnutrition (Kah et al., 2019; De La Torre-Roche et al., 2020; Acharya et al., 2020) . Beside seed priming, biofortification could be achieved by soil and foliar application or cultivated plant in soil rich in candidate nutrient. 5. Controlled or slow-release nano-fertilizers are promising approach (Guo et al., 2018; Yu et al., 2021) , whereas nano-encapsulated conventional fertilizers may help in slow and sustained release of nutrients over an extended period of time (Madzokere et al., 2021) . 6. Agricultural sustainability could be promoted using coated fertilizers, which might enhance the nutrient utilization efficiency and decrease environmental problems like sulfur coated urea . Many materials could be used as green bio-based coating materials (e.g., chitin, cellulose, keratin, poly-amino acid and starch), which are considered low-cost, renewable and have the ability to control-release of nutrients in fertilizers. It could be also used nano-silica and organosilicon as modified superhydrophobic bio-based polymer, which are considered promising tools in improving the poor release properties of bio-materials .

No one deny that COVID-19 is classified as one of the most critical global health crises, which faced the humanity in the 21st century. This virus has caused a lot of troubles in different sectors of our life as reported by our previous reports (i.e., El-Ramady et al., 2020c , 2021a . This disease increases the difficulties and life burdens on the humanity beside the global malnutrition and hidden hunger. It is reported that all forms of malnutrition not might only increase drastically due to the COVID-19 pandemic but the potential of the double burden of malnutrition epidemic, of particular concern, will be also increased (Littlejohn and Finlay, 2021) . Therefore, some studies recently published about the production of biofortified crops enriched in some nutrients like Zn, which has the ability to improve the respiratory disorders and pneumonia beside the susceptibility to the outbreak of COVID-19 (El-Ramady et al., 2021a; Gastélum-Estrada et al., 2021; Okwuonu et al., 2021) . There are new dimensions and challenges have been created during and post-COVID-19 pandemic, which threaten human health. With aggravation of the previous problems in different countries, the instant impact of COVID-19 on the food security and food supply systems has been reported (Heck et al., 2020) . This impact included several obstacles that restricted the movement of goods and people among the countries, restricted internal movement, border closure, preventing the access to markets, services and foods particularly in the agricultural sector (Ilesanmi et al., 2021) . What could be expected in the future due to COVID-19 is the drop in the global demand, a great loss in markets and employment as well as growing concerns about international cooperation (Wolfe and Patel, 2021) . Therefore, all countries need different strategies to protect foods and nutrition security of the world's poor through focus on the prioritization of diversification for production and markets (Heck et al., 2020) . The mitigation strategies for COVID-19 as a global risk should be linked with climate change as a global problem because both climate change and COVID-19 already rapidly expanded to all over the world (Rasul, 2021) .

Under the theme of COVID-19 and nano-nutrients, many challenges mainly related to the parts of nano-biofortification process: which nanonutrients are essential for human health? Which crops are needed to be biofortified and how? Are all nutrients could be converted into nanoform? Is that possible to achieve this process and what about its costs? All previous questions are representing serious challenges especially in developing countries and may control by the global status under COVID-19. More issues could be summarized in the following points:

(1) Is there any possibility for nano-nutrients like selenium to combat COVID-19? Selenium is essential nutrients for human health and its nano-form has distinguished properties like low toxicity, good candidate for the treatment of many viral diseases, cancers, Huntington's disease and Se has a direct association with COVID-19 (He et al., 2021) .

(2) Using the nano-phyto-therapy like nano-curcumin against COVID-19: this phytotherapy is an anti-inflammatory herbal based agent, which modulates the high rate of inflammatory cytokines particularly IL-6 and IL-1β mRNA expression and the secretion of cytokine in COVID-19 patients causing an enhancement in clinical manifestation and overall recovery (Valizadeh et al., 2020) . There are new promising phyto-anti-inflammatory like the mixture of green tea, guava and rose extracts, which could be used for the treatment of COVID-19 (Shin et al., 2021) . The phytomedicine or herbal immune-boosters may have substantial warriors of pandemic Covid-19 battle and more concerns are needed (Khanna et al., 2020) .

(3) Production of nanoparticles-based drugs has great attentions nowadays, which might create a new alternative and safer therapeutic agents (i.e., alternative antiviral and antimicrobial agents). Nanoparticle-based drugs (e.g., Ag-NPs, Cu-NPs, Co-NPs, and ZnO-NPs) have attractive physio-chemical properties including the shape, size, surface charge, and its area, aggregation, crystallinity, agglomeration and chemical composition (Gatadi et al., 2021) . These NP-based drugs can inhibit the impacts of viral infection like coronavirus (anti-COVID-19 nanoparticles) in many ways such as by halting viral replication and proliferation, blocking receptor cell entry and through direct inactivation (Gatadi et al., 2021) . Is there any chance for repurposed vaccines and drugs for possible treatment of COVID-19 ? Or are nanoparticle-based drugs the best solution for treating microbial and viral infections like COVID-19?

Nano-biofortification approach may consider a promising tool against malnutrition. This approach has several advantages like nanofertilizers including the efficiency and lower amount particularly the biological nano-form. Till now, this approach still in the infancy period and needs more effects to be applied on the global level. For nanobiofortification under CVID-19, there are several open questions that are needed to be answered such as how can the world overcome the expected crises in the global food security? How can developing countries fight malnutrition and food insecurity particularly under crisis of food production during and post-COVID-19? How can different countries build resilient food system amidst COVID-19? To what extent different countries can overcome the food losses in the agriculture during the COVID-19 pandemic? What is the expected role of nanotechnology in saving the treatment against COVID-19? Can nanobiofortification be the solution to fight the global malnutrition? Can we use nano-selenium and other nano-nutrients to combat COVID-19? Which elements beside Se can fight against different viruses especially COVID-19? Is there any possibility for nano-nutrients to be part of the solution of vaccine against COVID-19?

The idea of the review article and write up of the 1st draft was contributed by Hassan El-Ramady and Neama Abdalla. They also contributed in revising the MS and made constructive changes during revision of the MS. The data collection and draft write up of the manuscript was contributed by Heba Elbasiouny, Fathy Elbehiry, Tamer Elsakhawy, Alaa El-Dein Omara, Megahed Amer, Yousry Bayoumi, Tarek A. Shalaby, Yahya Eid. The final edits and finalizing of the data were made by Muhammad Zia-ur-Rehman. Moreover, he took the responsibility to submit the article. He also has made the corrections during revision process and resubmitted the article.

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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Drought stress amelioration in plants using green synthesised iron oxide nanoparticles

Nano-phytoremediation of pollutants from contaminated soil environment: current scenario and future prospects

Biogenic synthesized nanoparticles a boon to human health

Why go NANO on COVID-19 pandemic? Matter

Differential response of cowpea towards the CuO nanoparticles under Meloidogyne incognita stress. South Afr

Role of MgO nanoparticles in the suppression of Meloidogyne incognita, infecting cowpea and improvement in plant growth and physiology

Impact of zinc oxide nanoparticles on eggplant (S. melongena): studies on growth and the accumulation of nanoparticles

Meeting human dietary vitamin requirements in the staple rice via strategies of biofortification and post-harvest fortification

Nanoparticles in the aquatic environment: usage, properties, transformation and toxicity-a review

Green synthesis of ZnO nanoparticles for antimicrobial and vegetative growth applications: a novel approach for advancing efficient high quality health care to human wellbeing

Nanomedicine for COVID-19: the role of nanotechnology in the treatment and diagnosis of COVID-19

Antioxidant and defense genetic expressions in corn at earlydevelopmental stage are differentially modulated by copper form exposure (nano, bulk, ionic): nutrient and physiological effects

Nano-curcumin therapy, a promising method in modulating inflammatory cytokines in COVID-19 patients

Green fabricated MgO nanoparticles as antimicrobial agent: characterization and evaluation

Nano-selenium controlled cadmium accumulation and improved photosynthesis in indica rice cultivated in lead and cadmium combined paddy soils

Improvement of nutrient elements and allicin content in green onion (Allium fistulosum) plants exposed to CuO nanoparticles

Effect of metal oxide nanoparticles on amino acids in wheat grains (Triticum aestivum) in a life cycle study

Divergence in response of lettuce (var. ramosa Hort.) to copper oxide nanoparticles/microparticles as potential agricultural fertilizer

Everybody hurts: self-employment, financial concerns, mental distress, and well-being during COVID-19

Use of polymeric nanoparticles to improve seed germination and plant growth under copper stress

Effects of iron oxide nanoparticles on the mineral composition and growth of soybean (Glycine max L.) plants

Can abiotic stresses in plants be alleviated by manganese nanoparticles or compounds?

Remediation of copper contaminated sediments by granular activated carbonsupported titanium dioxide nanoparticles: mechanism study and effect on enzyme activities

Nano-soy-protein microcapsule-enabled self-healing biopolyurethane-coated controlled-release fertilizer: preparation, performance, and mechanism

Root system architecture, copper uptake and tissue distribution in soybean

Merr.) grown in copper oxide nanoparticle (CuONP)-amended soil and implications for human nutrition

Zinc oxide nanoparticles (ZnONPs) as a novel nanofertilizer: influence on seed yield and antioxidant defense system in soil grown soybean (Glycine max cv. Kowsar)

Alleviation of the effect of salinity on growth and yield of strawberry by foliar spray of selenium-nanoparticles

Foliar application of selenium and nano-selenium affects pomegranate (Punica granatum cv. Malase Saveh) fruit yield and quality. South Afr

Selenium and silica nanostructure-based recovery of strawberry plants subjected to drought stress

Determination of paracetamol using a sensor based on green synthesis of silver nanoparticles in plant extract

Biofortification of pulse crops: Status and future perspectives

Regulation of Plant Vitamin Metabolism: Backbone of Biofortification for the Alleviation of Hidden Hunger

Novel environment-friendly superhydrophobic bio-based polymer derived from liquefied corncob for controlled-released fertilizer

Effects of micro-/ nano-hydroxyapatite and phytoremediation on fungal community structure in copper contaminated soil

Nanoparticles potentially mediate salt stress tolerance in plants

This work was financialized and supported by the Central Department of Mission, Egyptian Ministry of Higher Education (Mission 19/ 2020) for El-Ramady.