Nanotechnology in Plant Growth Promotion and Protection. Группа авторов

Nanotechnology in Plant Growth Promotion and Protection - Группа авторов


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5 Faculty of Chemistry, Brno University of Technology, Brno, Czech Republic

       6 Nanotechnology Centre, VŠB Technical University of Ostrava, Ostrava, Czech Republic

       7 Department of Soil Science and Geology, Faculty of Agrobiology and Food Resources, Slovak University of Agriculture in Nitra, Nitra, Slovakia

      To date, titanium dioxide (TiO2) mainly in its nanoforms was found to be one of the most useful and effective materials. Various promising properties of TiO2 nanoparticles (TiO2NPs) such as its semiconductor and photocatalyst nature and other beneficial characteristics for plants attracted a great deal of attention for their applications in agriculture (Prasad et al. 2014, 2017; Wang et al. 2016; Mattiello et al. 2018; Kolenčík et al. 2019a). Nowadays, a variety of nanomaterials are increasingly used in different sectors including agriculture because of their unique or favorable properties arising from their minuscule size. Nanomaterials are defined as materials which have at least one dimension between1 and 100 nm. The definition includes a subgroup of nanoparticles with a defined size of 1–100 nm in three dimensions (CODATA‐VAMAS Working Group On the Description of Nanomaterials and Rumble 2016; Šebesta and Matúš 2018). This definition is sometimes broadened and includes slightly larger particles that display nanomaterial behavior in organisms (Cox et al. 2016; Kolenčík et al. 2019b).

      Nanomaterials made with TiO2 have broad use in nearly all human activities. They are used in various products like paints, cementitious composites, catalytic coatings, plastics, paper, pharmaceuticals, and sunscreen having applications including packaging, commercial printing inks, other cosmetics, toothpaste, and food (Weir et al. 2012; Li et al. 2018; Baranowska‐Wójcik et al. 2020). Besides, TiO2 nanomaterials are extensively used as photo‐catalysts in many chemical processes at the industrial level (Lan et al. 2013) and also used in photovoltaic cells (Gong et al. 2017). In addition, properties possess by TiO2 nanomaterials are suitable for a variety of environmental and biomedical applications such as water purification, photocatalytic degradation of pollutants, biosensing, antimicrobial coatings, and drug delivery (Mahlambi et al. 2015; Han et al. 2016; Jarosz et al. 2016; Yan et al. 2017; George et al. 2018). In analytical chemistry, TiO2 nanomaterials are used for extraction and detection of elements, and inorganic and organic compounds (Matúš et al. 2009; Hagarová et al. 2012a,b,c; Hagarová et al. 2013; Hagarová 2017, 2018; Gavazov et al. 2019; Nemček and Hagarová 2020).

      Along with all these potential uses the applicability of TiO2NPs in agriculture has been assessed in the past few years and it was observed that these nanoparticles play a pivotal role in the enhancement of plant growth, plant seed protection and enhanced germination, crop disease control (Servin et al. 2015), degradation of pesticides, pesticide residue detection (Aragay et al. 2012), and aforementioned water purification (Kumar and Bansal 2013; Prasad et al. 2014, 2017; Reddy et al. 2017). Considering these facts, the present chapter aimed to explore how the properties and modes of interaction of TiO2NPs with plants affect the growth, health, and yield of plants and especially crops. Moreover, the properties of TiO2NPs that affect the biology of plants are discussed. Positive effects of TiO2NPs are also briefly discussed. In addition, gaps in our understanding are described by proposing four areas of research that need to be studied in the foreseeable future. We believe that the present chapter will definitely help biotechnologists, agronomists, and food technologist to realize the value of TiO2 nanomaterials application.

      The methods used for the synthesis can profoundly change the properties of TiO2NPs that affect their biological interaction. Among the various properties, size and shape of TiO2NPs, their crystal structure, and surface coating are some of the most important properties found to affect the interaction of nanoparticles with other systems. Furthermore, the above‐mentioned properties also affect the surface area of nanoparticles, as well as their agglomeration/aggregation properties, generation of reactive oxygen species, and their ability to react with cell structures upon contact.

      In plants, two thresholds for root exposure were suggested by Larue et al. (2012a) when experimenting on wheat: (1) TiO2NPs having a threshold diameter of 140 nm and above do not accumulate in roots, and (2) TiO2NPs having a threshold diameter of 36 nm can be accumulated in root parenchyma, but cannot translocate to plant parts above the ground. This threshold proposed for wheat can serve as an approximation for root uptake thresholds of other plants although there were some variations dependent on plant species (Larue et al. 2012b). When applied on leaves, there was a size‐exclusion limit higher than 100 nm in lettuce and they were internalized in parenchymatic tissues (Larue et al. 2014).

      Not only the size of the TiO2 nanomaterials, but their shape is also very important. Nanospheres of TiO2 were found to be less toxic than other shapes, such as nanorods, nanowires, nanotubes, and nanobelts (Porter et al. 2012; Silva et al. 2013; Yeo and Nam 2013; Wang and Fan 2014; Landa et al. 2016). One of the proposed reasons is a higher surface area of the elongated shapes nanomaterials like nanorods and other similar shapes. Nevertheless, a study by Hsiao and Huang (2011) demonstrated that nanorods with the same surface area as that of TiO2 nanospheres showed higher toxicity, proposing the possible reason is that the area in contact with cells of an organism is more important than the whole surface area. However, some studies performed on plants show little to no difference between bulk TiO2, TiO2 nanospheres, and nanowires (Landa et al. 2016).

      The surface of the TiO2NPs is strongly affected by their crystal structure and different crystal phases of TiO2 display varying properties. Four different crystal phases of TiO2 were synthesized in form of nanoparticles, that is, amorphous, anatase, rutile, and brookite. There was a consensus that the anatase phase


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