Titlebook: Nanomaterial Interactions with Plant Cellular Mechanisms and Macromolecules and Agricultural Implica; Jameel M. Al-Khayri,Lina M. Alnaddaf

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Introduction: Impact of Nanotechnology on Plant Cell Biology,ding photosynthesis and pigment synthesis and accumulation. Also highlights the current understanding of the impact of NMs on cellular macromolecules, these processes and biochemical compounds have implications for crop yield.

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Effect of Nanomaterials on Water and Solutes Translocation in Plants-induced transformation of plants is also explored. The current state of analytical techniques for assessing the uptake of engineered NPs in plants is also addressed. Therefore, the current chapter discusses nanomaterials uptake and transport mechanisms, nanomaterials transformation in rhizosphere a

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Response of Plant Photosynthesis to Nanomaterialsver, the impact of NPs on photosynthetic effectiveness is found to varied between plants as well as even within species. They either improve plant photosynthetic effectiveness by enhancing the light-harvesting complexes or block routes through obstructing the electron transport chain. For instance,

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Impact of Nanomaterials on Plant Secondary Metabolismr properties. The application of elicitors is a simple strategy to increase the production of secondary metabolites in plant cell and tissues. The ability of nanomaterials to induce plant secondary metabolism has recently been exploited in the elicitation of pharmaceutically important compounds from

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Toxic Effects of Nanomaterials on Plant Cellular Mechanismsxicity. Despite numerous benefits of NMs for agriculture, exploring the risks of nanotoxicity due to the incorporation of NMs into food for human consumption has become imperative as engineered and incidental nanomaterials can cause future health problems. This chapter presents the results and progr

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Interaction of Nanomaterials with Plant Macromolecules: Nucleic Acid, Proteins and Hormonesnotes on some of the most recently used nanomaterials in agriculture such as metals and their oxides, quantum dots, graphene, arabinoxylan and chitosan nanoparticles, single and multi-walled carbon nanotubes. Interactions with these above-mentioned macromolecules are explored, along with futuristic

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