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1. Can nanotechnology and genomics innovations trigger agricultural revolution and sustainable development?

   https://doi.org/10.1007/s10142-024-01485-x  

   Javaid, Arzish; Hameed, Sadaf; Li, Lijie; Zhang, Zhiyong; Zhang, Baohong; -Rahman, Mehboob-ur (December 2024, Functional & Integrative Genomics)

   Abstract At the dawn of new millennium, policy makers and researchers focused on sustainable agricultural growth, aiming for food security and enhanced food quality. Several emerging scientific innovations hold the promise to meet the future challenges. Nanotechnology presents a promising avenue to tackle the diverse challenges in agriculture. By leveraging nanomaterials, including nano fertilizers, pesticides, and sensors, it provides targeted delivery methods, enhancing efficacy in both crop production and protection. This integration of nanotechnology with agriculture introduces innovations like disease diagnostics, improved nutrient uptake in plants, and advanced delivery systems for agrochemicals. These precision-based approaches not only optimize resource utilization but also reduce environmental impact, aligning well with sustainability objectives. Concurrently, genetic innovations, including genome editing and advanced breeding techniques, enable the development of crops with improved yield, resilience, and nutritional content. The emergence of precision gene-editing technologies, exemplified by CRISPR/Cas9, can transform the realm of genetic modification and enabled precise manipulation of plant genomes while avoiding the incorporation of external DNAs. Integration of nanotechnology and genetic innovations in agriculture presents a transformative approach. Leveraging nanoparticles for targeted genetic modifications, nanosensors for early plant health monitoring, and precision nanomaterials for controlled delivery of inputs offers a sustainable pathway towards enhanced crop productivity, resource efficiency, and food safety throughout the agricultural lifecycle. This comprehensive review outlines the pivotal role of nanotechnology in precision agriculture, emphasizing soil health improvement, stress resilience against biotic and abiotic factors, environmental sustainability, and genetic engineering. 

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2. Chitosan-Coated Mesoporous Silica Nanoparticles for Suppression of Fusarium virguliforme in Soybeans ( Glycine max )

   https://doi.org/10.1021/acsagscitech.4c00025  

   O’Keefe, Tana L.; Deng, Chaoyi; Wang, Yi; Mohamud, Sharmaka; Torres-Gómez, Andres; Tuga, Beza; Huang, Cheng-Hsin; Alvarez Reyes, Wilanyi R.; White, Jason C.; Haynes, Christy L. (May 2024, ACS Agricultural Science & Technology)

   There is a need to develop new and sustainable agricultural technologies to help provide global food security, and nanoscale materials show promising results in this area. In this study, mesoporous silica nanoparticles (MSNs) and chitosan-coated mesoporous silica nanoparticles (CTS-MSNs) were synthesized and applied to soybeans (Glycine max) by two different strategies in greenhouse and field studies to study the role of dissolved silicic acid and chitosan in enhancing plant growth and suppressing disease damage caused by Fusarium virguliforme. Plant growth and health were assessed by measuring the soybean biomass and chlorophyll content in both healthy and Fusarium-infected plants at harvest. In the greenhouse study, foliar and seed applications with 250 mg/L nanoparticle treatments were compared. A single seed treatment of MSNs reduced disease severity by 30% and increased chlorophyll content in both healthy and infected plants by 12%. Based on greenhouse results, seed application was used in the follow-up field study and MSNs and CTS-MSNs reduced disease progression by 12 and 15%, respectively. A significant 32% increase was observed for chlorophyll content for plants treated with CTS-MSNs. Perhaps most importantly, nanoscale silica seed treatment significantly increased (23–68%) the micronutrient (Zn, Mn, Mg, K, B) content of soybean pods, suggesting a potential sustainable strategy for nano-enabled biofortification to address nutrition insecurity. Overall, these findings indicate that MSN and CTS-MSN seed treatments in soybeans enable disease suppression and increase plant health as part of a nano-enabled strategy for sustainable agriculture. 

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3. Targeted delivery of nanomaterials with chemical cargoes in plants enabled by a biorecognition motif

   https://doi.org/10.1038/s41467-020-15731-w  

   Santana, Israel; Wu, Honghong; Hu, Peiguang; Giraldo, Juan Pablo (April 2020, Nature Communications)

   Abstract Current approaches for nanomaterial delivery in plants are unable to target specific subcellular compartments with high precision, limiting our ability to engineer plant function. We demonstrate a nanoscale platform that targets and delivers nanomaterials with biochemicals to plant photosynthetic organelles (chloroplasts) using a guiding peptide recognition motif. Quantum dot (QD) fluorescence emission in a low background window allows confocal microscopy imaging and quantitative detection by elemental analysis in plant cells and organelles. QD functionalization with β-cyclodextrin molecular baskets enables loading and delivery of diverse chemicals, and nanoparticle coating with a rationally designed and conserved guiding peptide targets their delivery to chloroplasts. Peptide biorecognition provides high delivery efficiency and specificity of QD with chemical cargoes to chloroplasts in plant cells in vivo (74.6 ± 10.8%) and more specific tunable changes of chloroplast redox function than chemicals alone. Targeted delivery of nanomaterials with chemical cargoes guided by biorecognition motifs has a broad range of nanotechnology applications in plant biology and bioengineering, nanoparticle-plant interactions, and nano-enabled agriculture. 

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4. Summer education in nano- and biological approaches to protect plants against drought stress

   Britt, D.W. (October 2017, Sustainable Nanotechnology Organization)

   An 8-week summer research experience for undergraduates was developed at Utah State University to train participants in nanotechnology and microbiome engineering approaches that the participants applied to improve plant resilience to stress and enhance food production. Nine participants from two-year colleges serving predominantly Native American and Hispanic populations were recruited with the aim of providing these students the confidence, skills, and passion for life-long learning to complete a four-year STEM degree and beyond. An interdisciplinary approach introduced students to nanotechnology, plant-microbiome functioning, and soilless growth platforms, demonstrating needs for diversity in skills and teamwork in solving problems. Six weeks of guided research modules were followed by student-designed projects conducted as small groups. Students synthesized and characterized nanoparticles, assessed mechanical properties of plants, isolated endophytic bacteria from wheat seed, and assessed the plant-protective properties imparted by the endophyte contrasted with a known root-colonizing beneficial microbe. Distinct responses of the two microbes to metal oxide nanoparticles having micronutrient and pesticide applications in agriculture demonstrated that nano-formulations may rapidly shift microbial populations based on susceptibility to nanoparticles / released ions. Participants gained a broad overview of nanotechnology and microbiome engineering as sustainable approaches for advancing plant productivity and agriculture under abiotic stress. 

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5. Advances in Translational Nanotechnology: Challenges and Opportunities

   https://doi.org/10.3390/app10144881  

   Mohapatra, Shyam S.; Frisina, Robert D.; Mohapatra, Subhra; Sneed, Kevin B.; Markoutsa, Eleni; Wang, Tao; Dutta, Rinku; Damnjanovic, Ratka; Phan, Manh-Huong; Denmark, Daniel J.; et al (July 2020, Applied Sciences)

   The burgeoning field of nanotechnology aims to create and deploy nanoscale structures, devices, and systems with novel, size-dependent properties and functions. The nanotechnology revolution has sparked radically new technologies and strategies across all scientific disciplines, with nanotechnology now applied to virtually every area of research and development in the US and globally. NanoFlorida was founded to create a forum for scientific exchange, promote networking among nanoscientists, encourage collaborative research efforts across institutions, forge strong industry-academia partnerships in nanoscience, and showcase the contributions of students and trainees in nanotechnology fields. The 2019 NanoFlorida International Conference expanded this vision to emphasize national and international participation, with a focus on advances made in translating nanotechnology. This review highlights notable research in the areas of engineering especially in optics, photonics and plasmonics and electronics; biomedical devices, nano-biotechnology, nanotherapeutics including both experimental nanotherapies and nanovaccines; nano-diagnostics and -theranostics; nano-enabled drug discovery platforms; tissue engineering, bioprinting, and environmental nanotechnology, as well as challenges and directions for future research. 

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