Adhesive Nanocomposite for Prolonging Foliar Retention and Synergistic Weeding and Nourishing

Ji, Yanzheng; Huang, Ming; Yan, Jia; Qi, Taomei; Li, Tao; Liu, Qing; Lü, Shaoyu; Liu, Mingzhu

doi:10.1002/adsu.202000010

Cited by 14 publications

(13 citation statements)

References 52 publications

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“…The development of intensive agriculture techniques and agrochemicals, especially pesticides, in the mid-20 th century are responsible for feeding the bulk of global population today. [1][2][3] About 4.1 million tons of pesticides were applied globally in 2018, which contributed to protecting almost 30% output of assembly, wherein a high surface area to volume ratio is desirable for enhanced adhesion/encapsulation of AIs for controlled release applications. [18] To prepare nanoscale particles of CEs, various bottom-up techniques such as emulsification-evaporation, solvent displacement, and dialysis have been developed; [19][20][21] however the use of high boiling point organic and chlorinated solvents, [18,19] additional polymers as stabilizing agents taken together with the risk of polymer degradation during the sonication process [19] are significant impediments to the use of these approaches for drug/AI encapsulation applications.…”

Section: Introductionmentioning

confidence: 99%

“…The development of intensive agriculture techniques and agrochemicals, especially pesticides, in the mid‐20 th century are responsible for feeding the bulk of global population today. [ 1–3 ] About 4.1 million tons of pesticides were applied globally in 2018, which contributed to protecting almost 30% output of global agricultural products. [ 1,4–6 ] The importance of pesticides notwithstanding, negative impacts on terrestrial and aquatic biodiversity, deleterious effects on non‐target organisms, increased pathogen resistance, and accumulation in the food chain are some of the negative effects because of the overuse of pesticides.…”

Section: Introductionmentioning

confidence: 99%

“…Controlled release formulations bond or encapsulate the AI within a micro/nanoscale carrier typically developed from a polymer. [ 2,3,8,9 ]…”

Section: Introductionmentioning

confidence: 99%

“…Controlled release formulations bond or encapsulate the AI within a micro/nanoscale carrier typically developed from a polymer. [2,3,8,9] Traditional pesticide delivery methods involve larger application volumes of AI, with approximately 90% wasted on nontargets, or through environmental loss and degradation. [1,5] In contrast, controlled release formulations can help tailor the bioavailability of a small quantity of AI based on crop and soil environment requirements while minimizing operation hazards and reducing the inhalation and contact toxicity of the pesticides to the non-targets.…”

mentioning

confidence: 99%

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Toward Sustainable Crop Protection: Aqueous Dispersions of Biodegradable Particles with Tunable Release and Rainfastness

Pirzada

Sohail

Tripathi

et al. 2021

Adv Funct Materials

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Fabrication of aqueous particulate dispersions of biodegradable cellulose esters (CEs) as efficient carriers of agrochemical active‐ingredients (AIs) for foliar applications, is reported. The use of different ester substituent groups on CE permits modulation of particle morphology and size, from irregular shapes (<350 nm) to spheres (≈1.1 µm diameter), while maintaining stability as supported by minimal change in zeta potential and particle size over one year. Rainfastness is tested by simulating >50 mm h−1 rainfall on coated banana and tomato leaves and silicon. Surface coverage loss as low as 9%, based on the nature of leaf and formulation, confirms the rainfastness of the formulations. Variation in the release kinetics of a model AI fluopyram from different CEs can be attributed to the particle morphology and the nature of binding between fluopyram and various CEs. Thermodynamic analysis demonstrates spontaneous binding between fluopyram and multiple sites of CEs, justifying its two‐step release from CE particles. System functionalities are corroborated via in‐vitro fungal inhibition assays demonstrating a 100% inhibition of the fungal growth. This “lab‐to‐leaf” approach of materials development involving fundamental insights and functional performance reveals CE dispersions are promising green agricultural formulations with the potential to impact a myriad of crops around the globe.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…Controlled release formulations bond or encapsulate the AI within a micro/nanoscale carrier typically developed from a polymer. [ 2,3,8,9 ]…”

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Toward Sustainable Crop Protection: Aqueous Dispersions of Biodegradable Particles with Tunable Release and Rainfastness

Pirzada

Sohail

Tripathi

et al. 2021

Adv Funct Materials

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“…Figure f shows a schematic diagram of the forces of the Cpf-MSNs@PDA droplet on the hydrophobic leaves; the three key forces for the droplet to maintain balance were gravity, support, and adhesion. Due to the abundant catechol groups in PDA, the adhesion of the PDA wrapped nanopesticide to the leaves was impressively enhanced by the interaction with hydroxyl groups of the crop leaves’ cuticle through hydrogen bonds, which effectively prevented the rolling loss of Cpf-MSNs@PDA. , …”

Section: Resultsmentioning

confidence: 99%

An Alkali-Triggered Polydopamine Modified Mesoporous Silica Nanopesticide for Smart Delivery of Chlorpyrifos with Low Loss

Kan

Lü

Deng

et al. 2022

ACS Agric. Sci. Technol.

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The development of nanotechnology provides a feasible and effective way to reduce pesticide loss and improve pesticide utilization. In this study, we created chlorpyrifos-loaded mesoporous silica nanocomposites modified with polydopamine (Cpf-MSNs@PDA) for the smart control of pests. The release of Cpf from the nanocomposite was alkali triggered and temperature dependent, guaranteeing the sustained and steady effectiveness of the active constituent with prolonged persistence time. The modification with PDA endowed the nanocomposite with better foliar adhesion and rain erosion resistance. Compared with Cpf, the leaf slip angle of Cpf-MSNs@PDA was increased from 27° to 60°, and the rain erosion loss was reduced by 2.6 times. The insecticidal persistence of the Cpf-MSNs@PDA nanopesticide was measured and found to be better than that of commercial Cpf with bi-insecticidal pathways. In pathway 1, a small portion of Cpf (16.7%) was released from Cpf-MSNs@PDA in vitro to perform contact toxicity on Mythimna separata, which shows an advantage of sustained release. In pathway 2, after being ingested, the alkaline midgut microenvironment of M. separata triggered the degradation of Cpf-MSNs@PDA, inducing the release of all the Cpf to exert acute gastric toxicity. These results highlight the potential of a nanopesticide in the delivery of an active pesticide ingredient with low loss and high efficiency. The design of a smart nanocomposite for the control of a specific type of pest or disease provides ideas for the development of sustainable agriculture.

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Precise and High‐Throughput Delivery of Micronutrients in Plants Enabled by Pollen‐Inspired Spiny and Biodegradable Microcapsules

Liu,

Cao,

et al. 2024

Advanced Materials

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Decarbonizing food production and mitigating agriculture's environmental impact require new technologies for precise delivery of fertilizers and pesticides to plants. The cuticle, a waxy barrier that protects the surface of leaves, causes 60%–90% runoff of fertilizers and pesticides, leading to the wastage of intensive resources, soil depletion, and water bodies pollution. Solutions to mitigate runoff include adding chemicals (e.g., surfactants) to decrease surface tension and enhance cuticles' permeability but have low efficacy. In this study, vapor‐induced synergistic differentiation (VISDi) is used to nanomanufacture echinate pollen‐like, high payload content (≈50 wt%) microcapsules decorated with robust spines that mechanically disrupt the cuticle and adhere to the leaf. VISDi induces a core–shell structure in the spines, enabling the release of agrochemicals from the microparticles' body into the leaf. As proof of concept, precise and highthroughput delivery of iron fertilizer in Fe‐deficient spinach plants is demonstrated. Spray of spiny microparticles improves leaf adhesion by mechanical interlocking, reduces wash‐off by an ≈12.5 fold, and enhances chlorophyll content by ≈7.3 times compared to the application of spherical counterparts. Together, these results show that spiny microparticles can mitigate agricultural runoff and provide a high‐throughput tool for precise plant drug delivery.

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Adhesive Nanocomposite for Prolonging Foliar Retention and Synergistic Weeding and Nourishing

Cited by 14 publications

References 52 publications

Toward Sustainable Crop Protection: Aqueous Dispersions of Biodegradable Particles with Tunable Release and Rainfastness

Toward Sustainable Crop Protection: Aqueous Dispersions of Biodegradable Particles with Tunable Release and Rainfastness

An Alkali-Triggered Polydopamine Modified Mesoporous Silica Nanopesticide for Smart Delivery of Chlorpyrifos with Low Loss

Precise and High‐Throughput Delivery of Micronutrients in Plants Enabled by Pollen‐Inspired Spiny and Biodegradable Microcapsules

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