AI Article Synopsis
- Weeds significantly reduce crop yields worldwide, and while paraquat (PQ) is an effective herbicide, its high toxicity limits its use due to safety concerns.
- The study focuses on developing a safe and efficient nanoherbicide using mesoporous carbon nanoparticles (MCN) coated with α-CD polymer to control the release of PQ.
- Results show that the new nanoherbicides effectively manage weed outbreaks while posing low toxicity risks to humans and beneficial organisms, supporting the potential for broader agricultural use of PQ.
Article Abstract
Introduction: Weeds seriously affect crop yield in global agricultural production. Paraquat (PQ), as one of low cost and highly effective herbicide, is forbidden or severely restricted in production and sales owing to its lethal toxicity to humans. Creating an efficient and bio-friendly PQ formulation is crucial to facilitate the open use of PQ in world's agriculture.
Objectives: This study aims to construct one intelligent and bio-friendly mesoporous carbon nanoparticles (MCN) nanoherbicides coated with α-CD polymer (CDP) gatekeepers.
Methods: MCN was prepared through the low-concentration hydrothermal way, calcined and carbonized. PEG stalks were immobilized on MCN surface by amidation reaction. The PQ was trapped in the MCN pores via physical diffusion adsorption and the robust π-π effects between electron-deficient PQ and electron-rich MCN. CDP gatekeepers were fastened via host-guest effects between the chamber of α-CD units and PEG stalks.
Results: The PQ-loaded MCN-PEG@CDP nanoherbicides integrated with multi-stimuli responses to amylase, elevated temperature under sunlight, and competitors at leaf interface to control the PQ release for efficient weed control, while appeared low PQ leakage under the simulated human gastric or intestinal conditions, low cytotoxicity to human normal cells in vitro, and high mouse survival rate in vivo. Even through the nanoherbicides inevitably contact with water or intake by beneficial insects, they appear good biosafety on zebrafish (D. rerio) and honeybees (Apis mellifera L.).
Conclusion: The as-prepared nanoherbicides have high herbicidal efficacy and low risks to non-target species, and could promote the open use of PQ in agriculture.
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| http://dx.doi.org/10.1016/j.jare.2024.12.005 | DOI Listing |
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