Abstract
The large-scale application of volatile and highly water-soluble pesticides to guarantee crop production can often have negative impacts on the environment. The main loss pathways are vapor drift, direct volatilization, or leaching of the active substances. Consequently, the pesticide can either accumulate and/or undergo physicochemical transformations in the soil. In this scenario, we synthesized alginate nanoparticles using an inverse miniemulsion template in sunflower oil and successfully used them to encapsulate a hydrophilic herbicide, i.e., dicamba. The formulation and process conditions were adjusted to obtain a unimodal size distribution of nanohydrogels of about 20 nm. The loading of the nanoparticles with dicamba did not affect the nanohydrogel size nor the particle stability. The release of dicamba from the nanohydrogels was also tested: the alginate nanoparticles promoted the sustained and prolonged release of dicamba over ten days, demonstrating the potential of our preparation method to be employed for field application. The encapsulation of hydrophilic compounds inside our alginate nanoparticles could enable a more efficient use of pesticides, minimizing losses and thus environmental spreading. The use of biocompatible materials (alginate, sunflower oil) also guarantees the absence of toxic additives in the formulation.
Highlights
Pesticides are massively used worldwide in agriculture to control pests, including insects, weeds, rodents, fungi, and any armful organism in crop production and livestock management [1]
The synthesis, characterization, encapsulation capacity, and modulated release of dicamba from alginate nanohydrogels obtained via inverse miniemulsion are reported and discussed, opening perspectives for the application of this approach to the encapsulation of highly soluble, mobile, and/or volatile pesticides
Nanohydrogels were synthesized starting from an inverse miniemulsion template: 0.25–0.4 g of Pluronic PE 6100 were dissolved in 75 mL of sunflower oil to prepare the continuous phase
Summary
Pesticides are massively used worldwide in agriculture to control pests, including insects, weeds, rodents, fungi, and any armful organism in crop production and livestock management [1]. Hydrophilic AIs may need engineered solutions to control their release over time, guaranteeing a specific concentration for a prolonged time, and to limit their leaching in the subsoil (following, for example, irrigation or precipitations) To this aim, the AI can be embedded, adsorbed, or encapsulated in a nanoparticle or a micelle that modifies its solubility, mobility, lifetime, and/or bioavailability. The synthesis, characterization, encapsulation capacity, and modulated release of dicamba from alginate nanohydrogels obtained via inverse miniemulsion are reported and discussed, opening perspectives for the application of this approach to the encapsulation of highly soluble, mobile, and/or volatile pesticides. The sustained release of AI from the alginate nanohydrogels was guaranteed over ten days
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