A Pyr-loaded polymer microparticle for effectively controlling Solenopsis invicta (Hymenoptera: Formicidae) in the nest.

Human interference and incorrect use of pesticides are easy to induce red imported fire ant (RIFA) escape and migrate from a nest, resulting in ineffective control of RIFA. In order to avoid RIFA alert, we designed an amphiphilic PSI-mPEG-Boc-DAH loaded Pyr to make the microparticles with effective controlled release. The investigation showed that the quantity of Pyr released by Pyr@PSI-mPEG-Boc-DAH under acidic environment was only 36.40 ± 1.90% at 48 h, whereas the release rate of original Pyr was 75.23 ± 5.71%. And the RIFA mortality rate of 1 ppm Pyr in Pyr@PSI-mPEG-Boc-DAH microparticles at 48 h was only 7.78%, which was significantly lower than that of the Pyr (47.78%). Futhermore, the death rate increased sharply after 48 h, and reached 95.84% within a week after using Pyr@PSI-mPEG-Boc-DAH microparticles. Moreover, PSI-mPEG-Boc-DAH carriers could be absorbed and even transported to crop of the RIFA for subsequent trophallaxis by using fluorescence tracking. In the field experiment, the reduction rate of Pyr@PSI-mPEG-Boc-DAH treatment was achieved 99.89% after 7 d. Pyr@PSI-mPEG-Boc-DAH didn't cause RIFA to be alarmed within 48 h and could kill nearly all of ants in the nest after 7 d, which showed a very good control effect in the field experiment. This work provided a new idea and guidance for the effective control RIFA and the development of sustainable agriculture.

Enzyme-Responsive Lignin Nanocarriers for Triggered Delivery of Abamectin to Control Plant Root-Knot Nematodes (Meloidogyne incognita).

Intelligently responsive nanoparticles can improve insecticidal activity against target organisms and reduce the use of pesticides in agriculture. In this study, enzymatic hydrolysis lignin (EHL) nanocarriers with enzyme responsiveness were successfully prepared by electrostatic interaction, and abamectin (Abm)-loaded EHL-based nanoparticles (Abm@L-CL) were investigated. The release behavior of Abm@L-CL nanoparticles showed that Abm was released rapidly in the presence of cellulase and pectinase but slowly under natural conditions. The insecticidal activity of Abm@L-CL treatment (LC50 = 0.68 µg/mL) against nematodes (Meloidogyne incognita) was significantly more effective than that of original Abm treatment (LC50 = 1.32 µg/mL). The mortality rate of Abm@L-CL was more than 90% by applying the same dose of Abm after 12 h. The bioactivity of Abm@L-CL against root-knot nematodes was 1.7-fold greater than that of Abm. The result of fluorescence indicated that nanoparticles could enter the intestinal tract through the oral cavity of nematodes and achieve obvious gastric toxicity. Furthermore, the enzyme-controlled lignin-based Abm nanocarriers could penetrate the tomato root near the elongation zone. This study provided intelligent enzyme-responsive nanocarriers for efficient management of soil-borne diseases and pests in green agricultural inputs.

Polyurea microencapsulate suspension: An efficient carrier for enhanced herbicidal activity of pretilachlor and reducing its side effects.

In this study, Pretilachlor polyurea microencapsulate suspension (PMS) with effective controlled release function was carefully prepared. Under the optimal conditions, wall material PM-200 dosage 4%, emulsifier T-60 dosage 4% with S-20 as solvent, the prepared PMS was demonstrated to have encapsulation efficiency approaching to 95.27 ± 0.57 % and high suspension rates of 97.33 ± 0.49 %. Afterwards, PMS was proved to possess average release rate reached to 85.56 %, 55.46 % and 15.85 % respectively in acidic, basic and natural medium. Subsequently, the herbicidal activity of PMS on barnyard grass and the growth safety of rice were evaluated. PMS showed enhanced herbicidal activity against barnyard grass and had lower toxicity to rice growth compared with technical pretilachlor at dose 270-540 g (a.i.)/hm2. In addition, the use safety of PMS was validated to be comparable to that of commercially available pretilachlor emulsifiable concentrate containing additive safener at dose 270-540 g (a.i.)/hm2. Moreover, inhibitory effect of PMS on rice growth was demonstrated to completely eliminated by cooperatively treatment with fenclorim. It was concluded that PMS had enhanced herbicidal activity and application safety, meeting the requirements of minimizing adverse effects of the herbicide on the environment, and enjoying a great application potential in agriculture.