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Engineering Atrazine Loaded Poly (lactic- co-glycolic Acid) Nanoparticles to Ameliorate Environmental Challenges.

Authors
  • Schnoor, Brian1, 2
  • Elhendawy, Ahmad1, 2
  • Joseph, Suzanna1, 2
  • Putman, Mark1, 2
  • Chacón-Cerdas, Randall3
  • Flores-Mora, Dora3
  • Bravo-Moraga, Felipe4
  • Gonzalez-Nilo, Fernando4
  • Salvador-Morales, Carolina1, 2
  • 1 Bioengineering Department , George Mason University , 4400 University Drive MS 1J7, Fairfax , Virginia 22030 , United States. , (United States)
  • 2 Institute of Advanced Biomedical Research , George Mason University , 10920 George Mason Circle, MS1A9 , Manassas , Virginia 20110 , United States. , (United States)
  • 3 InstitutoTecnológico de Costa Rica , Biotechnology Research Center , Cartago , Costa Rica. , (Costa Rica)
  • 4 Center for Bioinformatics and Integrative Biology, Facultad de Ciencias Biologicas , Universidad Andres Bello , Santiago 8370146 , Chile. , (Chile)
Type
Published Article
Journal
Journal of Agricultural and Food Chemistry
Publisher
American Chemical Society
Publication Date
Aug 01, 2018
Volume
66
Issue
30
Pages
7889–7898
Identifiers
DOI: 10.1021/acs.jafc.8b01911
PMID: 30039704
Source
Medline
Keywords
Language
English
License
Unknown

Abstract

The use of herbicides plays a vital role in controlling weeds and conserving crops; however, its usage generates both environmental and economic problems. For example, herbicides pose a financial issue as farmers must apply large quantities to protect crops due to absorption rates of less than 0.1%. Therefore, there is a great need for the development of new methods to mitigate these issues. Here, we report for the first time the synthesis of poly(lactic- co-glycolic-acid) (PLGA) nanoherbicides loaded with atrazine as an active ingredient. We used potato plants as a biological model to assess the herbicidal activity of the engineered PLGA nanoherbicides. Our method produced nanoherbicides with an average size of 110 ± 10 nm prior to lyophilization. Fifty percent of the loaded atrazine in the PLGA matrix is released in 72 h. Furthermore, we performed Monte Carlo simulations to determine the chemical interaction among atrazine, PLGA, and the solvent system. One of the most significant outcomes of these simulations was to find the formation of a hydrogen bond of 1.9 Å between PLGA and atrazine, which makes this interaction very stable. Our in vitro findings showed that as atrazine concentration is increased in PLGA nanoparticles, potato plants undergo a significant decrease in stem length, root length, fresh weight, dry weight, and the number of leaves, with root length being the most affected. These experimental results suggest the herbicidal effectiveness of atrazine-loaded PLGA nanoherbicides in inhibiting the growth of the potato plant. Hence, we present the proof-of-concept for using PLGA nanoherbicides as an alternative method for inhibiting weed growth. Future studies will involve a deep understanding of the mechanism of plant-nanoherbicide interaction as well as the role of PLGA as a growth potentiator.

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