Nanomaterials (Aug 2022)

Alternative Controlling Agent of <i>Theobroma grandiflorum</i> Pests: Nanoscale Surface and Fractal Analysis of Gelatin/PCL Loaded Particles Containing <i>Lippia origanoides</i> Essential Oil

  • Ana Luisa Farias Rocha,
  • Ronald Zico de Aguiar Nunes,
  • Robert Saraiva Matos,
  • Henrique Duarte da Fonseca Filho,
  • Jaqueline de Araújo Bezerra,
  • Alessandra Ramos Lima,
  • Francisco Eduardo Gontijo Guimarães,
  • Ana Maria Santa Rosa Pamplona,
  • Cláudia Majolo,
  • Maria Geralda de Souza,
  • Pedro Henrique Campelo,
  • Ştefan Ţălu,
  • Vanderlei Salvador Bagnato,
  • Natalia Mayumi Inada,
  • Edgar Aparecido Sanches

DOI
https://doi.org/10.3390/nano12152712
Journal volume & issue
Vol. 12, no. 15
p. 2712

Abstract

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A new systematic structural study was performed using the Atomic Force Microscopy (AFM) reporting statistical parameters of polymeric particles based on gelatin and poly-ε-caprolactone (PCL) containing essential oil from Lippia origanoides. The developed biocides are efficient alternative controlling agents of Conotrachelus humeropictus and Moniliophtora perniciosa, the main pests of Theobroma grandiflorum. Our results showed that the particles morphology can be successfully controlled by advanced stereometric parameters, pointing to an appropriate concentration of encapsulated essential oil according to the particle surface characteristics. For this reason, the absolute concentration of 1000 µg·mL−1 (P1000 system) was encapsulated, resulting in the most suitable surface microtexture, allowing a faster and more efficient essential oil release. Loaded particles presented zeta potential around (–54.3 ± 2.3) mV at pH = 8, and particle size distribution ranging from 113 to 442 nm. The hydrodynamic diameter of 90% of the particle population was found to be up to (405 ± 31) nm in the P1000 system. The essential oil release was evaluated up to 80 h, with maximum release concentrations of 63% and 95% for P500 and P1000, respectively. The best fit for the release profiles was obtained using the Korsmeyer–Peppas mathematical model. Loaded particles resulted in 100% mortality of C. humeropictus up to 48 h. The antifungal tests against M. perniciosa resulted in a minimum inhibitory concentration of 250 µg·mL−1, and the P1000 system produced growth inhibition up to 7 days. The developed system has potential as alternative controlling agent, due to its physical stability, particle surface microtexture, as well as pronounced bioactivity of the encapsulated essential oil.

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