Modelling network effects of biological control: the case of the Philippine coconut scale insect outbreak

Biological control provides a sustainable alternative to chemical pesticides for controlling pests in agriculture. Chemical pesticides may lack the specificity to limit their adverse effects just on target species. However, the use of a biological control agent may cause ripple effects on ecological...

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Bibliographic Details
Published in:BioControl (Dordrecht, Netherlands) Netherlands), 2023-04, Vol.68 (2), p.117-130
Main Authors: Almarinez, Billy Joel M., Amalin, Divina M., Aviso, Kathleen B., Cabezas, Heriberto, Lao, Angelyn R., Tan, Raymond R.
Format: Article
Language:English
Subjects:
Agriculture
Agrochemicals
Animal Biochemistry
Animal Ecology
Behavioral Sciences
Biological control
Biological effects
Biomedical and Life Sciences
Chemical pest control
Ecological effects
Ecosystems
Entomology
Infestation
Insects
Life Sciences
Network analysis
Outbreaks
Pest control
Pest outbreaks
Pesticides
Pests
Plant Pathology
Plant reproduction
Plantations
Pollinators
Productivity
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Summary:Biological control provides a sustainable alternative to chemical pesticides for controlling pests in agriculture. Chemical pesticides may lack the specificity to limit their adverse effects just on target species. However, the use of a biological control agent may cause ripple effects on ecological communities that exist within a farm or plantation. Ecological network analysis models can be used to anticipate such indirect impacts. In this work, we develop a graph theoretic model to gauge the effects of using a biological control agent to suppress the infestation of coconut plantations by scale insects. The model is based on the process graph technique described in our previous work. We retrospectively analyze the case of massive scale insect infestation of coconut plantations that occurred in the Philippines in the previous decade. Simulations with the model indicate the efficacy of biological control to suppress the infestation, particularly for serious outbreaks. On the other hand, use of a neonicotinoid poses undue collateral risks to the system because of its lethal effect on pollinators and on the biological control agents. Both of these results are corroborated by the actual field experience.
ISSN:1386-6141
1573-8248
DOI:10.1007/s10526-023-10188-4