Chemical characterization and insecticidal effect of &lt;i&gt;Moringa oleifera&lt;/i&gt; L. seeds extracts on common bean weevil (&lt;i&gt;Acanthoscelides obtectus&lt;/i&gt; Say)

Songwe, Thierry Atindo; Bekolo, Ndongo; Tueguem, William Norbert Kuate; Anaba, Désiré Manga; Zemko, Patrice Ngatsi; Yılmaz, Mustafa Abdullah; Sinan, Kouadio Ibrahime; Zengin, Gökhan; Ambang, Zachée

doi:10.53365/nrfhh/143056

Cited by 1 publication

(1 citation statement)

References 24 publications

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“…According to the findings of these studies, from result of table 3, compounds such as diaziridine derivatives, phytol, and squalene have been reported to have insecticidal properties [25][26][27]. Also from table 4, the insecticidal potential of the LDL extracts may be due to the presence of some of the identified compounds such as dioxirane, fumaric acid, oxalic acid, and myristic acid, which have all been reported to possess various insecticidal activities [28][29][30][31]. From the results of table 5, the chemistry of some of the identified compounds was revealed, such as the number of rotatable bonds, electronegativity, H-acceptor, and chemical structure using Osiris Online server [24].…”

Section: Discussionmentioning

confidence: 96%

Insecticidal Potentials and Identification of Bioactive Compounds from Extracts of Bacopa Floribunda and Ludwigia Decurrens Plants

Adewole¹,

Ogola-Emma²,

al.³

2022

JAC

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The negative impact of insecticides used to combat insect-borne plant ailments cannot be emphasized, as they have had a major influence on plant yields throughout time, and the side effect of insecticide residue on consumers cannot be overstated either. Callosobrochus maculatus is an insect that attacks cowpeas and has the potential to significantly reduce crop productivity. This research developed from investigations into the utilization of biological control technologies that have little or no harmful influence on humans or the environment. The leaves of Bacopa Floribunda (BFL) and Ludwigia Decurrens (LDL) were air dried, powdered, and extracted with n-hexane. The insecticidal activities were carried out according to protocol, and the LC50 was determined using online software from AAT Bioquest, Inc. The presence of bioactive compounds was detected using GC-MS. The Callosobrochus maculatus mortality rate was found to be a function of exposure time and concentration of the extracts, with the maximum mortality rate (66.67±8.82 percent) occurring after 72 hours at 0.5 mg/ml for BFL extract. The highest mortality rate (70.00 ±5.77 percent) was obtained for the LDL extract at 72 hours at 0.5 mg/ml of the extract concentration, which was better than the other extract (BFL) at 0.5 mg/ml. The lethal concentration LC50 for BFL varies from 0.251 (24 hours), 0.276 (48 hours), and 0.223 (72 hours), while the LC50 for LDL extract is 0.228 (24 hours), 0.039 (48 hours), and 0.663 (72 hours) (72 hrs). The presence of chemicals found could be linked to the extracts’ insecticidal properties. The excellent potential of the extracts as insect biocontrol agents against Callosobrochus maculatus can be recommended for future research as insect biocontrol agents.

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