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Journal Abstract Search

124 related items for PubMed ID: 38771663

  • 1. Identification of a Novel Inhibitor of Cimex lectularius Acetylcholinesterase.
    Qin J, Yuchi Z.
    J Agric Food Chem; 2024 Jun 05; 72(22):12498-12507. PubMed ID: 38771663
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  • 2. Common substitution mutation F348Y of acetylcholinesterase gene contributes to organophosphate and carbamate resistance in Cimex lectularius and C. hemipterus.
    Komagata O, Kasai S, Itokawa K, Minagawa K, Kazuma T, Mizutani K, Muto A, Tanikawa T, Adachi M, Komatsu N, Tomita T.
    Insect Biochem Mol Biol; 2021 Nov 05; 138():103637. PubMed ID: 34454015
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  • 3. Biochemical efficacy, molecular docking and inhibitory effect of 2, 3-dimethylmaleic anhydride on insect acetylcholinesterase.
    Singh KD, Labala RK, Devi TB, Singh NI, Chanu HD, Sougrakpam S, Nameirakpam BS, Sahoo D, Rajashekar Y.
    Sci Rep; 2017 Oct 02; 7(1):12483. PubMed ID: 28970561
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  • 4. Aryl methylcarbamates: potency and selectivity towards wild-type and carbamate-insensitive (G119S) Anopheles gambiae acetylcholinesterase, and toxicity to G3 strain An. gambiae.
    Wong DM, Li J, Lam PC, Hartsel JA, Mutunga JM, Totrov M, Bloomquist JR, Carlier PR.
    Chem Biol Interact; 2013 Mar 25; 203(1):314-8. PubMed ID: 22989775
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  • 5. Biochemical and molecular characterisation of acetylcholinesterase in four field populations of Bactrocera dorsalis (Hendel) (Diptera: Tephritidae).
    Shen GM, Wang XN, Dou W, Wang JJ.
    Pest Manag Sci; 2012 Dec 25; 68(12):1553-63. PubMed ID: 23007913
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  • 11. Synthesis, Biological Evaluation and In Silico Computational Studies of 7-Chloro-4-(1H-1,2,3-triazol-1-yl)quinoline Derivatives: Search for New Controlling Agents against Spodoptera frugiperda (Lepidoptera: Noctuidae) Larvae.
    Rosado-Solano DN, Barón-Rodríguez MA, Sanabria Florez PL, Luna-Parada LK, Puerto-Galvis CE, Zorro-González AF, Kouznetsov VV, Vargas-Méndez LY.
    J Agric Food Chem; 2019 Aug 21; 67(33):9210-9219. PubMed ID: 31390203
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  • 12. Insecticide resistance mechanisms with novel 'kdr' type gene mutations in the tropical bed bug Cimex hemipterus.
    Punchihewa R, de Silva WAPP, Weeraratne TC, Karunaratne SHPP.
    Parasit Vectors; 2019 Jun 21; 12(1):310. PubMed ID: 31227020
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  • 13. Enzyme Dynamics Determine the Potency and Selectivity of Inhibitors Targeting Disease-Transmitting Mosquitoes.
    Kumari R, Lindgren C, Kumar R, Forsgren N, Andersson CD, Ekström F, Linusson A.
    ACS Infect Dis; 2024 Oct 11; 10(10):3664-3680. PubMed ID: 39291389
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  • 14. The characterization of Lucilia cuprina acetylcholinesterase as a drug target, and the identification of novel inhibitors by high throughput screening.
    Ilg T, Cramer J, Lutz J, Noack S, Schmitt H, Williams H, Newton T.
    Insect Biochem Mol Biol; 2011 Jul 11; 41(7):470-83. PubMed ID: 21530657
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  • 17. The discovery of new acetylcholinesterase inhibitors derived from pharmacophore modeling, virtual screening, docking simulation and bioassays.
    Zhang Y, Zhang S, Xu G, Yan H, Pu Y, Zuo Z.
    Mol Biosyst; 2016 Nov 15; 12(12):3734-3742. PubMed ID: 27801451
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  • 18. Biochemical and toxicological properties of two acetylcholinesterases from the common bed bug, Cimex lectularius.
    Hwang CE, Kim YH, Kwon DH, Seong KM, Choi JY, Je YH, Lee SH.
    Pestic Biochem Physiol; 2014 Mar 15; 110():20-6. PubMed ID: 24759047
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  • 19. Can acetylcholinesterase serve as a target for developing more selective insecticides?
    Lang GJ, Zhu KY, Zhang CX.
    Curr Drug Targets; 2012 Apr 15; 13(4):495-501. PubMed ID: 22280346
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  • 20. In silico approaches to evaluate the molecular properties of organophosphate compounds to inhibit acetylcholinesterase activity in housefly.
    Marimuthu P, Lee YJ, Kim B, Seo SS.
    J Biomol Struct Dyn; 2019 Feb 15; 37(2):307-320. PubMed ID: 29322868
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