References
[1] Heeb L, Jenner E, Cock MJ. Climate-smart pest management: building resilience of farms and landscapes to changing pest threats. J Pest Sci. 2019;92(3):951-69.
[2] Pathak VM, Verma VK, Rawat BS, Kaur B, Babu N, Sharma A, et al. Current status of pesticide effects on environment, human health and it’s eco-friendly management as bioremediation: A comprehensive review. Front Microbiol. 2022;13:962619.
[3] Aarif KO M, Alam A, Hotak Y. Smart sensor technologies shaping the future of precision agriculture: Recent advances and future outlooks. J Sens. 2025;2025(1):2460098. doi:10.1155/js/2460098.
[4] Karlsson Green K, Stenberg JA, Lankinen Å. Making sense of Integrated Pest Management (IPM) in the light of evolution. Evol Appl. 2020;13(8):1791-805.
[5] Ali MA, Abdellah IM, Eletmany MR. Towards sustainable management of insect pests: Protecting food security through Ecological Intensification. Int J Chem Biochem Sci. 2023;24(4):386-94.
[6] Singh S, Sharma P, Pal N, Sarma DK, Tiwari R, Kumar M. Holistic one health surveillance framework: synergizing environmental, animal, and human determinants for enhanced infectious disease management. ACS Infect Dis. 2024;10(3):808-26.
[7] Rizvi SAH, George J, Reddy GVP, Zeng X, Guerrero A. Latest developments in insect sex pheromone research and its application in agricultural pest management. Insects. 2021;12(6):484.
[8] Shashank DU, Sujatha GS, Teja KSS, Hema AP, Mishra R, Abinaya S, et al. A Comprehensive Review of Advances in Semiochemical Exploitation for Insect Pest Management. J Adv Biol Biotechnol. 2024;27(9):845-63.
[9] Gill RJ, Baldock KCR, Brown MJF, Cresswell JE, Dicks LV, Fountain MT, et al. Protecting an ecosystem service: approaches to understanding and mitigating threats to wild insect pollinators. In: Advances in Ecological Research. Vol. 54. Academic Press; 2016. p. 135-206.
[10] Hailay Gebremariam G. A Systematic Review of Insect Decline and Discovery: Trends, Drivers, and Conservation Strategies over the past Two Decades. Psyche (Camb Mass). 2024;2024(1):5998962.
[11] Busse M, Zoll F, Siebert R, Bartels A, Bokelmann A, Scharschmidt P. How farmers think about insects: perceptions of biodiversity, biodiversity loss and attitudes towards insect-friendly farming practices. Biodivers Conserv. 2021;30:3045-66.
[12] Siddiqui JA, Fan R, Naz H, Bamisile BS, Hafeez M, Ghani MI, et al. Insights into insecticide-resistance mechanisms in invasive species: Challenges and control strategies. Front Physiol. 2023;13:1112278.
[13] Beckie HJ, Busi R, Lopez-Ruiz FJ, Umina PA. Herbicide resistance management strategies: how do they compare with those for insecticides, fungicides and antibiotics? Pest Manag Sci. 2021;77(7):3049-56.
[14] Lamichhane JR, Aubertot JN, Begg G, Birch ANE, Boonekamp P, Dachbrodt-Saaydeh S, et al. Networking of integrated pest management: A powerful approach to address common challenges in agriculture. Crop Prot. 2016;89:139-51.
[15] Ramesha NM, Mahanta D. Understanding Insect Behavior and Physiology for Effective Pest Management. Uttar Pradesh J Zool. 2024;45(14):312-23.
[16] Agarwal ML, Sunil V. Basic behavioural patterns in insects and applications of behavioural manipulation in insect pest management. J Entomol Zool Stud. 2020;8:991-6.
[17] Barragán-Fonseca KB, Ortiz JE, García-Arteaga JD, Giron D. The role of insects in agri-food sustainability: Taking advantage of ecosystem services to achieve integrated insect management. Insects. 2025;16(8):866.
[18] Al Naggar Y, Fahmy NM, Alkhaibari AM, Al-Akeel RK, Alharbi HM, Mohamed A, et al. Mechanisms and Genetic Drivers of Resistance of Insect Pests to Insecticides and Approaches to Its Control. Toxics. 2025;13(8):681. doi:10.3390/toxics13080681.
[19] Razzaq MK, Hina A, Abbasi A, Karikari B, Ashraf HJ, Mohiuddin M, et al. Molecular and genetic insights into secondary metabolic regulation underlying insect-pest resistance in legumes. Funct Integr Genomics. 2023;23(3):217.
[20] Pereira JL, Antunes SC, Castro BB, et al. Toxicity evaluation of three pesticides on non-target aquatic and soil organisms: commercial formulation versus active ingredient. Ecotoxicology. 2009;18:455-63. doi:10.1007/s10646-009-0300-y.
[21] Araújo MF, Castanheira EMS, Sousa SF. The Buzz on Insecticides: A Review of Uses, Molecular Structures, Targets, Adverse Effects, and Alternatives. Molecules. 2023;28:3641. doi:10.3390/molecules28083641.
[22] Deletre E. Prospects for repellent in pest control: current developments and future challenges. Chemoecology. 2016;26:127-42. doi:10.1007/s00049-016-0214-0.
[23] Baker BP, Green TA, Loker AJ. Biological control and integrated pest management in organic and conventional systems. Biol Control. 2020;140:104095.
[24] Khursheed A, Rather MA, Jain V, Rasool S, Nazir R, Malik NA. Plant based natural products as potential ecofriendly and safer biopesticides: A comprehensive overview of their advantages over conventional pesticides, limitations and regulatory aspects. Microb Pathog. 2022;173:105854.
[25] Elnahal AS, El-Saadony MT, Saad AM, Desoky ESM, El-Tahan AM, Rady MM, et al. The use of microbial inoculants for biological control, plant growth promotion, and sustainable agriculture: A review. Eur J Plant Pathol. 2022;162(4):759-92.
[26] Humphreys RK. Predator-prey behavioural interactions on plants, with special emphasis on aphid dropping defence and ladybird search strategies [doctoral thesis]. St Andrews: The University of St Andrews; 2022.
[27] Tscharntke T, Karp DS, Chaplin-Kramer R, Batáry P, DeClerck F, Gratton C, et al. When natural habitat fails to enhance biological pest control – Five hypotheses. Biol Conserv. 2016;204:449-58.
[28] Gonzalez F. New opportunities for the integration of microorganisms into biological pest control systems in greenhouse crops. J Pest Sci. 2016;89:295-311. doi:10.1007/s10340-016-0751-x.
[29] Tonnang HEZ, Hervé BDB, Biber-Freudenberger L, Salifu D, Subramanian S, Ngowi VB, et al. Advances in crop insect modelling methods—Towards a whole system approach. Ecol Modell. 2017;354:88-103.
[30] Holland JM. Structure, function and management of semi-natural habitats for conservation biological control: a review of European studies. Pest Manag Sci. 2016;72(9):1638-51.
[31] van Emden HF. Conservation biological control: from theory to practice. In: Proceedings of the International Symposium on Biological Control of Arthropods; 2002 Jan 14-18;. p. 14-8.
[32] Ahmad N. Pest Management in Agriculture: Integrated Approaches for Sustainable Control. Frontiers in Agriculture. 2024;1(2):416-43. [Journal not indexed; name retained as published]
[33] Sivinski J. Augmentative biological control: research and methods to help make it work. CABI Rev. 2014;(2013):1-11.
[34] Buitenhuis R, Cock MJW, Colmenarez YC, De Clercq P, Edgington S, Gadaleta P, et al. Sustainable use and conservation of microbial and invertebrate biological control agents and microbial biostimulants. Rome: FAO; 2023.
[35] Mourya PK, Singh JK, Chaudhary P, Chaudhary AK, Upadhayay V. Role of Drone Technology in Insect Pest Management. 2024. [Source unclear; not a journal]
[36] Evans KJ, Terhorst A, Kang BH. From data to decisions: helping crop producers build their actionable knowledge. Crit Rev Plant Sci. 2017;36(2):71-88.
[37] Struik PC, Kuyper TW. Sustainable intensification in agriculture: the richer shade of green. A review. Agron Sustain Dev. 2017;37:1-15.
[38] Li C, Wang M. Pest and disease management in agricultural production with artificial intelligence: Innovative applications and development trends. Adv Resour Res. 2024;4(3):381-401.
[39] Tommasi D. Managing living marine resources in a dynamic environment: the role of seasonal to decadal climate forecasts. Prog Oceanogr. 2017;152:15-49.
[40] Jacquet F, Jeuffroy MH, Jouan J, Le Cadre E, Litrico I, Malausa T, et al. Pesticide-free agriculture as a new paradigm for research. Agron Sustain Dev. 2022;42(1):8.
[41] Shedole ST, Madhu YB. Automated Pest Detection and Control in Agriculture using IoT and Image Processing. J Surv Fish Sci. 2019;106-16.
[42] Bottrell DG, Schoenly KG. Integrated pest management for resource-limited farmers: challenges for achieving ecological, social and economic sustainability. J Agric Sci. 2018;156(3):408-26.
[43] Kalogiannidis S. Role of crop-protection technologies in sustainable agricultural productivity and management. Land. 2022;11(10):1680.
[44] Komal J. Unveiling the Genetic Symphony: Harnessing CRISPR-Cas Genome Editing for Effective Insect Pest Management. Plants. 2023;12:3961. doi:10.3390/plants12233961.
[45] Munaweera TIK. Modern plant biotechnology as a strategy in addressing climate change and attaining food security. Agric Food Secur. 2022;11(1):1-28.
[46] Khan MR, Rehman N. Implementation of novel genomic and biotechnological interventions for accelerated breeding of crops. In: Plant Speed Breeding and High-Throughput Technologies. Boca Raton: CRC Press; 2024. p. 53-81.
[47] Jain A. Nanomaterials in food and agriculture: an overview on their safety concerns and regulatory issues. Crit Rev Food Sci Nutr. 2018;58(2):297-317.
[48] Tizard M. Strategies to enable the adoption of animal biotechnology to sustainably improve global food safety and security. Transgenic Res. 2016;25:575-95.
[49] Zilberman D. Agricultural GMOs—what we know and where scientists disagree. Sustainability. 2018;10(5):1514.
[50] Zhao Y. Advancements and Future Prospects of CRISPR-Cas-Based Population Replacement Strategies in Insect Pest Management. Insects. 2024;15:653.
doi:10.3390/insects15090653.
[51] Clapp J, Ruder SL. Precision technologies for agriculture: Digital farming, gene-edited crops, and the politics of sustainability. Glob Environ Polit. 2020;20(3):49-69.
[52] Moon TT. CRISPR-Cas Genome Editing for Insect Pest Stress Management in Crop Plants. Stresses. 2022;2:493-514. doi:10.3390/stresses2040034.
[53] Kavhiza NJ. Improving Crop Productivity and Ensuring Food Security through the Adoption of Genetically Modified Crops in Sub-Saharan Africa. Agronomy. 2022;12:439. doi:10.3390/agronomy12020439.
[54] Legros M. Gene drive strategies of pest control in agricultural systems: Challenges and opportunities. Evol Appl. 2021;14(9):2162-78.
[55] Kumar R. Advances in genomic tools for plant breeding: harnessing DNA molecular markers, genomic selection, and genome editing. Biol Res. 2024;57(1):80.
[56] Pixley KV. Genome editing, gene drives, and synthetic biology: will they contribute to disease-resistant crops, and who will benefit? Annu Rev Phytopathol. 2019;57(1):165-88.
[57] Wesseler J. EU regulation of genetically modified microorganisms in light of new policy developments: Possible implications for EU bioeconomy investments. Appl Econ Perspect Policy. 2023;45(2):839-59.
[58] Bain C, Lindberg S, Selfa T. Emerging sociotechnical imaginaries for gene edited crops for foods in the United States: implications for governance. Agric Hum Values. 2020;37:265-79.
[59] Gildea L, Ayariga JA, Robertson BK. Bacteriophages as biocontrol agents in livestock food production. Microorganisms. 2022;10(11):2126.
[60] Thakur N, Kaur S. Microbial biopesticides: current status and advancement. In: New and Future Developments in Microbial Biotechnology and Bioengineering. Elsevier; 2020. p. 243-82.
[61] Blouin DD, Perry EM. Whom does service learning really serve? Community-based organizations’ perspectives on service learning. Teach Sociol. 2009;37(2):120-35.
[62] Rose DC, Keating C, Morris C. Understanding how to influence farmers’ decision-making behaviour: a social science literature review. 2018. [Report, not a journal]
[63] Lange L. Developing a sustainable and circular bio-based economy in EU: by partnering across sectors, upscaling and using new knowledge faster, and for the benefit of climate, environment & biodiversity, and people & business. Front Bioeng Biotechnol. 2021;8:619066.
[64] Wyckhuys KAG. Maximizing farm-level uptake and diffusion of biological control innovations in today’s digital era. BioControl. 2018;63(1):133-48.
[65] Janssen SJC. Towards a new generation of agricultural system data, models and knowledge products: Information and communication technology. Agric Syst. 2017;155:200-12.