1. Smith, L. B., Kasai, S. & Scott, J. G. Pyrethroid resistance in Aedes aegypti and Aedes albopictus: Important mosquito vectors of human diseases. Pesticide Biochemistry and Physiology 133, 1–12 (2016).
2. Benelli, G. & Mehlhorn, H. Declining malaria, rising of dengue and Zika virus: insights for mosquito vector control. Parasitology Research 115, 1747–1754 (2016).
3. Campbell, G. L., Marfin, A. A., Lanciotti, R. S. & Gubler, D. J. West Nile virus. Lancet Infectious Diseases 2, 519–529 (2002).
4. Tolle, M. A. Mosquito-borne Diseases. Current Problems in Pediatric and Adolescent Health Care 39, 97–140 (2009).
5. Wang, Y. et al. Investigation of mosquito larval habitats and insecticide resistance in an area with a high incidence of mosquito-borne diseases in Jining, Shandong Province. PLOS ONE 15, e0229764 (2020).
6. Fivelman, Q. L., Butcher, G. A., Adagu, I. S., Warhurst, D. C. & Pasvol, G. Malarone treatment failure and in vitro confirmation of resistance of Plasmodium falciparum isolate from Lagos, Nigeria. Malaria Journal 1, 1–4 (2002).
7. Fillinger, U. & Lindsay, S. W. Larval source management for malaria control in Africa: Myths and reality. Malaria Journal 10, 353 (2011).
8. Hemingway, J. The role of vector control in stopping the transmission of malaria: threats and opportunities. Philosophical Transactions of the Royal Society B: Biological Sciences 369, 20130431 (2014).
9. Silver, J. B. Mosquito Ecology-Field Sampling Methods 3rd Edition. Springer (2008). doi:10.1007/978-1-4020-6666-5
10. Walton, C., Sharpe, R. G., Pritchard, S. J., Thelwell, N. J. & Butlin, R. K. Molecular identification of mosquito species. Biological Journal of the Linnean Society 68, 241–256 (1999).
11. Minamoto, T., Yamanaka, H., Takahara, T., Honjo, M. N. & Kawabata, Z. Surveillance of fish species composition using environmental DNA. Limnology 13, 193–197 (2012).
12. Sato, M. O. et al. Usefulness of environmental DNA for detecting Schistosoma mansoni occurrence sites in Madagascar. International Journal of Infectious Diseases 76, 130–136 (2018).
13. Goldberg, C. S. et al. Critical considerations for the application of environmental DNA methods to detect aquatic species. Methods in Ecology and Evolution 7, 1299–1307 (2016).
14. Wang, G. et al. Identifying the Main Mosquito Species in China Based on DNA Barcoding. PLoS ONE 7, e47051 (2012).
15. Schneider, J. et al. Detection of invasive mosquito vectors using environmental DNA (eDNA) from water samples. PLoS ONE 11, e0162493 (2016).
16. Odero, J., Gomes, B., Fillinger, U. & Weetman, D. Detection and quantification of Anopheles gambiae sensu lato mosquito larvae in experimental aquatic habitats using environmental DNA (eDNA). Wellcome Open Research 3, 26 (2018).
17. Yamanaka, H. et al. A simple method for preserving environmental DNA in water samples at ambient temperature by addition of cationic surfactant. Limnology 18, 233–241 (2017).
18. Minamoto, T., Hayami, K., Sakata, M. K. & Imamura, A. Real-time polymerase chain reaction assays for environmental DNA detection of three salmonid fish in Hokkaido, Japan: Application to winter surveys. Ecological Research 34, 237–242 (2019).
19. Sakata, M. K., Maki, N., Sugiyama, H. & Minamoto, T. Identifying a breeding habitat of a critically endangered fish, Acheilognathus typus, in a natural river in Japan. The Science of Nature 104, 100 (2017).
20. Ellison, S. L. R., English, C. A., Burns, M. J. & Keer, J. T. Routes to improving the reliability of low level DNA analysis using real-time PCR. BMC Biotechnology 6, 33 (2006).
21. Barnes, M. A. et al. Environmental conditions influence eDNA persistence in aquatic systems. Environmental Science and Technology 48, 1819–1827 (2014).
22. Mauvisseau, Q., Troth, C., Young, E., Burian, A. & Sweet, M. The development of an eDNA based detection method for the invasive shrimp Dikerogammarus haemobaphes. Management of Biological Invasions 10, (2019).
23. Sansom, B. J. & Sassoubre, L. M. Environmental DNA (eDNA) Shedding and Decay Rates to Model Freshwater Mussel eDNA Transport in a River. Environmental Science and Technology 51, 14244–14253 (2017).
24. Barnes, M. A. & Turner, C. R. The ecology of environmental DNA and implications for conservation genetics. Conservation Genetics 17, 1–17 (2016).
25. Ondiba, I. M., Oyieke, F. A., Athinya, D. K., Nyamongo, I. K. & Estambale, B. B. A. Larval species diversity, seasonal occurrence and larval habitat preference of mosquitoes transmitting Rift Valley fever and malaria in Baringo County, Kenya. Parasites and Vectors 12, (2019).
26. Tusting, L. S. et al. Mosquito larval source management for controlling malaria. Cochrane Database of Systematic Reviews 2013, (2013).
27. Batra, C. P., Mittal, P. K., Adak, T. & Ansari, M. A. Efficacy of IGR compound Starycide 480 SC (Triflumuron) against mosquito larvae in clear and polluted water. Journal of Vector Borne Diseases 42, 109–116 (2005).
28. Spear, S. F., Groves, J. D., Williams, L. a & Waits, L. P. Using environmental DNA methods to improve detectability in a hellbender monitoring program. Biological Conservation 183, 38–45 (2014).
29. Takeshita, D. et al. Projection range of eDNA analysis in marshes: a suggestion from the Siberian salamander ( Salamandrella keyserlingii ) inhabiting the Kushiro marsh, Japan . PeerJ 8, e9764 (2020).
30. Doi, H. et al. Water sampling for environmental DNA surveys by using an unmanned aerial vehicle. Limnology and Oceanography: Methods 15, 939–944 (2017).