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Fighting Malaria in Africa, a CRID perspective

Mosquittoes in Africa: expert research and recommendations to National Malaria Control Programmes – Dr. NDO Cyrille, Vector Biologist, Head of Parasitology and Microbiology Department at CRID

Mosquittoes in Africa: expert research and recommendations to National Malaria Control Programmes – Dr. NDO Cyrille, Vector Biologist, Head of Parasitology and Microbiology Department at CRID

Africa has over 10 indigenous Anopheles species with ability to transmit Plasmodium parasites that cause malaria [2, 3]. Therefore, control of these vector species is the pillar of prevention strategies. Vector control relies extensively on the use of pyrethroid-based insecticide-treated bed nets or indoor residual spraying. Mosquitoes have however developed resistance against the insecticides actually in use. More so, in some settings, it has been noticed that instead of biting indoor (as people are protected by bed net), some mosquito populations have developed a new tendency of biting outdoor in the early hours of the day when people are not protected by the bed net. This high insecticide resistance profile (and associated change in biting behaviour) is a major challenge to the efforts of National Malaria Control Programmes in fighting the killer disease [4, 5].

The Centre for Research in Infectious Diseases (CRID) has over the years sort to understand the challenges in the fight against malaria vectors, and to find ways to improve the efficacy of current vector control tools. Drawing from studies conducted in Central, West and  East Africa, cases of high resistance levels to insecticides in major malaria vectors leading to loss of efficacy of Long Lasting Insecticidal Nets (LLINs) have been reported [6-13].

 In order to improve malaria control and a possible disease elimination which is backed in the agenda [14], there is an urgent need to first preserve the optimal efficacy of existing vector control tools. We advise National Malaria Control Programmes to conduct routine entomological surveillance for determination of insecticide resistance profile and mechanisms in vector populations, using standard WHO bioassays protocols, but also molecular techniques that can allow early detection of target site [15, 16] and metabolic-mediated resistance [6, 11, 17]. Availability of these data will help to better design resistance management strategies, and to implement evidence-based and integrated vector control.

Meanwhile researchers at the CRID are working, in collaboration with the broad malaria research community,  in  indentifying new insecticides with different mode of action and/or in developing alternative vector control tools such as the sterile insect technique [18, 19].

References

1.   WHO: World Malaria Report 2019. WHO Global Malaria Programme. World Health Organiszation https://wwwwhoint/publications-detail/world-malaria-report-2019.

2.   Fontenille D, Cohuet A, Awono-Ambene PH, Antonio-Nkondjio C, Wondji C, Kengne P, Dia I, Boccolini D, Duchemin JB, Rajaonarivelo V et al: [Systematics and biology of Anopheles vectors of Plasmodium in Africa, recent data]. Med Trop (Mars) 2003, 63(3):247-253.

3.   Antonio-Nkondjio C, Kerah CH, Simard F, Awono-Ambene P, Chouaibou M, Tchuinkam T, Fontenille D: Complexity of the malaria vectorial system in Cameroon: contribution of secondary vectors to malaria transmission. J Med Entomol 2006, 43(6):1215-1221.

4.   Benelli G, Beier JC: Current vector control challenges in the fight against malaria. Acta Trop 2017, 174:91-96.

5.   Sougoufara S, Doucoure S, Backe Sembene PM, Harry M, Sokhna C: Challenges for malaria vector control in sub-Saharan Africa: Resistance and behavioral adaptations in Anopheles populations. J Vector Borne Dis 2017, 54(1):4-15.

6.   Weedall GD, Mugenzi LMJ, Menze BD, Tchouakui M, Ibrahim SS, Amvongo-Adjia N, Irving H, Wondji MJ, Tchoupo M, Djouaka R et al: A cytochrome P450 allele confers pyrethroid resistance on a major African malaria vector, reducing insecticide-treated bednet efficacy. Sci Transl Med 2019, 11(484).

7.   Tchigossou G, Djouaka R, Akoton R, Riveron JM, Irving H, Atoyebi S, Moutairou K, Yessoufou A, Wondji CS: Molecular basis of permethrin and DDT resistance in an Anopheles funestus population from Benin. Parasit Vectors 2018, 11(1):602.

8.  Kamgang B, Tchapga W, Ngoagouni C, Sangbakembi-Ngounou C, Wondji M, Riveron JM, Wondji CS: Exploring insecticide resistance mechanisms in three major malaria vectors from Bangui in Central African Republic. Pathog Glob Health 2018, 112(7):349-359.

9.   Riveron JM, Watsenga F, Irving H, Irish SR, Wondji CS: High Plasmodium Infection Rate and Reduced Bed Net Efficacy in Multiple Insecticide-Resistant Malaria Vectors in Kinshasa, Democratic Republic of Congo. J Infect Dis 2018, 217(2):320-328.

10. Ibrahim SS, Fadel AN, Tchouakui M, Terence E, Wondji MJ, Tchoupo M, Kerah-Hinzoumbe C, Wanji S, Wondji CS: High insecticide resistance in the major malaria vector Anopheles coluzzii in Chad Republic. Infect Dis Poverty 2019, 8(1):100.

11. Mugenzi LMJ, Menze BD, Tchouakui M, Wondji MJ, Irving H, Tchoupo M, Hearn J, Weedall GD, Riveron JM, Wondji CS: Cis-regulatory CYP6P9b P450 variants associated with loss of insecticide-treated bed net efficacy against Anopheles funestus. Nat Commun 2019, 10(1):4652.

12. Ibrahim SS, Mukhtar MM, Irving H, Labbo R, Kusimo MO, Mahamadou I, Wondji CS: High Plasmodium infection and multiple insecticide resistance in a major malaria vector Anopheles coluzzii from Sahel of Niger Republic. Malar J 2019, 18(1):181.

13. Riveron JM, Huijben S, Tchapga W, Tchouakui M, Wondji MJ, Tchoupo M, Irving H, Cuamba N, Maquina M, Paaijmans K et al: Escalation of Pyrethroid Resistance in the Malaria Vector Anopheles funestus Induces a Loss of Efficacy of Piperonyl Butoxide-Based Insecticide-Treated Nets in Mozambique. J Infect Dis 2019, 220(3):467-475.

14. Rabinovich RN, Drakeley C, Djimde AA, Hall BF, Hay SI, Hemingway J, Kaslow DC, Noor A, Okumu F, Steketee R et al: malERA: An updated research agenda for malaria elimination and eradication. PLoS Med 2017, 14(11):e1002456.

15. Nwane P, Etang J, Chouasmall yi UM, Toto JC, Mimpfoundi R, Simard F: Kdr-based insecticide resistance in Anopheles gambiae s.s populations in. BMC Res Notes 2011, 4:463.

16. Djogbenou L, Weill M, Hougard JM, Raymond M, Akogbeto M, Chandre F: Characterization of insensitive acetylcholinesterase (ace-1R) in Anopheles gambiae (Diptera: Culicidae): resistance levels and dominance. J Med Entomol 2007, 44(5):805-810.

17. Riveron JM, Yunta C, Ibrahim SS, Djouaka R, Irving H, Menze BD, Ismail HM, Hemingway J, Ranson H, Albert A et al: A single mutation in the GSTe2 gene allows tracking of metabolically based insecticide resistance in a major malaria vector. Genome Biol 2014, 15(2):R27.

18. Lobo NF, Achee NL, Greico J, Collins FH: Modern Vector Control. Cold Spring Harb Perspect Med 2018, 8(1).

19. Ndo C, Poumachu Y, Metitsi D, Awono-Ambene HP, Tchuinkam T, Gilles JLR, Bourtzis K: Isolation and characterization of a temperature-sensitive lethal strain of Anopheles arabiensis for SIT-based application. Parasit Vectors 2018, 11(Suppl 2):659.

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