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Professor Abdoulaye Diabaté
Professor Abdoulaye Diabaté is one of Africa’s foremost malaria experts, he is a prominent Burkinabè researcher known for his contributions to the field of medical entomology and malaria research.

As Head of Medical Entomology and Parasitology, Professor Diabaté also serves as the Principal Investigator of Target Malaria Burkina Faso. He established the project in Burkina Faso in 2012. He is leading some of the world’s most advanced work on controlling malaria mosquitoes using genetically modified mosquitoes, in particular the use of gene drive, an innovative approach to genetic modification used by Target Malaria.

Professor Diabaté is a leading figure in malaria research, particularly in the field of genetical approaches to malaria reduction in Africa. He hopes to bring gene drive, an innovative genetic tool which could help reduce malaria transmission, to Africa in the future.

Professor Diabaté's expertise and research contributions have gained international recognition, leading to invitations as a guest speaker at esteemed universities, including Harvard University. His collaborations with various research centres and universities around the world have fostered lasting partnerships and knowledge exchanges.

Professor Diabaté's dedication to advancing scientific knowledge in the fight against malaria has positioned him as a leading figure in medical entomology, contributing to groundbreaking research and initiatives in Burkina Faso and beyond. Notably, Professor Diabaté led the Target Malaria Burkina Faso team through the first release of genetically modified mosquitoes in Africa, marking a historic moment for science.

Professor Diabaté is principal investigator (PI) of the following projects:


 * Target Malaria Burkina Faso
 * Engineering fungi to kill malaria mosquitoes

Early life and education
Professor Abdoulaye Diabaté was born in Burkina Faso, a small landlocked country in West Africa. As a child, he suffered from many malaria episodes and almost died of the disease when he was four years old. This experience was pivotal in his vocation to take on a scientific career and dedicate it to finding innovative solutions to fight malaria.

In his country, Burkina Faso, malaria rages every rainy season. In 2021, there were an estimated 8.3 million cases of malaria, that’s 37% of the whole population. There were also 18,900 deaths, that’s 15% of all deaths (WHO, 2022). Malaria is one of the primary causes of medical consultations and hospital admissions.

Professor Diabaté studied at the University of Ouagadougou, where he obtained a Doctorate of Animal Biology and Ecology degree. Later, he earned his Ph.D. in Parasitology from the University of Montpellier II in France in 2003.

In 2005, Diabaté embarked on a post-doctoral fellowship at the Laboratory of Malaria and Vector research of the National Institutes of Health (NIH) in the United States. After completing his fellowship, he returned to Burkina Faso in 2009 and took up a position at the Research Institute in Health Sciences (Institut de Recherche en Sciences de la Santé) in Bobo-Dioulasso, Burkina Faso.

Target Malaria
Abdoulaye Diabaté is leading the research on genetic technologies for malaria control in Burkina Faso, the only country in Africa to be working with genetically modified mosquitoes.

Gene drive is a technology that biases the rate of inheritance, to push a genetic modification to be inherited by the offspring 90% of the time instead of the normal mendelian inheritance rate of 50%. In the context of malaria, Target Malaria is developing genetically modified mosquitoes that would carry the gene drive technology to reduce the population of malaria-transmitting mosquitoes. It could potentially be a cost-efficient, long-term and sustainable vector tool that would complement existing and new tools and be very well suited for an African environment where malaria is a rural disease that strikes the vulnerable population, mostly children and pregnant women.

In 2019, he led the team who conducted the first release of genetically modified mosquitoes in Africa. His team also successfully imported in 2022 a new strain of non gene drive genetically modified mosquitoes, the male bias. It was a significant achievement for an African research team. It was developed in the UK at Imperial College London, tested in the UK and Italy and imported to the insectary at the Institut de Recherche en Sciences de la Santé(IRSS) in Bobo-Dioulasso, Burkina Faso. The team are currently studying it under contained use and hope to conduct an experimental field release in 2025.

Professor Diabaté has been a key proponent of the importance of engaging stakeholders in science. In his team, he has hired social scientists, sociologists, anthropologists and stakeholder engagement practitioners to make sure that every step of the research done by Target Malaria in Burkina Faso is shared with those who may be affected by the research activities.

Professor Diabaté is passionate about sharing with stakeholders the fundamental issues about the role of science in our society, about the scientific progress and ethics of specific impacts of science. As well as about our perception of the natural world and about how diseases have shaped and impacted human civilisations.

Fungi
Professor Diabaté’s team genetically modified the fungi Metarhizium pingshaense (Mp) to specifically deliver insecticidal proteins into mosquito blood. This transgenic fungus is engineered to express an insect-specific spider neurotoxin called Hybrid (Ca++/K+ channel blocker).

Recognition
Professor Diabaté was honoured with the following distinctions:


 * The Royal Society Pfizer Award in 2013
 * Grand Challenges Star in Global Health grant
 * MRC/DFID African Leader Scheme grant
 * PAMCA (Pan-African Mosquito Control Association) award for his significant contributions to the field of medical entomology
 * "Chevalier des Palmes académiques" by the Government of Burkina Faso for his outstanding scientific research in the country in 2022
 * Vox Future Perfect 50, among the 50 global personalities shaping the future
 * Professor Diabaté and his team of eight researchers based in the United States and Burkina Faso for receiving the 2019 Newcomb Cleveland Prize at the American Association for the Advancement of Science (AAAS). For more information, please read this blog by Raymond J. Monnat, Jr. M.D.

More recently, he was chosen as a finalist for the Falling Walls 2023: Science Breakthrough of the Year in the Science & Innovation Management category. On August 16th 2023, it was announced that Professor Diabaté was among the Science & Innovation Management category winners and an interview was published on the Falling Walls website titled 'ERADICATING MALARIA: GENETIC SOLUTIONS AND AFRICAN LEADERSHIP'.

Media coverage
As a respected expert in his field, Professor Diabaté has been interviewed by various prestigious international and national media outlets, including the BBC, Netflix, New York Times, and Burkinabè media, further amplifying his research and its impact on global health.

Articles
New York Times Magazine, The Gene Drive Dilemma: We Can Alter Entire Species, but Should We?, 8 January 2020 https://www.nytimes.com/2020/01/08/magazine/gene-drive-mosquitoes.html

Vox, Future Perfect 50, "Working toward a healthier world": "FredAboagye-Antwi, Mamadou Coulibaly, Abdoulaye Diabate, and Jonathan Kayondo are developing a groundbreaking “gene drive” approach to eradicating malaria." 2022 https://www.vox.com/future-perfect/23364075/future-perfect-50-target-malaria-gene-drive-mosquito

The Conversation, Fighting malaria with fungi: biologists engineer a fungus to be deadlier to mosquitoes, 30 May 2019, https://theconversation.com/fighting-malaria-with-fungi-biologists-engineer-a-fungus-to-be-deadlier-to-mosquitoes-117940

NH Directors Blog, Combating Mosquitoes with an Engineered Fungus, 11 June 2019, https://directorsblog.nih.gov/2019/06/11/combating-mosquitoes-with-an-engineered-fungus/

VOA Afrique, Des moustiques génétiquement modifiés lâchés dans la nature, 24 July 2019, https://www.voaafrique.com/a/des-moustiques-g%C3%A9n%C3%A9tiquement-modifi%C3%A9s-l%C3%A2ch%C3%A9s-dans-la-nature-/5013374.html

Le Monde Afrique, Au Burkina, un premier lâcher de moustiques génétiquement modifiés crée la polémique, 4 July 2019, https://www.lemonde.fr/afrique/article/2019/07/04/au-burkina-un-premier-lacher-de-moustiques-genetiquement-modifies-cree-la-polemique_5485432_3212.html

Wired, A Netflix Series Explores the Brave New World of CRISPR, 18 October 2019, https://www.wired.com/story/a-netflix-series-explores-the-brave-new-world-of-crispr/

BBC, Des moustiques génétiquement modifiés pour lutter contre le paludisme, 13 September 2018, https://www.bbc.com/afrique/region-45505022

Podcasts
Johns Hopkins Malaria Minute podcast: Abdoulaye Diabaté, the entomologist bringing gene drives to Africa https://open.spotify.com/episode/4LVNazf20DQu70g4EHLd8O?si=d15a930e5b134b61&nd=1

Brave New Planet (Professor Eric Lander podcast): “Reshaping nature through gene drives” https://podcasts.apple.com/us/podcast/reshaping-nature-through-gene-drives/id1531898121?i=1000497749144

TV/Documentaries
Netflix, (Un)natural selection (episode 3: Changing an entire species): https://www.netflix.com/fr-en/title/80208910

Canal+: https://www.youtube.com/watch?v=UzYhdIbXwBI

Talks
Grand challenges: https://www.grandchallenges.org/video/new-tools-mosquito-population-engineering-and-control-abdoulaye-diabate-burkina-faso

Videos
Entretien avec Dr. Abdoulaye Diabaté

Results from the release of non gene drive genetically modified sterile male mosquitoes

Royal Society Pfizer Award 2013_Dr Abdoulaye Diabate

Dr. Abdoulaye Diabaté (President, PAMCA Burkina Faso Chapter)

Dr. Abdoulaye Diabaté, investigateur général, décline l'importance du projet Target Malaria

Dr Abdoulaye Diabaté explains Target Malaria

Publications
SARE I, BALDINI F, VIANA M, Athanase B, DJIGMA F, DIABATE A, BILGO E Native Metarhizium strains: kinetics of adhesion to the cuticle and their virulence against mosquitoes, 14 Feb 2023, Research Square doi: 10.21203/RS.3.RS-2573863/V1

Stephens K, Gnambani EJ, Bilgo E, Diabate A, Soby S, Draft Genome of a Member of the Family Chromobacteriaceae Isolated from Anopheles Mosquitoes in West Africa. Microbiology resource announcements .October 2022 doi 10.1128/MRA.00524-22

Bayili K, Ki HD, Bayili B, Sow B, Ouattara A, Small G, Dabire RK, Diabate A, Laboratory and experimental hut trial evaluation of VECTRON™ T500 for indoor residual spraying (IRS) against insecticide resistant malaria vectors in Burkina Faso. Gates Open Research. 25 Apr 2022, doi 10.12688/GATESOPENRES.13578.1

Pare Toe L, Barry N, Ky AD, Kekele S, Meda WI, Bayala K, Drabo M, Thizy D, Majorin O, Coche I, Epopa PS, Namountougou M, Dabire RK, Diabate A. A multi-disciplinary approach for building a common understanding of genetic engineering for malaria control in Burkina Faso. Humanities and Social Sciences Communications. 20 Apr 2022. Doi 10.1057/S41599-022-01165-W

Bayili K, Ki HD, Bayili B, Sow B, Ouattara A, Small G, Hien AS, Dabire RK, Diabate A. Laboratory and experimental hut trial evaluation of VECTRON ™ T500 for indoor residual spraying (IRS) against insecticide resistant malaria vectors in Burkina Faso. Gates open research. Jan 2022. Doi: 10.12688/GATESOPENRES.13578.2

N'Do S, Bandibabone JB, Soma DD, Musaka BZ, Prudhomme J, Habamungu CC, Namountougou M, Sangaré I, Kientega M, Kaboré DAP, Bayili K, Yerbanga RS, Diabate A, Dabire RK, Ouedraogo J-B, Belem AMG, Boëte C, Guardiola-Claramonte M, Chimanuka B. Insecticide resistance profiles in malaria vector populations from Sud-Kivu in the Democratic Republic of the Congo. Transactions of the Royal Society of Tropical Medicine and Hygiene. Nov 2021. Doi 10.1093/TRSTMH/TRAB116

Pare Toe L, Barry N, Ky AD, Kekele S, Meda W, Bayala K, Drabo M, Thizy D, Diabate A, Small-scale release of non-gene drive mosquitoes in Burkina Faso: from engagement implementation to assessment, a learning journey. Malaria journal. 9 Oct 2021 doi: 10.1186/S12936-021-03929-2

Guindo, A., Epopa, P.S., Doumbia, S. et al. Improved BioGents® Sentinel trap with heat (BGSH) for outdoor collections of Anopheline species in Burkina Faso and Mali, West Africa. Parasites Vectors 14, 82 (2021). https://doi.org/10.1186/s13071-020-04527-y

Chemonges Wanyama, E., Dicko, B., Pare Toe, L. et al. Co‐developing a common glossary with stakeholders for engagement on new genetic approaches for malaria control in a local African setting. Malar J 20, 53 (2021). https://doi.org/10.1186/s12936-020-03577-y

Wang G, Vega-Rodríguez J, Diabate A, Liu J, Cui C, Nignan C, Dong L, Li F, Ouedrago CO, Bandaogo AM, Sawadogo PS, Maiga H, Alves E Silva TL, Pascini TV, Wang S, Jacobs-Lorena M. Clock genes and environmental cues coordinate Anopheles pheromone synthesis, swarming, and mating.Science371,411-415(2021).DOI:10.1126/science.abd4359

Gueye OK, Tchouakui M, Diabate AK, Faye MB, Ahmed AA, Wondji MJ, Nguiffo DN, J. Mugenzi LM, Tripet F, Konaté L, et al. Insecticide Resistance Profiling of Anopheles coluzzii and Anopheles gambiae Populations in the Southern Senegal: Role of Target Sites and Metabolic Resistance Mechanisms. Genes. 2020; 11(12):1403. https://doi.org/10.3390/genes11121403

Gueye OK, Tchouakui M, Diabate AK, Faye MB, Ahmed AA, Wondji MJ, Nguiffo DN, J. Mugenzi LM, Tripet F, Konaté L, et al. Insecticide Resistance Profiling of Anopheles coluzzii and Anopheles gambiae Populations in the Southern Senegal: Role of Target Sites and Metabolic Resistance Mechanisms. Genes. 2020; 11(12):1403. https://doi.org/10.3390/genes11121403

Chemonges EW, Dicko B, Toe LP, Coulibaly M, Barry N, Bayala K, Diabate A, Drabo M, Kayondo J, Kekele S, Kodio S, Ky AD, Linga RR, Magala E, Meda WI, Mukwaya S, Namukwaya A, Robinso B, Samoura H, Sanogo K, thizy D, Traore F Good Practices and Lessons Learned in Developing Local Language Tools to Support Stakeholder Engagement Activities, 23 September 2020, PREPRINT (Version 1) available at Research Square

Gnambani EJ, Bilgo E, Sanou A, Dabire RK, Diabate A. Infection of highly insecticide-resistant malaria vector Anopheles coluzzii with entomopathogenic bacteria Chromobacterium violaceum reduces its survival, blood feeding propensity and fecundity, 17 September 2020, PREPRINT (Version 5) available at Research Square

Gnambani EJ, Bilgo E, Sanou A, Dabire RK, Diabate A Infection of highly insecticide-resistant malaria vector Anopheles coluzzii with entomopathogenic bacteria Chromobacterium violaceum reduces its survival, blood feeding propensity and fecundity, 29 August 2020, PREPRINT (Version 4) available at Research Square

Gnambani EJ, Bilgo E, Sanou A, Dabire RK, Diabate A Infection of highly insecticide-resistant malaria vector Anopheles coluzzii with entomopathogenic bacteria Chromobacterium violaceum reduces its survival, blood feeding propensity and fecundity, 13 July 2020, PREPRINT (Version 3) available at Research Square

Barry, N., Toé, P., Pare Toe, L. et al. Motivations and expectations driving community participation in entomological research projects: Target Malaria as a case study in Bana, Western Burkina Faso. Malar J 19, 199 (2020). https://doi.org/10.1186/s12936-020-03277-7

Nourou Barry, Patrice Toé, Lea Pare/Toe et al. Motivations and expectations driving community participation in entomological research projects: Target Malaria as a case study in Bana, Western Burkina Faso, 04 June 2020, PREPRINT (Version 4) available at Research Square

Nourou Barry, Patrice Toé, Lea Pare/Toe et al. Motivations and expectations driving community participation in entomological research projects: Target Malaria as a case study in Bana, Western Burkina Faso, 02 April 2020, PREPRINT (Version 2) available at Research Square

Edounou Jacques Gnambani, Etienne Bilgo, Adama Sanou et al. Infection of highly insecticide-resistant malaria vector Anopheles coluzzii with an environment friendly entomopathogenic bacteria Chromobacterium violaceum reduces its survival, blood feeding propensity and fecundity, 10 February 2020, PREPRINT (Version 1) available at Research Square

Nourou Barry, Patrice Toé, Lea Pare/Toe et al. Community expectations and motivations in entomological research activities for the development of innovative malaria vector control tools: Target Malaria as a case study in Bana, Western Burkina Faso, 01 January 2020, PREPRINT (Version 1) available at Research Square

Genome variation and population structure among 1,142 mosquitoes of the African malaria vector species Anopheles gambiae and Anopheles coluzzii, 9 Dec 2019

Co-authorsConsortium TAGG, Clarkson CS, Miles A, Harding NJ, Lucas ER, Battey CJ, Amaya-Romero JE, Cano J, Diabate A, Constant E, Nwakanma DC, Jawara M, Essandoh J, Dinis J, Le Goff G, Robert V, Troco AD, Costantini C, Rohatgi KR, Elissa N, Coulibaly B, Midega J, Mbogo C, Mawejje HD, Stalker J, Rockett KA, Drury E, Mead D, Jeffreys AE, Hubbart C, Rowlands K, Isaacs AT, Jyothi D, Malangone C, Kamali M, Henrichs C, Simpson V, Ayala D, Besansky NJ, Burt A, Caputo B, della Torre A, Fontaine M, Godfray HCJ, Hahn MW, Kern AD, Lawniczak MKN, O’Loughlin S, Pinto J, Riehle MM, Sharakhov I, Schrider DR, Vernick KD, White BJ, Donnelly MJ, Kwiatkowski DP. Doi: 10.1101/864314

Lovett B, Bilgo E, Diabate A, St Leger R. A review of progress toward field application of transgenic mosquitocidal entomopathogenic fungi. Sep 2019. Pest management science75 (9):2316-2324 Doi: 10.1002/PS.5385

St Leger R, Diabate A, Lovett B. Regulate GM fungi to protect ecosystems—Response.Science365,455-455(2019).DOI:10.1126/science.aay5221

Akpodiete, N.O., Diabate, A. & Tripet, F. Effect of water source and feed regime on development and phenotypic quality in Anopheles gambiae (s.l.): prospects for improved mass-rearing techniques towards release programmes. Parasites Vectors 12, 210 (2019). https://doi.org/10.1186/s13071-019-3465-0

Lovett B, Bilgo E, Millogo SA, Ouattarra AK, Sare I, Gnambani EJ, Dabire RK, Diabate A, St Leger RJ Transgenic Metarhizium rapidly kills mosquitoes in a malaria-endemic region of Burkina Faso.Science364,894-897(2019).DOI:10.1126/science.aaw8737

Epopa, P.S., Collins, C.M., North, A. et al. Seasonal malaria vector and transmission dynamics in western Burkina Faso. Malar J 18, 113 (2019). https://doi.org/10.1186/s12936-019-2747-5

Papathanos, P.A., Bourtzis, K., Tripet, F. et al. A perspective on the need and current status of efficient sex separation methods for mosquito genetic control. Parasites Vectors 11 (Suppl 2), 654 (2018). https://doi.org/10.1186/s13071-018-3222-9

Epopa, P.S., Maiga, H., Hien, D.F.d. et al. Assessment of the developmental success of Anopheles coluzzii larvae under different nutrient regimes: effects of diet quality, food amount and larval density. Malar J 17, 377 (2018). https://doi.org/10.1186/s12936-018-2530-z

Bilgo, E., Vantaux, A., Sanon, A. et al. Field assessment of potential sugar feeding stations for disseminating bacteria in a paratransgenic approach to control malaria. Malar J 17, 367 (2018). https://doi.org/10.1186/s12936-018-2516-x

Thailayil, J., Gabrieli, P., Caputo, B. et al. Analysis of natural female post-mating responses of Anopheles gambiae and Anopheles coluzzii unravels similarities and differences in their reproductive ecology. Sci Rep 8, 6594 (2018). https://doi.org/10.1038/s41598-018-24923-w

Austin Burt, Mamadou Coulibaly, Andrea Crisanti, Abdoulaye Diabate & Jonathan K. Kayondo (2018) Gene drive to reduce malaria transmission in sub-Saharan Africa, Journal of Responsible Innovation, 5:sup1, S66-S80, DOI: 10.1080/23299460.2017.1419410

Bilgo E, Lovett B, Bayili K, Millogo AS, Saré I, Dabiré RK, et al. (2018) Transgenic Metarhizium pingshaense synergistically ameliorates pyrethroid-resistance in wild-caught, malaria-vector mosquitoes. PLoS ONE 13(9): e0203529. https://doi.org/10.1371/journal.pone.0203529

Epopa, P.S., Millogo, A.A., Collins, C.M. et al. The use of sequential mark-release-recapture experiments to estimate population size, survival and dispersal of male mosquitoes of the Anopheles gambiae complex in Bana, a west African humid savannah village. Parasites Vectors 10, 376 (2017). https://doi.org/10.1186/s13071-017-2310-6

Bilgo, E., Lovett, B., Fang, W. et al. Improved efficacy of an arthropod toxin expressing fungus against insecticide-resistant malaria-vector mosquitoes. Sci Rep 7, 3433 (2017). https://doi.org/10.1038/s41598-017-03399-0

Killeen GF, Tatarsky A, Diabate A, et al. Developing an expanded vector control toolbox for malaria elimination. BMJ Global Health 2017;2:e000211. http://dx.doi.org/10.1136/bmjgh-2016-000211

Kaindoa EW, Ngowo HS, Limwagu A et al. New evidence of mating swarms of the malaria vector, Anopheles arabiensis in Tanzania [version 1; peer review: 1 approved, 2 approved with reservations]. Wellcome Open Res 2017, 2:88 (https://doi.org/10.12688/wellcomeopenres.12458.1)

Sangare I, Djibougou A, Koudraogo B, Drabo F, Diabate A, Laure Banu A, Fournet F, Price H, Tinga Guig R, Kounbobr D R. First Detection of Leishmania infantum  in Domestic Dogs from Burkina Faso (West Africa). 15 Dec 2016Research Journal of Parasitology12(1):27-32. Doi: 10.3923/JP.2017.27.32

Maïga, H., Damiens, D., Diabaté, A. et al. Large-scale Anopheles arabiensis egg quantification methods for mass-rearing operations. Malar J 15, 72 (2016). https://doi.org/10.1186/s12936-016-1119-7

Niang, A., Epopa, P.S., Sawadogo, S.P. et al. Does extreme asymmetric dominance promote hybridization between Anopheles coluzzii and Anopheles gambiae s.s. in seasonal malaria mosquito communities of West Africa?. Parasites Vectors 8, 586 (2015). https://doi.org/10.1186/s13071-015-1190-x

Nkiru E Ekechukwu and others, Heterosis Increases Fertility, Fecundity, and Survival of Laboratory-Produced F1 Hybrid Males of the Malaria Mosquito Anopheles coluzzii, G3 Genes|Genomes|Genetics, Volume 5, Issue 12, 1 December 2015, Pages 2693–2709, https://doi.org/10.1534/g3.115.021436

Mosqueira B, Soma DD, Namountougou M, Poda S, Diabaté A, Ali O, Fournet F, Baldet T, Carnevale P, Dabiré RK, Mas-Coma S. Pilot study on the combination of an organophosphate-based insecticide paint and pyrethroid-treated long lasting nets against pyrethroid resistant malaria vectors in Burkina Faso. Aug 2015 Acta tropica. Doi: 10.1016/J.ACTATROPICA.2015.04.010

Diabate, A., Tripet, F. Targeting male mosquito mating behaviour for malaria control. Parasites Vectors 8, 347 (2015). https://doi.org/10.1186/s13071-015-0961-8

Aboagye-Antwi F, Alhafez N, Weedall GD, Brothwood J, Kandola S, Paton D, Fofana A, Olohan L, Betancourth MP, Ekechukwu NE, Baeshen R, Traorè SF, Diabate A, Tripet F. Experimental swap of Anopheles gambiae's assortative mating preferences demonstrates key role of X-chromosome divergence island in incipient sympatric speciation. 16 Apr 2015PLoS genetics. Doi: 10.1371/JOURNAL.PGEN.1005141

Koama, B., Namountougou, M., Sanou, R. et al. The sterilizing effect of pyriproxyfen on the malaria vector Anopheles gambiae: physiological impact on ovaries development. Malar J 14, 101 (2015). https://doi.org/10.1186/s12936-015-0609-3

Arnal, A., Kengne, P., Brengues, C. et al. Genetic polymorphism at an odorant receptor gene (Or39) among mosquitoes of the Anopheles gambiae complex in Senegal (West Africa). BMC Res Notes 7, 321 (2014). https://doi.org/10.1186/1756-0500-7-321

Assogba BS, Djogbénou L, Saizonou J, Diabaté A, Dabiré RK, Moiroux N, Gilles JRL, Makoutodé M, Baldet T. Characterization of swarming and mating behaviour between Anopheles coluzzii and Anopheles melas in a sympatry area of Benin. Apr 2014 Acta tropica. Doi: https://doi.org/10.1016/j.actatropica.2013.09.006

Maïga H, Niang A, Sawadogo SP, Dabiré RK, Lees RS, Gilles JRL, Tripet F, Diabaté A. Role of nutritional reserves and body size in Anopheles gambiae males mating success. Apr 2014Acta tropica. 10.1016/J.ACTATROPICA.2013.08.018

More here: https://profiles.tdr-global.net/Abdoulaye.Diabate/publications?favouritesFirst=true&perPage=25&sort=dateDesc&startFrom=50