Influence of amendment type and re-cutting on biomass production and germination capacity of Artemisia annua L. in Burkina Faso

Paper Details

Research Paper 08/12/2023
Views (457) Download (31)
current_issue_feature_image
publication_file

Influence of amendment type and re-cutting on biomass production and germination capacity of Artemisia annua L. in Burkina Faso

Adama Pascal Kihindo, Zeya Kabore, Edmond Dondasse, Badoua Badiel, Gérard Zombre
Int. J. Biosci.23( 6), 146-155, December 2023.
Certificate: IJB 2023 [Generate Certificate]

Abstract

Artemisia annua L. is a plant containing artemisinin in its leaves, recommended by the world health organization (WHO) for the treatment of malaria through Artemisinin-based Combination Therapy (ACT). This study was carried out to develop an efficient technique for producing aerial biomass and seeds with high germination capacity of the species. A factorial block design was used, with three replications and two factors, namely organic fertilizer with three modalities and the level of pruning, also with three levels. The results showed a significant difference (p<0.0001) between treatments and biomass production. Plants fertilized with compost and harvested at 20 cm from the crown produced more seed biomass and more above-ground dry biomass, with 12.690±0.66 grams per individual and 49.333±0.87 grams per individual respectively. The unfertilized, uncut control (28.086±0.64 grams) and the compost (28.255±1.47 grams) and Fertile Soil (9.689±1.12 grams) treatments cut at 10 cm from the crown did not produce good above-ground biomass. The results also showed that seeds from plants re-sowed at 10 cm from the soil and fertilized with compost germinated significantly (p<0.0001) more (79.33±1%) than non-re-seeded, non-fertilized control plants (55.33±3%). In summary, we can conclude that organic fertilization with compost and re-coring of plants at 10 cm and 20 cm from the crown respectively improved the germinative power of the seeds produced and above-ground biomass.

VIEWS 73

Ayaz S, McKenzie BA, McNeil DL, Hill GD. 2004. Light interception and utilization of four grain legumes sown at different plant populations and depths. Journal of Agricultural Sciences 142, 297-308.

Blanc B, Weniger B, Nicolas J.-P. 2008. Reflections on Artemisia annua cultivation and artemisinin production. Ethnopharmacologia 41, 82-87.

De Magalhães P, Raharinaivo J, Delabays N. 1996. Influence of nitrogen dose and type on artemisinin production in Artemisia annua L. Revue suisse Vitic. Arboric Hortic. 28 (6), 349-353.

FAO. 2012. Enriched compost for higher yields, Kenya. ID 7651.

Feodoroff A, Betremieux R. 1964. A laboratory method for determining field capacity. Sci. Sol. 2, 109-118.

Ferreira JFS, Janick J. 1996. Distribution of artemisinin in Artemisia annua” In: J. Janick (ed.), Progress in new crops, ASHS Press, Arlington, VA, 579-584.

Fertial (les fertilisants d’Algerie) et IFC. 2010. Manuel utilisation des engrais: Grandes cultures, Arboriculture, cultures maraîchères et industrielles 100p.

Fontès J, Guinko S. 1995. Carte de la végétation et de l’occupation du sol du Burkina Faso: notice explicative Ministère de la Coopérative Française. Projet 88(313), 101p.

Djego J, Gbaguidi F, Avode Ad, Aminou T. C, Napporn T.d , Moudachirou M.a , Leclercq JQ. 2014. Effects of different manures on the growth of Artemisia annua L. (Asteraceae) and quantification of its artemisinin content. Science of Life, Earth and Agronomy 2, 55-62.

Giblain C. 2006. Conférence Atelier Paludisme, Institut Pasteur de Madagascar, 29 Mars 2006; “Artemisia annua project”, Power Point presentation [http://www.pasteur.mg/Atelier-Palu/index.html]

Gingade S, Varghese ST, Manivel P. 2014. Cultivation of Artemisia (Artemisia annua Linn.). 16p.

Graham I.A, Besser K, Blumer S. 2010. La carte génétique d’Artemisia annua L. identifie les loci affectant le rendement de l’artémisinine antipaludique. Science, 327, 328-31.

Laughlin J.C, Heazlewood G.N, Beattie B.M. 2002. Cultivation of Artemisia annua L., In : Wright C.W. (ed), Artemisia, London, Ed Taylor & Francis, 159-195.

Ridley RG. 2003. To kill a parasite. Nature, 424, 887-889.

Lindquist JL, Arkebauer TJ, Walters DT, Cassman KG, Dobermann A. 2005. Maize radiation use efficiency under optimal growth conditions. Agron. J. 97, 72-78.

Mehra P, Pandey B, Melebari D, Banda J, Leftley N, Couvreur V. 2022. Hydraulic flux-responsive hormone redistribution determines root branching. Science 378, 762768.

Mounirou MM. 2022. Comparative effect of biochar, organic fertilizer and chemical fertilizer fertilization on mineral elements and onion (Allium cepa L.) production. European Scientific Journal 18(24),     47. https://doi.org/10.19044/esj.2022.v18n24p47

Nguinambaye MM, Nana R, Djinet AI, Tamini Z. 2020. Some physiological parameters and biochemical constituents of duckweed (Macrotyloma geocarpum) organs under water stress conditions. Int. J. Biol. Chem. Sci. 14(4), 1228-1240. https://doi.org/10.4314/ijbcs.v14i4.6

Norman JM, Arkebauer TJ. 1991. Predicting canopy photosynthesis and light use efficiency from leaf characteristics. In Modeling Crop Photosynthesis from Biochemistry to Canopy, KJ Boote, RS Loomis (eds). CSSA Spec. Publ. 19. CSSA: Madison, WI; 75-94.

N’Zue B, Doumbia S. 1998. Influence of taking cassava (Manihot esculenta Crantz) cuttings during vegetation on the severity of diseases and pests. Agronomie Africaine 12 (2), 60-70.

WHO. 2022. Key messages: World Malaria Report 2022. 22p.

Petit J, Jobin P. 2005. La fertilisation organique des cultures: Les bases 48p.

Sounon M, Glèlè Kakai R, Avakoudjo J, Assogbadjo AE, Sinsin B. 2009. Germination and growth tests of Artemisia annua L. anamed on different substrates in Benin. International Journal of Biological and Chemical Sciences 3, 337-346.

Van Oosterom EJ, O’Leary GJ, Carberry PS, Craufurd PQ. 2002. Simulating growth, development, and yield of till ring pearl millet. III. Biomass accumulation and partitioning. Field Crops Research 79, 85-106.

Veihmeyer F.J, Hendrickson A.H. 1931. The moisture equivalent as a measure of the field capacity of soil. Soil Science 32, 3, 181-194.

Yao FA, Millogo AA, Epopa PS. 2022. Mark-release-recapture experiment in Burkina Faso demonstrates reduced fitness and dispersal of genetically modified sterile malaria mosquitoes. Nat Commun 13, 796. https://doi.org/10.1038/s41467-022-28419-0