Systemwide Initiative on Malaria and Agriculture

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Practical Examples

How can agriculture-based interventions help reduce malaria?

Some practical examples:

Problem: Flooding of rice fields promotes mosquito breeding.

Opportunity: Intermittent irrigation can increase rice yields and control mosquito breeding.

Problem: Cattle expand mosquito populations through provision of blood meals and creation of vector breeding habitat.

Opportunity: Cattle can be used to divert hungry mosquitoes from people (zooprophylaxis). They are also ‘dead-end’ hosts to malaria parasites.

Problem: Pesticides used in production of high-value crops induce insecticide resistance in malaria mosquitoes and can also lead to acute and chronic poisoning of people.

Opportunity: Control of crop pests using other insects (integrated pest management - IPM) can considerably reduce the need for synthetic insecticides.

Problem: Poor nutritional status contributes to low immunity against infections among children.

Opportunity: Micro-nutrients (eg. Vitamin A in varieties of sweet potato, vegetables, etc.) can enhance immunity against infections, including those due to malaria parasites.

Opportunity: Bucket-kit drip irrigation systems and treadle pumps can enhance food security and income (for purchase of nets, drugs etc.) among poor households in Africa, Asia and Latin America.

Problem: Synthetic fertilizers used for rice production cause a rapid increase in populations of important vectors of disease including malaria (Africa) and Japanese Encephalitis (India). Fertilizers can thus significantly increase transmission risks for the two diseases.

Opportunity: Rice fields with freshly applied synthetic fertilizers can enhance the biological control of mosquitoes using Bacillus thuringiensis israelensis (Bti) as follows: (1) by serving as important concentration sites for mosquito larvae compared to fields without fertilizers, (2) by improving the timing of the application of the entomo-pathogenic bacteria, since peaks of larvae appear to closely follow fertilizer application in the field. The non-persistent nature of Bti has in the past curtailed its use in Africa due to the high costs repeated applications of the bio-agent would entail. Improved timing could increase the efficiency of applying Bti, thereby reducing costs.

Contact the SIMA Web Coordinator



<< HOME >> [[ BACK ]]	*Practical Examples* *How can agriculture-based interventions help reduce malaria?* Some practical examples: Problem: Flooding of rice fields promotes mosquito breeding. Opportunity: Intermittent irrigation can increase rice yields and control mosquito breeding. Problem: Cattle expand mosquito populations through provision of blood meals and creation of vector breeding habitat. Opportunity: Cattle can be used to divert hungry mosquitoes from people (zooprophylaxis). They are also ‘dead-end’ hosts to malaria parasites. Problem: Pesticides used in production of high-value crops induce insecticide resistance in malaria mosquitoes and can also lead to acute and chronic poisoning of people. Opportunity: Control of crop pests using other insects (integrated pest management - IPM) can considerably reduce the need for synthetic insecticides. Problem: Poor nutritional status contributes to low immunity against infections among children. Opportunity: Micro-nutrients (eg. Vitamin A in varieties of sweet potato, vegetables, etc.) can enhance immunity against infections, including those due to malaria parasites. Opportunity: Bucket-kit drip irrigation systems and treadle pumps can enhance food security and income (for purchase of nets, drugs etc.) among poor households in Africa, Asia and Latin America. Problem: Synthetic fertilizers used for rice production cause a rapid increase in populations of important vectors of disease including malaria (Africa) and Japanese Encephalitis (India). Fertilizers can thus significantly increase transmission risks for the two diseases. Opportunity: Rice fields with freshly applied synthetic fertilizers can enhance the biological control of mosquitoes using Bacillus thuringiensis israelensis (Bti) as follows: (1) by serving as important concentration sites for mosquito larvae compared to fields without fertilizers, (2) by improving the timing of the application of the entomo-pathogenic bacteria, since peaks of larvae appear to closely follow fertilizer application in the field. The non-persistent nature of Bti has in the past curtailed its use in Africa due to the high costs repeated applications of the bio-agent would entail. Improved timing could increase the efficiency of applying Bti, thereby reducing costs.
	Contact the SIMA Web Coordinator