AI tool ‘98 per cent correct’ to predict mosquitoes’ age

A machine learning technique that predicts the ages of mosquitoes is a win for malaria control, say African researchers.

A female anopheles mosquito. A study says machine learning techniques to predict the age of mosquitoes from different populations could reduce turnaround time for malaria research. Credit: James Gathany, USCDCP on Pixnio, (CC0 1.0)


Using machine learning techniques to predict the age of mosquitoes from different populations could reduce turnaround time for malaria research and improve surveillance programmes, a study says.

Knowledge of a mosquito's age helps scientists to understand its potential to spread malaria but the existing tools used for foreseeing this are costly, labour-intensive and often prone to human errors, the researchers say.

According to the World Health Organization, the African region accounted for about 95 per cent of the 247 million cases of malaria globally in 2021, and scientists say the adoption of innovative tools to control mosquitoes and prevent the spread of malaria is key to eliminating the disease.

"Accurately predicting these factors can help identify high-risk populations and target interventions more effectively.”

Emmanuel Mwanga, Ifakara Health Institute

The study targeted strains of mosquitoes raised in laboratories at the Ifakara Health Institute in Tanzania and the University of Glasgow in Scotland.

Using analytical tools known as infrared spectroscopy, the researchers recorded the biochemical composition of mosquitoes, and used machine learning — a form of artificial intelligence (AI) — to train models that can predict the age of mosquitoes.

Mwanga says that machine learning is a more efficient option compared to the existing tools for predicting mosquito ages which are laborious and costly.

"There is a challenge that we have been facing in machine learning, which is the difficulty in accurately identifying the ages of mosquitoes from different locations,” says Emmanuel Mwanga, the study's lead author and a research scientist at Ifakara Health Institute. "This is the main problem that this paper is addressing.”

"It's important to test the findings on mosquitoes from different places and species,” Mwanga explains.

However, the scientists stress that further research is needed since the study looked at only one specific type of mosquito, Anopheles arabiensis, obtained from only two countries.

Findings of the study, published in BMC Bioinformatics this month (9 January), show that the machine learning models were able to improve the accuracy of the predictions for same mosquito ages to about 98 per cent.

Mwanga tells SciDev.Net that malaria interventions could be improved if malaria scientists further understand the accurate age, host preferences and species of the malaria-carrying agents.

According to the researchers, old mosquitoes are more likely to transmit malaria than young ones, but also mosquitoes that prefer to feed on humans are more likely to transmit malaria than those that prefer other animals, making studying their characteristics vital in efforts to tackle malaria.

"Accurately predicting these factors can help identify high-risk populations and target interventions more effectively,'' explains Mwanga, adding that the use of machine learning techniques could "save time and resources that can be used for other aspects of malaria control and elimination efforts”.

"This can ultimately lead to a reduction in the number of malaria cases and deaths in the region, which is an important step towards achieving zero malaria,'' he says.

According to the researchers, the findings suggest that artificial intelligence can be used to determine the age of mosquitoes from different populations.

"This could help entomologists reduce the amount of time and work required to dissect large numbers of mosquitoes,'' says the study. "Overall, these approaches have the potential to improve model-based surveillance programmes, such as assessing the impact of malaria vector control tools, by monitoring the age structures of local vector populations.”

Frank Mussa, a research and development lead at Afya Intelligence, a Tanzania-based firm focussing on use of AI in healthcare, tells SciDev.Net that the findings, if incorporated in malaria interventions, could boost planning for malaria interventions.

"[The] findings are necessary for policymakers because they will make resource allocation simpler and aid in trend prediction and assist in the development of sound strategic plans for the elimination of malaria in Tanzania," he says.

Written by

Syriacus Buguzi


This article was originally published by SciDevNet on 25 January 2023.

This piece was produced by SciDev.Net's Sub-Saharan Africa English desk.