Malaria is a mosquito-borne infectious disease in humans and other animals. There are five forms of malaria, which can cause symptoms ranging from a headache to death.
More than 1 million people, many of whom are children in Africa, die every year from the disease. Currently, there is no vaccine for malaria, though researchers around the world, including many at Notre Dame, are working on understanding the complexities and working toward vaccine development.
Also mosquito-borne, filarial worms, which reproduce and occupy the lymphatic system in humans, cause lymphatic filariasis, which can develop into elephantiasis. Early stages can go undetected for years. Once the damage to the lymphatic system is done, it cannot be reversed.
An international team of researchers from the University of Notre Dame’s Eck Institute for Global Health and Imperial College in London has recently published its work on a malaria-filaria co-transmission model, where the same mosquito transmits both diseases together.
Found in large areas of sub-Saharan Africa, one mosquito genus, Anopheles, carries both the malaria parasite Plasmodium falciparum and the microfilarial worm Wuchereria bancrofti, which causes lymphatic filariasis.
According to lead researcher Edwin Michael, professor of biological sciences specializing in epidemiology, “This has major implications for the transmission of each disease in endemic settings, and, of course, for developing better control interventions that ensure that removal of one disease does not have a profound (a worse health impact) outcome for diseases caused by the other pathogen.”
The manuscript, titled “Modelling Co-Infection with Malaria and Lymphatic Filariasis,” is being published in PLOS Computational Biology. The findings indicate that mosquito co-infection is more prevalent than expected from single prevalence, meaning two parasites facilitate each other’s invasion. Looking for ways to address co-infection is vital to addressing the considerable public health burden of these major vector-borne diseases afflicting humans today.
Since these two infections are transmitted by the same mosquito species, important questions about optimal control strategies in co-endemic regions need to be answered. The effect of the presence of each infection on the endemicity of the other leads to the need for comprehensive, reliable and dynamic pathogen co-infection modeling studies.
The Eck Institute for Global Health is a University-wide enterprise that recognizes health as a fundamental human right and endeavors to promote research, training and service to advance health standards for all people, especially people in low and middle-income countries, who are disproportionately impacted by preventable diseases.