Malaria control and elimination programmes often face practical obstacles that can be tackled more effectively with information about the parasite population.

Novel laboratory methods and analytical tools make it possible to rapidly sequence and genotype Plasmodium genomes from dried blood spots (DBS) collected from malaria patients – allowing for more comprehensive coverage in malaria endemic areas.

SpotMalaria connects local and national partners creating a sampling and reporting network for collecting large numbers of dried blood spots and uses a simple standardised operating procedure (SOP) that is easy to implement in the field.

Our main goal is to provide partners with actionable information to support malaria control interventions. We use state-of-the-art genetic and genomic technologies to rapidly genotype Plasmodium falciparum samples isolated from the finger-prick blood samples.

Our SpotMalaria partners receive a Genetic Report Card for each sample that they contribute, showing whether the parasites carry mutations that make them resistant to antimalarial drugs such as artemisinin or its ACT partner drugs. This allows our partners to rapidly detect changes in drug efficacy and to respond to these changes.

Currently, we report on genetic variations that are relevant to resistance to several antimalarial drugs:

• artemisinin (kelch13, arps10, mdr2, fd, crt genes)
• piperaquine (plasmepsin2-3, exo)
• chloroquine, amodiaquine, mefloquine (crt, mdr1)
• sulfadoxine, pyrimethamine (dhfr, dhps)

In addition, we report on other genetic variations relevant to parasite epidemiology:

• Detection of additional species of Plasmodium in a P. falciparum infection, such as P. vivax, P. knowlesi, P. malariae, P. ovale
• Genetic barcodes (101 high-diversity SNPs across the genomes), used to estimate complexity of infection (COI), identify expanding strains and the geographic origins of samples.

We use a set of highly informative single nucleotide polymorphisms (SNPs) to “barcode” parasites, from which we can estimate complexity of infection. We are also able to determine if an infection comprises additional species of Plasmodium, such as P. vivax, P. malariae, P. ovale, and P. knowlesi.

The next project phase will focus on developing easy to use tools that incorporate genetic report card data in the context of the ever-growing database of genotyped malaria parasites. We are also working on methods that allow expansion of genotyping to global partner sites to speed up genotyping time. Additionally, we are working on genotyping methods for typing a similar set of informative loci in P. vivax dried blood spot samples.