Abstract

BackgroundThe use of highly sensitive molecular tools in malaria diagnosis is currently largely restricted to research and epidemiological settings, but will ultimately be essential during elimination and potentially eradication. Accurate diagnosis and differentiation down to species levels, including the two Plasmodium ovale species and zoonotic variants of the disease, will be important for the understanding of changing epidemiological patterns of the disease.MethodsA qPCR-high resolution melting (HRM) method was to detect and differentiate all human Plasmodium species with one forward and one reverse primer set. The HRM detection method was further refined using a hydrolysis probe to specifically discriminate Plasmodium falciparum.ResultsOut of the 113 samples tested with the developed HRM-qPCR- P. falciparum probe assay, 96 (85.0 %) single infections, 12 (10.6 %) mixed infections, and 5 (4.4 %) were Plasmodium negative. The results were concordant with those of the nested PCR at 98.2 %. The assay limit of detection was varied from 21.47 to 46.43 copies /µl, equivalent to 1–2.11 parasites/µl. All P. falciparum infections were confirmed with the associated Taqman probe.ConclusionsAlthough the dependence on qPCR currently limits its deployment in resource-limited environments, this assay is highly sensitive and specific, easy to perform and convenient for Plasmodium mono-infection and may provide a novel tool for rapid and accurate malaria diagnosis also in epidemiological studies.

Highlights

  • The use of highly sensitive molecular tools in malaria diagnosis is currently largely restricted to research and epidemiological settings, but will be essential during elimination and potentially eradication

  • Assay design and optimization Species identification was originally performed by microscopy analysis and/ or nested Polymerase chain reaction (PCR) (Additional file 1)

  • Assay performance Isolated plasmid construct with each mitochondrial fragment of the Plasmodium species was used to determine the efficiency of the assay by amplifying 10-fold serial dilutions starting with 1­ 07 copies/μl to 10 copies/μl

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Summary

Introduction

The use of highly sensitive molecular tools in malaria diagnosis is currently largely restricted to research and epidemiological settings, but will be essential during elimination and potentially eradication. Around 84 % of imported malaria cases have been reported to be non-falciparum malaria [2] These tend to receive limited attention due to their less severe clinical course (when compared to Plasmodium falciparum); recent and increasing numbers of studies are supporting the capacity of Plasmodium vivax to cause severe disease by affecting the spleen, lungs and born marrow [3,4,5,6,7]. These findings are prompting a more thorough and comprehensive differentiation between

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