Your search keyword '"Imwong, M"' showing total 298 results

1. Molecular surveillance for operationally relevant genetic polymorphisms in Plasmodium falciparum in Southern Chad, 2016–2017

Author

Das, S, Kérah-Hinzoumbé, C, Kebféné, M, Srisutham, S, Nagorngar, T-Y, Saralamba, N, Vongpromek, R, Khomvarn, T, Sibley, CH, Guérin, PJ, Imwong, M, and Dhorda, M

Subjects

Adult, Male, Polymorphism, Genetic, Adolescent, Chad, Artemether, Lumefantrine Drug Combination, Plasmodium falciparum, Drug Resistance, Protozoan Proteins, Middle Aged, Antimalarials, Young Adult, Infectious Diseases, Child, Preschool, parasitic diseases, Humans, Female, Parasitology, Artemether, Child

Abstract

Background Resistance to anti-malarials is a serious threat to the efforts to control and eliminate malaria. Surveillance based on simple field protocols with centralized testing to detect molecular markers associated with anti-malarial drug resistance can be used to identify locations where further investigations are needed. Methods Dried blood spots were collected from 398 patients (age range 5–59 years, 99% male) with Plasmodium falciparum infections detected using rapid diagnostic tests over two rounds of sample collection conducted in 2016 and 2017 in Komé, South-West Chad. Specimens were genotyped using amplicon sequencing or qPCR for validated markers of anti-malarial resistance including partner drugs used in artemisinin-based combination therapy (ACT). Results No mutations in the pfk13 gene known to be associated with artemisinin resistance were found but a high proportion of parasites carried other mutations, specifically K189T (190/349, 54.4%, 95%CI 49.0–59.8%). Of 331 specimens successfully genotyped for pfmdr1 and pfcrt, 52% (95%CI 46.4–57.5%) carried the NFD-K haplotype, known to be associated with reduced susceptibility to lumefantrine. Only 20 of 336 (6.0%, 95%CI 3.7–9.0%) had parasites with the pfmdr1-N86Y polymorphism associated with increased treatment failures with amodiaquine. Nearly all parasites carried at least one mutation in pfdhfr and/or pfdhps genes but ‘sextuple’ mutations in pfdhfr—pfdhps including pfdhps -A581G were rare (8/336 overall, 2.4%, 95%CI 1.2–4.6%). Only one specimen containing parasites with pfmdr1 gene amplification was detected. Conclusions These results provide information on the likely high efficacy of artemisinin-based combinations commonly used in Chad, but suggest decreasing levels of sensitivity to lumefantrine and high levels of resistance to sulfadoxine-pyrimethamine used for seasonal malaria chemoprevention and intermittent preventive therapy in pregnancy. A majority of parasites had mutations in the pfk13 gene, none of which are known to be associated with artemisinin resistance. A therapeutic efficacy study needs to be conducted to confirm the efficacy of artemether-lumefantrine.

Published

2023

2. Drug resistance of Plasmodium falciparum and Plasmodium vivax isolates in Indonesia

Author

Rahmasari, FV, Asih, PBS, Dewayanti, FK, Rotejanaprasert, C, Charunwatthana, P, Imwong, M, and Syafruddin, D

Subjects

Antimalarials, Infectious Diseases, Indonesia, Plasmodium falciparum, Drug Resistance, Parasitology, Plasmodium vivax, Polymorphism, Single Nucleotide, Artemisinins

Abstract

This review article aims to investigate the genotypic profiles of Plasmodium falciparum and Plasmodium vivax isolates collected across a wide geographic region and their association with resistance to anti-malarial drugs used in Indonesia. A systematic review was conducted between 1991 and date. Search engines, such as PubMed, Science Direct, and Google Scholar, were used for articles published in English and Indonesian to search the literature. Of the 471 initially identified studies, 61 were selected for 4316 P. falciparum and 1950 P. vivax individual infections. The studies included 23 molecular studies and 38 therapeutic efficacy studies. K76T was the most common pfcrt mutation. K76N (2.1%) was associated with the haplotype CVMNN. By following dihydroartemisinin–piperaquine (DHA–PPQ) therapy, the mutant pfmdr1 alleles 86Y and 1034C were selected. Low prevalence of haplotype N86Y/Y184/D1246Ypfmdr1 reduces susceptibility to AS–AQ. SNP mutation pvmdr1 Y976F reached 96.1% in Papua and East Nusa Tenggara. Polymorphism analysis in the pfdhfr gene revealed 94/111 (84.7%) double mutants S108N/C59R or S108T/A16V in Central Java. The predominant pfdhfr haplotypes (based on alleles 16, 51, 59,108, 164) found in Indonesia were ANCNI, ANCSI, ANRNI, and ANRNL. Some isolates carried A437G (35.3%) or A437G/K540E SNPs (26.5%) in pfdhps. Two novel pfdhps mutant alleles, I588F/G and K540T, were associated with six pfdhps haplotypes. The highest prevalence of pvdhfr quadruple mutation (F57L/S58R/T61M/S117T) (61.8%) was detected in Papua. In pvdhps, the only polymorphism before and after 2008 was 383G mutation with 19% prevalence. There were no mutations in the pfk13 gene reported with validated and candidate or associated k13 mutation. An increased copy number of pfpm2, associated with piperaquine resistance, was found only in cases of reinfection. Meanwhile, mutation of pvk12 and pvpm4 I165V is unlikely associated with ART and PPQ drug resistance. DHA–PPQ is still effective in treating uncomplicated falciparum and vivax malaria. Serious consideration should be given to interrupt local malaria transmission and dynamic patterns of resistance to anti-malarial drugs to modify chemotherapeutic policy treatment strategies. The presence of several changes in pfk13 in the parasite population is of concern and highlights the importance of further evaluation of parasitic ART susceptibility in Indonesia. Graphical Abstract

Published

2023

3. Pharmacometrics of high dose ivermectin in early COVID-19: an open label, randomized, controlled adaptive platform trial (PLATCOV)

Author

Schilling, WHK, Jittamala, P, Watson, JA, Ekkapongpisit, M, Siripoon, T, Ngamprasertchai, T, Luvira, V, Pongwilai, S, Cruz, CV, Callery, JJ, Boyd, S, Kruabkontho, V, Ngernseng, T, Tubprasert, J, Abdad, MY, Piaraksa, N, Suwannasin, K, Hanboonkunupakarn, P, Hanboonkunupakarn, B, Sookprome, S, Poovorawan, K, Thaipadungpanit, J, Blacksell, S, Imwong, M, Tarning, J, Taylor, WRJ, Chotivanich, V, Sangketchon, C, Ruksakul, W, Chotivanich, K, Teixeira, MM, Pukrittayakamee, S, Dondorp, AM, Day, NPJ, Piyaphanee, W, Phumratanaprapin, W, White, NJ, and Group, PLATCOV Collaborative

Subjects

General Immunology and Microbiology, General Neuroscience, General Medicine, General Biochemistry, Genetics and Molecular Biology

Abstract

Background:There is no generally accepted methodology for in vivo assessment of antiviral activity in SARS-CoV-2 infections. Ivermectin has been recommended widely as a treatment of COVID-19, but whether it has clinically significant antiviral activity in vivo is uncertain.Methods:In a multicentre open label, randomized, controlled adaptive platform trial, adult patients with early symptomatic COVID-19 were randomized to one of six treatment arms including high-dose oral ivermectin (600 µg/kg daily for 7 days), the monoclonal antibodies casirivimab and imdevimab (600 mg/600 mg), and no study drug. The primary outcome was the comparison of viral clearance rates in the modified intention-to-treat population. This was derived from daily log10 viral densities in standardized duplicate oropharyngeal swab eluates. This ongoing trial is registered at https://clinicaltrials.gov/ (NCT05041907).Results:Randomization to the ivermectin arm was stopped after enrolling 205 patients into all arms, as the prespecified futility threshold was reached. Following ivermectin, the mean estimated rate of SARS-CoV-2 viral clearance was 9.1% slower (95% confidence interval [CI] –27.2% to +11.8%; n=45) than in the no drug arm (n=41), whereas in a preliminary analysis of the casirivimab/imdevimab arm it was 52.3% faster (95% CI +7.0% to +115.1%; n=10 (Delta variant) vs. n=41).Conclusions:High-dose ivermectin did not have measurable antiviral activity in early symptomatic COVID-19. Pharmacometric evaluation of viral clearance rate from frequent serial oropharyngeal qPCR viral density estimates is a highly efficient and well-tolerated method of assessing SARS-CoV-2 antiviral therapeutics in vitro.Funding:‘Finding treatments for COVID-19: A phase 2 multi-centre adaptive platform trial to assess antiviral pharmacodynamics in early symptomatic COVID-19 (PLAT-COV)’ is supported by the Wellcome Trust Grant ref: 223195/Z/21/Z through the COVID-19 Therapeutics Accelerator.Clinical trial number:NCT05041907.

Published

2023

4. Pf7: an open dataset of Plasmodium falciparum genome variation in 20,000 worldwide samples

Author

Hamid, M.M.A., Abdelraheem, M.H., Acheampong, D.O., Ahouidi, A., Ali, M, Almagro-Garcia, J., Amambua-Ngwa, A., Amaratunga, C., Amenga-Etego, L., Andagalu, B., Anderson, T., Andrianaranjaka, V., Aniebo, I., Aninagyei, E., Ansah, F., Ansah, P.O., Apinjoh, T., Arnaldo, P., Ashley, E., Auburn, S., Awandare, G.A., Ba, H., Baraka, V., Barry, A., Bejon, P., Bertin, G.I., Boni, M.F., Borrmann, S., Bousema, T., Bouyou-Akotet, M., Branch, O., Bull, P.C., Cheah, H., Chindavongsa, K., Chookajorn, T., Chotivanich, K., Claessens, A., Conway, D.J., Corredor, V., Courtier, E., Craig, A., D'Alessandro, U., Dama, S., Day, N., Denis, B., Dhorda, M., Diakite, M., Djimde, A., Dolecek, C., Dondorp, A., Doumbia, S., Drakeley, C., Drury, E., Duffy, P., Echeverry, D.F., Egwang, T.G., Enosse, S.M.M., Erko, B., Fairhurst, R.M., Faiz, A., Fanello, C.A., Fleharty, M., Forbes, M., Fukuda, M., Gamboa, D., Ghansah, A., Golassa, L., Goncalves, S., Harrison, G.L.A., Healy, Sara A., Hendry, J.A., Hernandez-Koutoucheva, A., Hien, T.T., Hill, C.A., Hombhanje, F., Hott, A., Htut, Y., Hussein, M., Imwong, M., Ishengoma, D., Jackson, S.A., Jacob, C.G., Jeans, J., Johnson, K.J., Kamaliddin, C., Kamau, E., Keatley, J., Kochakarn, T., Konate, D.S., Konaté, A., Kone, A., Kwiatkowski, D.P., Kyaw, M.P., Kyle, D., Lawniczak, M., Lee, S.K., Lemnge, M., Lim, P., Lon, C., Yavo, W., Pluijm, R.W. van der, Hamid, M.M.A., Abdelraheem, M.H., Acheampong, D.O., Ahouidi, A., Ali, M, Almagro-Garcia, J., Amambua-Ngwa, A., Amaratunga, C., Amenga-Etego, L., Andagalu, B., Anderson, T., Andrianaranjaka, V., Aniebo, I., Aninagyei, E., Ansah, F., Ansah, P.O., Apinjoh, T., Arnaldo, P., Ashley, E., Auburn, S., Awandare, G.A., Ba, H., Baraka, V., Barry, A., Bejon, P., Bertin, G.I., Boni, M.F., Borrmann, S., Bousema, T., Bouyou-Akotet, M., Branch, O., Bull, P.C., Cheah, H., Chindavongsa, K., Chookajorn, T., Chotivanich, K., Claessens, A., Conway, D.J., Corredor, V., Courtier, E., Craig, A., D'Alessandro, U., Dama, S., Day, N., Denis, B., Dhorda, M., Diakite, M., Djimde, A., Dolecek, C., Dondorp, A., Doumbia, S., Drakeley, C., Drury, E., Duffy, P., Echeverry, D.F., Egwang, T.G., Enosse, S.M.M., Erko, B., Fairhurst, R.M., Faiz, A., Fanello, C.A., Fleharty, M., Forbes, M., Fukuda, M., Gamboa, D., Ghansah, A., Golassa, L., Goncalves, S., Harrison, G.L.A., Healy, Sara A., Hendry, J.A., Hernandez-Koutoucheva, A., Hien, T.T., Hill, C.A., Hombhanje, F., Hott, A., Htut, Y., Hussein, M., Imwong, M., Ishengoma, D., Jackson, S.A., Jacob, C.G., Jeans, J., Johnson, K.J., Kamaliddin, C., Kamau, E., Keatley, J., Kochakarn, T., Konate, D.S., Konaté, A., Kone, A., Kwiatkowski, D.P., Kyaw, M.P., Kyle, D., Lawniczak, M., Lee, S.K., Lemnge, M., Lim, P., Lon, C., Yavo, W., and Pluijm, R.W. van der

Abstract

Item does not contain fulltext, We describe the MalariaGEN Pf7 data resource, the seventh release of Plasmodium falciparum genome variation data from the MalariaGEN network. It comprises over 20,000 samples from 82 partner studies in 33 countries, including several malaria endemic regions that were previously underrepresented. For the first time we include dried blood spot samples that were sequenced after selective whole genome amplification, necessitating new methods to genotype copy number variations. We identify a large number of newly emerging crt mutations in parts of Southeast Asia, and show examples of heterogeneities in patterns of drug resistance within Africa and within the Indian subcontinent. We describe the profile of variations in the C-terminal of the csp gene and relate this to the sequence used in the RTS,S and R21 malaria vaccines. Pf7 provides high-quality data on genotype calls for 6 million SNPs and short indels, analysis of large deletions that cause failure of rapid diagnostic tests, and systematic characterisation of six major drug resistance loci, all of which can be freely downloaded from the MalariaGEN website.

Published

2023

5. Comparative analysis of targeted next-generation sequencing for Plasmodium falciparum drug resistance markers

Author

Kunasol, C, Dondorp, AM, Batty, EM, Nakhonsri, V, Sinjanakhom, P, Day, NPJ, Imwong, M, and Intensive Care Medicine

Subjects

Multidisciplinary, Molecular medicine, Biological techniques, Plasmodium falciparum, parasitic diseases, Drug Resistance, High-Throughput Nucleotide Sequencing, Humans, Malaria, Falciparum, Thailand

Abstract

Well-defined molecular resistance markers are available for a range of antimalarial drugs, and molecular surveillance is increasingly important for monitoring antimalarial drug resistance. Different genotyping platforms are available, but these have not been compared in detail. We compared Targeted Amplicon Deep sequencing (TADs) using Ion Torrent PGM with Illumina MiSeq for the typing of antimalarial drug resistance genes. We developed and validated protocols to type the molecular resistance markers pfcrt, pfdhfr, pfdhps, pfmdr1, pfkelch, and pfcytochrome b, in Plasmodium falciparum for the Ion Torrent PGM and Illumina MiSeq sequencing platforms. With P. falciparum 3D7 and K1 as reference strains, whole blood samples (N = 20) and blood spots from Rapid Diagnostic Test (RDT) samples (N = 5) from patients with uncomplicated falciparum malaria from Ubon Ratchathani were assessed on both platforms and compared for coverage (average reads per amplicon), sequencing accuracy, variant accuracy, false positive rate, false negative rate, and alternative allele detection, with conventional Sanger sequencing as the reference method for SNP calling. Both whole blood and RDT samples could be successfully sequenced using the Ion Torrent PGM and Illumina MiSeq platforms. Coverage of reads per amplicon was higher with Illumina MiSeq (28,886 reads) than with Ion Torrent PGM (1754 reads). In laboratory generated artificial mixed infections, the two platforms could detect the minor allele down to 1% density at 500X coverage. SNPs calls from both platforms were in complete agreement with conventional Sanger sequencing. The methods can be multiplexed with up to 96 samples per run, which reduces cost by 86% compared to conventional Sanger sequencing. Both platforms, using the developed TAD protocols, provide an accurate method for molecular surveillance of drug resistance markers in P. falciparum, but Illumina MiSeq provides higher coverage than Ion Torrent PGM.

Published

2022

6. Artemisinin resistance in the malaria parasite, Plasmodium falciparum, originates from its initial transcriptional response

Author

Zhu, L, van der Pluijm, RW, Kucharski, M, Nayak, S, Tripathi, J, White, NJ, Day, NPJ, Faiz, A, Phyo, AP, Amaratunga, C, Lek, D, Ashley, EA, Nosten, F, Smithuis, F, Ginsburg, H, von Seidlein, L, Lin, K, Imwong, M, Chotivanich, K, Mayxay, M, Dhorda, M, Nguyen, HC, Nguyen, TNT, Miotto, O, Newton, PN, Jittamala, P, Tripura, R, Pukrittayakamee, S, Peto, TJ, Hien, TT, Dondorp, AM, Bozdech, Z, Graduate School, Radiology and Nuclear Medicine, Intensive Care Medicine, AII - Infectious diseases, and School of Biological Sciences

Subjects

Antimalarials, Antimalarial Agent, parasitic diseases, Plasmodium falciparum, Drug Resistance, Medicine (miscellaneous), Animals, Biological sciences [Science], Parasites, Malaria, Falciparum, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology, Artemisinins

Abstract

The emergence and spread of artemisinin-resistant Plasmodium falciparum, first in the Greater Mekong Subregion (GMS), and now in East Africa, is a major threat to global malaria elimination ambitions. To investigate the artemisinin resistance mechanism, transcriptome analysis was conducted of 577 P. falciparum isolates collected in the GMS between 2016-2018. A specific artemisinin resistance-associated transcriptional profile was identified that involves a broad but discrete set of biological functions related to proteotoxic stress, host cytoplasm remodelling, and REDOX metabolism. The artemisinin resistance-associated transcriptional profile evolved from initial transcriptional responses of susceptible parasites to artemisinin. The genetic basis for this adapted response is likely to be complex. Ministry of Education (MOE) National Medical Research Council (NMRC) Published version This research was funded by Singapore National Medical Research Council grant #NMRC/OFIRG/0040/2017 and Singapore Ministry of education grant #MOE2019-T3-1-007 and #MOE2017-T2-2-030 (S) awarded to Z. Bozdech. Moreover, A.D. coordinated funding for the TRACII epidemiology studies funded by DFID (FCDO): Artemisinin Resistant Malaria Research Programme (TRAC). DFID PO 5408 and Wellcome Trust: MOP Thailand Core award 220211/Z/20/Z and 220211/A/20/Z.

Published

2022

7. Comparison of Antibody Responses and Parasite Clearance in Artemisinin Therapeutic Efficacy Studies in the Democratic Republic of Congo and Asia

Author

Cutts, JC, O'Flaherty, K, Zaloumis, SG, Ashley, EA, Chan, JA, Onyamboko, MA, Fanello, C, Dondorp, AM, Day, NP, Phyo, AP, Dhorda, M, Imwong, M, Fairhurst, RM, Lim, P, Amaratunga, C, Pukrittayakamee, S, Hien, TT, Htut, Y, Mayxay, M, Faiz, MA, Takashima, E, Tsuboi, T, Beeson, JG, Nosten, F, Simpson, JA, White, NJ, Fowkes, FJ, Cutts, JC, O'Flaherty, K, Zaloumis, SG, Ashley, EA, Chan, JA, Onyamboko, MA, Fanello, C, Dondorp, AM, Day, NP, Phyo, AP, Dhorda, M, Imwong, M, Fairhurst, RM, Lim, P, Amaratunga, C, Pukrittayakamee, S, Hien, TT, Htut, Y, Mayxay, M, Faiz, MA, Takashima, E, Tsuboi, T, Beeson, JG, Nosten, F, Simpson, JA, White, NJ, and Fowkes, FJ

Abstract

BACKGROUND: Understanding the effect of immunity on Plasmodium falciparum clearance is essential for interpreting therapeutic efficacy studies designed to monitor emergence of artemisinin drug resistance. In low-transmission areas of Southeast Asia, where resistance has emerged, P. falciparum antibodies confound parasite clearance measures. However, variation in naturally acquired antibodies across Asian and sub-Saharan African epidemiological contexts and their impact on parasite clearance re yet to be quantified. METHODS: In an artemisinin therapeutic efficacy study, antibodies to 12 pre-erythrocytic and erythrocytic P. falciparum antigens were measured in 118 children with uncomplicated P. falciparum malaria in the Democratic Republic of Congo (DRC) and compared with responses in patients from Asian sites, described elsewhere. RESULTS: Parasite clearance half-life was shorter in DRC patients (median, 2 hours) compared with most Asian sites (median, 2-7 hours), but P. falciparum antibody levels and seroprevalences were similar. There was no evidence for an association between antibody seropositivity and parasite clearance half-life (mean difference between seronegative and seropositive, -0.14 to +0.40 hour) in DRC patients. CONCLUSIONS: In DRC, where artemisinin remains highly effective, the substantially shorter parasite clearance time compared with Asia was not explained by differences in the P. falciparum antibody responses studied.

Published

2022

8. An open dataset of Plasmodium falciparum genome variation in 7,000 worldwide samples

Author

Ahouidi, A., Ali, M, Almagro-Garcia, J., Amambua-Ngwa, A., Amaratunga, C., Amato, R., Amenga-Etego, L., Andagalu, B., Anderson, T.J., Andrianaranjaka, V., Apinjoh, T., Ariani, C., Ashley, E.A., Auburn, S., Awandare, G.A., Ba, H., Baraka, V., Barry, A.E., Bejon, P., Bertin, G.I., Boni, M.F., Borrmann, S., Bousema, T., Branch, O., Bull, P.C., Busby, G.B.J., Chookajorn, T., Chotivanich, K., Claessens, A., Conway, D., Craig, A., D'Alessandro, U., Dama, S., Day, N.P., Denis, B., Diakite, M., Djimdé, A., Dolecek, C., Dondorp, A.M., Drakeley, C., Drury, E., Duffy, P., Echeverry, D.F., Egwang, T.G., Erko, B., Fairhurst, R.M., Faiz, A., Fanello, C.A., Fukuda, M.M., Gamboa, D., Ghansah, A., Golassa, L., Goncalves, S., Hamilton, W.L., Harrison, G.L.A., Hart, L. 't, Henrichs, C., Hien, T.T., Hill, C.A., Hodgson, A., Hubbart, C., Imwong, M., Ishengoma, D.S., Jackson, S.A., Jacob, C.G., Jeffery, B., Jeffreys, A.E., Johnson, K.J., Jyothi, D., Kamaliddin, C., Kamau, E., Kekre, M., Kluczynski, K., Kochakarn, T., Konaté, A., Kwiatkowski, D.P., Kyaw, M.P., Lim, P., Lon, C., Loua, K.M., Maïga-Ascofaré, O., Malangone, C., Manske, M., Marfurt, J., Marsh, K., Mayxay, M., Miles, A., Miotto, O., Mobegi, V., Mokuolu, O.A., Montgomery, J., Mueller, I., Newton, P.N., Nguyen, T., Nguyen, T.N.D., Noedl, H., Nosten, F., Noviyanti, R., Nzila, A., Ochola-Oyier, L.I., and MalariaGEN

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, lnfectious Diseases and Global Health Radboud Institute for Health Sciences [Radboudumc 4], 030231 tropical medicine, parasitic diseases, Medicine (miscellaneous), General Biochemistry, Genetics and Molecular Biology, 3. Good health

Abstract

Contains fulltext : 238195.pdf (Publisher’s version ) (Open Access) MalariaGEN is a data-sharing network that enables groups around the world to work together on the genomic epidemiology of malaria. Here we describe a new release of curated genome variation data on 7,000 Plasmodium falciparum samples from MalariaGEN partner studies in 28 malaria-endemic countries. High-quality genotype calls on 3 million single nucleotide polymorphisms (SNPs) and short indels were produced using a standardised analysis pipeline. Copy number variants associated with drug resistance and structural variants that cause failure of rapid diagnostic tests were also analysed. Almost all samples showed genetic evidence of resistance to at least one antimalarial drug, and some samples from Southeast Asia carried markers of resistance to six commonly-used drugs. Genes expressed during the mosquito stage of the parasite life-cycle are prominent among loci that show strong geographic differentiation. By continuing to enlarge this open data resource we aim to facilitate research into the evolutionary processes affecting malaria control and to accelerate development of the surveillance toolkit required for malaria elimination.

Published

2021

9. An open dataset of Plasmodium falciparum genome variation in 7,000 worldwide samples.

Author

MalariaGEN, Ahouidi, A, Ali, M, Almagro-Garcia, J, Amambua-Ngwa, A, Amaratunga, C, Amato, R, Amenga-Etego, L, Andagalu, B, Anderson, TJC, Andrianaranjaka, V, Apinjoh, T, Ariani, C, Ashley, EA, Auburn, S, Awandare, GA, Ba, H, Baraka, V, Barry, Alyssa, Bejon, P, Bertin, GI, Boni, MF, Borrmann, S, Bousema, T, Branch, O, Bull, PC, Busby, GBJ, Chookajorn, T, Chotivanich, K, Claessens, A, Conway, D, Craig, A, D'Alessandro, U, Dama, S, Day, NP, Denis, B, Diakite, M, Djimdé, A, Dolecek, C, Dondorp, AM, Drakeley, C, Drury, E, Duffy, P, Echeverry, DF, Egwang, TG, Erko, B, Fairhurst, RM, Faiz, A, Fanello, CA, Fukuda, MM, Gamboa, D, Ghansah, A, Golassa, L, Goncalves, S, Hamilton, WL, Harrison, GLA, Hart, L, Henrichs, C, Hien, TT, Hill, CA, Hodgson, A, Hubbart, C, Imwong, M, Ishengoma, DS, Jackson, SA, Jacob, CG, Jeffery, B, Jeffreys, AE, Johnson, KJ, Jyothi, D, Kamaliddin, C, Kamau, E, Kekre, M, Kluczynski, K, Kochakarn, T, Konaté, A, Kwiatkowski, DP, Kyaw, MP, Lim, P, Lon, C, Loua, KM, Maïga-Ascofaré, O, Malangone, C, Manske, M, Marfurt, J, Marsh, K, Mayxay, M, Miles, A, Miotto, O, Mobegi, V, Mokuolu, OA, Montgomery, J, Mueller, I, Newton, PN, Nguyen, T, Nguyen, T-N, Noedl, H, Nosten, F, Noviyanti, R, Nzila, A, Ochola-Oyier, LI, Ocholla, H, Oduro, A, Omedo, I, Onyamboko, MA, Ouedraogo, J-B, Oyebola, K, Pearson, RD, Peshu, N, Phyo, AP, Plowe, CV, Price, RN, Pukrittayakamee, S, Randrianarivelojosia, M, Rayner, JC, Ringwald, P, Rockett, KA, Rowlands, K, Ruiz, L, Saunders, D, Shayo, A, Siba, P, Simpson, VJ, Stalker, J, Su, X-Z, Sutherland, C, Takala-Harrison, S, Tavul, L, Thathy, V, Tshefu, A, Verra, F, Vinetz, J, Wellems, TE, Wendler, J, White, NJ, Wright, I, Yavo, W, Ye, H, MalariaGEN, Ahouidi, A, Ali, M, Almagro-Garcia, J, Amambua-Ngwa, A, Amaratunga, C, Amato, R, Amenga-Etego, L, Andagalu, B, Anderson, TJC, Andrianaranjaka, V, Apinjoh, T, Ariani, C, Ashley, EA, Auburn, S, Awandare, GA, Ba, H, Baraka, V, Barry, Alyssa, Bejon, P, Bertin, GI, Boni, MF, Borrmann, S, Bousema, T, Branch, O, Bull, PC, Busby, GBJ, Chookajorn, T, Chotivanich, K, Claessens, A, Conway, D, Craig, A, D'Alessandro, U, Dama, S, Day, NP, Denis, B, Diakite, M, Djimdé, A, Dolecek, C, Dondorp, AM, Drakeley, C, Drury, E, Duffy, P, Echeverry, DF, Egwang, TG, Erko, B, Fairhurst, RM, Faiz, A, Fanello, CA, Fukuda, MM, Gamboa, D, Ghansah, A, Golassa, L, Goncalves, S, Hamilton, WL, Harrison, GLA, Hart, L, Henrichs, C, Hien, TT, Hill, CA, Hodgson, A, Hubbart, C, Imwong, M, Ishengoma, DS, Jackson, SA, Jacob, CG, Jeffery, B, Jeffreys, AE, Johnson, KJ, Jyothi, D, Kamaliddin, C, Kamau, E, Kekre, M, Kluczynski, K, Kochakarn, T, Konaté, A, Kwiatkowski, DP, Kyaw, MP, Lim, P, Lon, C, Loua, KM, Maïga-Ascofaré, O, Malangone, C, Manske, M, Marfurt, J, Marsh, K, Mayxay, M, Miles, A, Miotto, O, Mobegi, V, Mokuolu, OA, Montgomery, J, Mueller, I, Newton, PN, Nguyen, T, Nguyen, T-N, Noedl, H, Nosten, F, Noviyanti, R, Nzila, A, Ochola-Oyier, LI, Ocholla, H, Oduro, A, Omedo, I, Onyamboko, MA, Ouedraogo, J-B, Oyebola, K, Pearson, RD, Peshu, N, Phyo, AP, Plowe, CV, Price, RN, Pukrittayakamee, S, Randrianarivelojosia, M, Rayner, JC, Ringwald, P, Rockett, KA, Rowlands, K, Ruiz, L, Saunders, D, Shayo, A, Siba, P, Simpson, VJ, Stalker, J, Su, X-Z, Sutherland, C, Takala-Harrison, S, Tavul, L, Thathy, V, Tshefu, A, Verra, F, Vinetz, J, Wellems, TE, Wendler, J, White, NJ, Wright, I, Yavo, W, and Ye, H

Abstract

MalariaGEN is a data-sharing network that enables groups around the world to work together on the genomic epidemiology of malaria. Here we describe a new release of curated genome variation data on 7,000 Plasmodium falciparum samples from MalariaGEN partner studies in 28 malaria-endemic countries. High-quality genotype calls on 3 million single nucleotide polymorphisms (SNPs) and short indels were produced using a standardised analysis pipeline. Copy number variants associated with drug resistance and structural variants that cause failure of rapid diagnostic tests were also analysed.  Almost all samples showed genetic evidence of resistance to at least one antimalarial drug, and some samples from Southeast Asia carried markers of resistance to six commonly-used drugs. Genes expressed during the mosquito stage of the parasite life-cycle are prominent among loci that show strong geographic differentiation. By continuing to enlarge this open data resource we aim to facilitate research into the evolutionary processes affecting malaria control and to accelerate development of the surveillance toolkit required for malaria elimination.

Published

2021

10. Strong protective effect of Mediterranean type glucose-6-phosphate dehydrogenase deficiency against vivax malaria

Author

Awab, GR, Aaram, F, Jamornthanyawat, N, Suwannasin, K, Pagornrat, W, Watson, JA, Woodrow, CJ, Dondorp, A, Day, NP, Imwong, M, and White, N

Published

2020

11. The dynamic of asymptomatic Plasmodium falciparum infections following mass drug administrations with dihydroarteminisin–piperaquine plus a single low dose of primaquine in Savannakhet Province, Laos

Author

Pongvongsa, T, Phommasone, K, Adhikari, B, Henriques, G, Chotivanich, K, Hanboonkunupakarn, B, Mukaka, M, Peerawaranun, P, Von Seidlein, L, Day, N, White, N, Dondorp, A, Imwong, M, Newton, P, Singhasivanon, P, Mayxay, M, Pukrittayakamee, S, Graduate School, AII - Infectious diseases, APH - Global Health, and APH - Methodology

Subjects

Adult, Male, lcsh:Arctic medicine. Tropical medicine, Adolescent, Elimination, lcsh:RC955-962, MDA, Plasmodium falciparum, P. falciparum, lcsh:Infectious and parasitic diseases, Antimalarials, Young Adult, parasitic diseases, Prevalence, Humans, lcsh:RC109-216, Malaria, Falciparum, Child, Asymptomatic Infections, Research, Incidence, Asymptomatic parasitaemia, Middle Aged, Artemisinins, Drug Combinations, Savannakhet, Laos, Quinolines, Mass Drug Administration, Female

Abstract

Background The increase in multidrug resistant Plasmodium falciparum infections threatens the malaria elimination goals in countries within the Greater Mekong Sub-region. A multi-pronged approach assuring access to basic malaria control measures, including insecticide-treated bed nets and early diagnosis and treatment was followed by mass drug administrations (MDA) in southern Savannakhet Province, Laos. The main objective of this study was to evaluate the effectiveness and safety of mass drug administrations as well as their effects on the dynamic of asymptomatic P. falciparum infections in 4 malaria endemic villages. Methods Two villages were randomized to early MDA consisting of 3 rounds of a 3-day course of dihydroartemisinin–piperaquine with a single low dose of primaquine. In the other 2 villages MDA was deferred by 1 year. A total of 1036 residents were enrolled in early MDA villages and 883 in control villages (deferred-MDA). Tri-monthly parasitaemia surveys using uPCR were conducted for a year in the 4 villages. Results Eighty-four percent (872/1036) of the residents participated in the MDAs, of whom 90% (781/872) completed 3 rounds of MDA (9 doses). In intervention villages, the prevalence of asymptomatic P. falciparum infections decreased by 85% after MDA from 4.8% (95% CI 3.4–6.4) at baseline (month 0 or M0) to 0.7% (95% CI 0.3–1.6) at month 12. In control villages there was a decrease of 33% in P. falciparum prevalence between M0: 17.5% (95% CI 15.9–20.3) and M12: 11.6% (95% CI 9.3–14.2). In bivariate and multivariate analyses P. falciparum infections were significantly reduced with early MDA (adjusted incidence rate ratios (AIRR): 0.08, CI 0.01–0.091) and completion of 3 MDA rounds (AIRR: 0.06; CI 0.01–0.66). A quarter of participants (226/872) reported adverse events of which 99% were mild. Conclusion The study found a significant reduction in P. falciparum prevalence and incidence following MDA. MDA was safe, well tolerated, feasible, and achieved high population coverage and adherence. MDAs must be integrated in multi-pronged approaches such as vector control and preventive measures with a focus on specific risk groups such as mobile, migrant population and forest goers for a sustained period to eliminate the remaining parasite reservoirs. Trial registration ClinicalTrials.gov Identifier: NCT01872702

Published

2018

12. Determinants of dihydroartemisinin-piperaquine treatment failure in Plasmodium falciparum malaria in Cambodia, Thailand, and Vietnam: a prospective clinical, pharmacological, and genetic study

Author

van Der Pluijm, R, Imwong, M, Chau, N, Hoa, N, Thuy-Nhien, N, Thanh, N, Jittamala, P, Hanboonkunupakarn, B, Chutasmit, K, Saelow, C, Runjarern, R, Kaewmok, W, Tripura, R, Peto, T, Yok, S, Suon, S, Sreng, S, Mao, S, Oun, S, Yen, S, Amaratunga, C, Lek, D, Huy, R, Dhorda, M, Chotivanich, K, Ashley, E, Mukaka, M, Waithira, N, Cheah, P, Maude, R, Amato, R, Pearson, R, Gonçalves, S, Jacob, C, Hamilton, W, Fairhurst, R, Tarning, J, Winterberg, M, Kwiatkowski, D, Pukrittayakamee, S, Hien, T, Day, N, Miotto, O, White, N, and Dondorp, A

Subjects

Adult, Male, Adolescent, Plasmodium falciparum, Protozoan Proteins, High-Throughput Nucleotide Sequencing, Membrane Transport Proteins, Middle Aged, Thailand, Artemisinins, Drug Resistance, Multiple, Mefloquine, Antimalarials, Young Adult, Vietnam, Mutation, Quinolines, Humans, Drug Therapy, Combination, Female, Prospective Studies, Treatment Failure, Malaria, Falciparum, Cambodia

Abstract

The emergence and spread of resistance in Plasmodium falciparum malaria to artemisinin combination therapies in the Greater Mekong subregion poses a major threat to malaria control and elimination. The current study is part of a multi-country, open-label, randomised clinical trial (TRACII, 2015-18) evaluating the efficacy, safety, and tolerability of triple artemisinin combination therapies. A very high rate of treatment failure after treatment with dihydroartemisinin-piperaquine was observed in Thailand, Cambodia, and Vietnam. The immediate public health importance of our findings prompted us to report the efficacy data on dihydroartemisinin-piperaquine and its determinants ahead of the results of the overall trial, which will be published later this year.Patients aged between 2 and 65 years presenting with uncomplicated P falciparum or mixed species malaria at seven sites in Thailand, Cambodia, and Vietnam were randomly assigned to receive dihydroartemisinin-piperaquine with or without mefloquine, as part of the TRACII trial. The primary outcome was the PCR-corrected efficacy at day 42. Next-generation sequencing was used to assess the prevalence of molecular markers associated with artemisinin resistance (kelch13 mutations, in particular Cys580Tyr) and piperaquine resistance (plasmepsin-2 and plasmepsin-3 amplifications and crt mutations). This study is registered with ClinicalTrials.gov, number NCT02453308.Between Sept 28, 2015, and Jan 18, 2018, 539 patients with acute P falciparum malaria were screened for eligibility, 292 were enrolled, and 140 received dihydroartemisinin-piperaquine. The overall Kaplan-Meier estimate of PCR-corrected efficacy of dihydroartemisinin-piperaquine at day 42 was 50·0% (95% CI 41·1-58·3). PCR-corrected efficacies for individual sites were 12·7% (2·2-33·0) in northeastern Thailand, 38·2% (15·9-60·5) in western Cambodia, 73·4% (57·0-84·3) in Ratanakiri (northeastern Cambodia), and 47·1% (33·5-59·6) in Binh Phuoc (southwestern Vietnam). Treatment failure was associated independently with plasmepsin2/3 amplification status and four mutations in the crt gene (Thr93Ser, His97Tyr, Phe145Ile, and Ile218Phe). Compared with the results of our previous TRACI trial in 2011-13, the prevalence of molecular markers of artemisinin resistance (kelch13 Cys580Tyr mutations) and piperaquine resistance (plasmepsin2/3 amplifications and crt mutations) has increased substantially in the Greater Mekong subregion in the past decade.Dihydroartemisinin-piperaquine is not treating malaria effectively across the eastern Greater Mekong subregion. A highly drug-resistant P falciparum co-lineage is evolving, acquiring new resistance mechanisms, and spreading. Accelerated elimination of P falciparum malaria in this region is needed urgently, to prevent further spread and avoid a potential global health emergency.UK Department for International Development, Wellcome Trust, BillMelinda Gates Foundation, Medical Research Council, and National Institutes of Health.

Published

2019

13. Probabilistic classification of Plasmodium vivax relapse and reinfection using microsatellite genotyping data for improved estimation of radical curative efficacy

Author

Taylor, A, Watson, J, Buckee, C, Imwong, M, Chu, C, and White, N

Published

2019

14. Polymorphisms in Pvkelch12 and gene amplification of Pvplasmepsin4 in Plasmodium vivax from Thailand, Lao PDR and Cambodia

Author

Duanguppama, J, Mathema, V, Tripura, R, Day, N, Nguon, C, Maxay, M, Von Seidlein, L, Dhorda, M, Peto, T, Nosten, F, White, N, Dondorp, A, Imwong, M, Graduate School, AII - Infectious diseases, APH - Aging & Later Life, and APH - Global Health

Subjects

Genetic Markers, lcsh:Arctic medicine. Tropical medicine, Genotype, lcsh:RC955-962, CNV, Drug Resistance, Mutation, Missense, Protozoan Proteins, Drug pressure, Real-Time Polymerase Chain Reaction, lcsh:Infectious and parasitic diseases, Antimalarials, Mutation Rate, parasitic diseases, Malaria, Vivax, Aspartic Acid Endopeptidases, Humans, P. vivax, lcsh:RC109-216, Polymorphism, Genetic, Research, Gene Amplification, Sequence Analysis, DNA, Thailand, Artemisinins, Malaria, Laos, Quinolines, Cambodia, Plasmodium vivax, Mutations, SNPs

Abstract

Background Mutations in Pfkelch13 and Pfplasmepsin2/3 gene amplification are well-established markers for artemisinin and piperaquine resistance in Plasmodium falciparum, a widespread problem in the Greater Mekong Subregion (GMS). The Plasmodium vivax parasite population has experienced varying drug pressure dependent on local drug policies. We investigated the correlation between drug pressure from artemisinins and piperaquine and mutations in the P. vivax orthologous genes Pvkelch12 and Pvplasmepsin4 (Pvpm4), as candidate resistance markers. Methods Blood samples from 734 P. vivax patients were obtained from Thailand (n = 399), Lao PDR (n = 296) and Cambodia (n = 39) between 2007 and 2017. Pvkelch12 and Pvpm4 was amplified and sequenced to assess gene mutations. To assess PvPM4 gene amplification, a Taqman® Real-Time PCR method was developed and validated. Selection of non-synonymous mutations was assessed by its ratio with synonymous mutations (Ka/Ks ratios). Mutation rates were compared to the estimated local drug pressure. Results Polymorphisms in Pvkelch12 were rare. Pvkelch12 mutations V552I, K151Q and M124I were observed in 1.0% (7/734) of P. vivax samples. V552I was the most common mutation with a frequency of 0.7% (5/734), most of which (4/5) observed in Ubon Ratchathani, Thailand. Polymorphisms in Pvpm4 were more common, with a frequency of 40.3% (123/305) in 305 samples from Thailand, Lao PDR and Cambodia, but this was not related to the estimated piperaquine drug pressure in these areas (Pearson’s χ2 test, p = 0.50). Pvpm4 mutation V165I was most frequent in Tak, Thailand (40.2%, 43/107) followed by Pailin, Cambodia (43.5%, 37/85), Champasak, Lao PDR (40.4%, 23/57) and Ubon Ratchathani, Thailand (35.7%, 20/56). Pvpm4 amplification was not observed in 141 samples from Thailand and Cambodia. For both Pvkelch12 and Pvpm4, in all areas and at all time points, the Ka/Ks values were

Published

2019

15. OSTRFPD: Multifunctional Tool for Genome-Wide Short Tandem Repeat Analysis for DNA, Transcripts, and Amino Acid Sequences with Integrated Primer Designer

Author

Mathema, VB, Dondorp, AM, and Imwong, M

Subjects

Computational Bioinformatics Tools for Evolutionary Genomics - Original Research, tandem repeat, ComputingMethodologies_PATTERNRECOGNITION, in silico mining, genotyping marker, lcsh:Evolution, lcsh:QH359-425, flanking sequence, microsatellites

Abstract

Microsatellite mining is a common outcome of the in silico approach to genomic studies. The resulting short tandemly repeated DNA could be used as molecular markers for studying polymorphism, genotyping and forensics. The omni short tandem repeat finder and primer designer (OSTRFPD) is among the few versatile, platform-independent open-source tools written in Python that enables researchers to identify and analyse genome-wide short tandem repeats in both nucleic acids and protein sequences. OSTRFPD is designed to run either in a user-friendly fully featured graphical interface or in a command line interface mode for advanced users. OSTRFPD can detect both perfect and imperfect repeats of low complexity with customisable scores. Moreover, the software has built-in architecture to simultaneously filter selection of flanking regions in DNA and generate microsatellite-targeted primers implementing the Primer3 platform. The software has built-in motif-sequence generator engines and an additional option to use the dictionary mode for custom motif searches. The software generates search results including general statistics containing motif categorisation, repeat frequencies, densities, coverage, guanine–cytosine (GC) content, and simple text-based imperfect alignment visualisation. Thus, OSTRFPD presents users with a quick single-step solution package to assist development of microsatellite markers and categorise tandemly repeated amino acids in proteome databases. Practical implementation of OSTRFPD was demonstrated using publicly available whole-genome sequences of selected Plasmodium species. OSTRFPD is freely available and open-sourced for improvement and user-specific adaptation.

Published

2019

16. The impact of targeted malaria elimination with mass drug administrations on falciparum malaria in Southeast Asia: a cluster randomised trial

Author

Von Seidlein, L, Peto, TJ, Landier, J, Nguyen, T-N, Tripura, R, Phommasone, K, Pongvongsa, T, Lwin, KM, Keereecharoen, L, Kajeechiwa, L, Thwin, MM, Parker, DM, Wiladphaingern, J, Nosten, S, Proux, S, Corbel, V, Tuong-Vy, N, Phuc-Nhi, TL, Son, DH, Huong-Thu, PN, Tuyen, NTK, Tien, NT, Dong, LT, Hue, DV, Quang, HH, Nguon, C, Davoeung, C, Rekol, H, Adhikari, B, Henriques, G, Phongmany, P, Suangkanarat, P, Jeeyapant, A, Vihokhern, B, Van Der Pluijm, RW, Lubell, Y, White, LJ, Aguas, R, Promnarate, C, Sirithiranont, P, Malleret, B, Rénia, L, Onsjö, C, Chan, XH, Chalk, J, Miotto, O, Patumrat, K, Chotivanich, K, Hanboonkunupakarn, B, Jittmala, P, Kaehler, N, Cheah, PY, Pell, C, Dhorda, M, Imwong, M, Snounou, G, Mukaka, M, Peerawaranun, P, Lee, SJ, Simpson, JA, Pukrittayakamee, S, Singhasivanon, P, Grobusch, MP, Cobelens, F, Smithuis, F, Newton, PN, Thwaites, GE, Day, NPJ, Mayxay, M, Hien, TT, Nosten, FH, Dondorp, AM, White, NJ, Mahidol Oxford Tropical Medicine Research Unit (MORU), University of Oxford-Mahidol University [Bangkok]-Wellcome Trust, Centre for Tropical Medicine and Global Health [Oxford, UK], Nuffield Department of Medicine [Oxford, UK] (Big Data Institute), University of Oxford-University of Oxford, Sciences Economiques et Sociales de la Santé & Traitement de l'Information Médicale (SESSTIM - U1252 INSERM - Aix Marseille Univ - UMR 259 IRD), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM), Shoklo Malaria Research Unit [Mae Sot, Thailand] (SMRU), University of Oxford-Mahidol University [Bangkok]-Wellcome Trust-University of Oxford-Mahidol University [Bangkok]-Wellcome Trust, Oxford University Clinical Research Unit [Ho Chi Minh City] (OUCRU), Department of Infectious Diseases [Amsterdam, Netherlands] (Academic Medical Center), University of Amsterdam [Amsterdam] (UvA)-Center for Tropical and Travel Medicine [Amsterdam, Netherlands], Lao-Oxford-Mahosot Hospital-Wellcome Trust Research Unit (LOMWRU), Mahidol University [Bangkok]-Mahosot Hospital, Amsterdam Institute for Global Health & Development [Amsterdam, The Netherlands], Savannakhet Provincial Health Department [Lao People’s Democratic Republic], Savannakhet Province [Lao People’s Democratic Republic], Department of Clinical Tropical Medicine [Bangkok, Thailand] (Faculty of Tropical Medicine), Mahidol University [Bangkok], Department of Population Health and Disease Prevention [Irvine, CA, USA], University of California [Irvine] (UC Irvine), University of California (UC)-University of California (UC), Génétique et évolution des maladies infectieuses (GEMI), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Institute of Malariology, Parasitology, and Entomology [Ho Chi Minh City, Vietnam] (IMPE), Center for Malariology, Parasitology and Entomology [Ninh Thuan Province, Vietnam] (CMPE), Institute of Malariology, Parasitology, and Entomology [Quy Nhon, Vietnam] (IMPE), National Center for Parasitology, Entomology and Malaria Control [Phnom Penh, Cambodia] (CNM), Provincial Health Department [Battambang, Cambodia] (PHD), Department of Pathogen Molecular Biology [London, UK], London School of Hygiene and Tropical Medicine (LSHTM), WWARN Asia Regional Centre [Bangkok, Thailand], Department of Microbiology & Immunology [Singapore] (Yong Loo Lin School of Medicine), National University of Singapore (NUS), Singapore Immunology Network (SIgN), Biomedical Sciences Institute (BMSI), Department of Oncology, Clinical and Experimental Medicine, Faculty of Health Sciences [Linköping University ], Linköping University (LIU), Wellcome Trust Sanger Institute [Hinxton, UK], Department of Molecular Tropical Medicine and Genetics [Bangkok, Thailand] (Faculty of Tropical Medicine), Department of Tropical Hygiene [Bangkok, Thailand] (Faculty of Tropical Medicine), Immunologie des Maladies Virales et Autoimmunes (IMVA - U1184), Université Paris-Sud - Paris 11 (UP11)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de la Santé et de la Recherche Médicale (INSERM), Centre for Epidemiology and Biostatistics [Victoria, Australia], University of Melbourne-Melbourne School of Population and Global Health [Victoria, Australia], Royal Society of Thailand [Bangkok, Thailand], Myanmar Oxford Clinical Research Unit [Yangon, Myanmar], Institute of Research and Education Development [Vientiane, Lao People’s Democratic Republic], University of Health Sciences [Vientiane, Laos] (UHS), NJW is the recipient of the Wellcome Trust Award Number: 101148/Z/13/Z. AMD is the recipient of the Bill and Melinda Gates Foundation Award Number: OPP1081420. JAS is the recipient of the National Health and Medical Research Council Award Number: 1104975., Dupuis, Christine, Mahidol Oxford Tropical Medicine Research Unit, University of Oxford [Oxford]-Mahidol University [Bangkok], University of Oxford [Oxford]-Mahidol University [Bangkok]-Wellcome Trust, Shoklo Malaria Research Unit [Mae Sot, Thailand] (Faculty of Tropical Medicine), Mahidol University [Bangkok]-Mahidol Oxford Tropical Medicine Research Unit (MORU), University of Oxford [Oxford]-Mahidol University [Bangkok]-Wellcome Trust-University of Oxford [Oxford]-Wellcome Trust, Laboratoire de Lutte contre les Insectes Nuisibles, National Institute of Malariology, Parasitology and Entomology, National Center for Parasitology, Entomology, and Malaria Control, Institut des Maladies Emergentes et des Thérapies Innovantes (IMETI), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Institut Cochin (UMR_S567 / UMR 8104), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Descartes - Paris 5 (UPD5), Faculty of Tropical Medicine [Bangkok, Thailand], University of Oxford [Oxford], Faculty of Tropical Medicine, University of Oxford-Mahidol University [Bangkok], National Institute of Malariology, Parasitology and Entomology [Hanoi] (NIMPE), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), University of Oxford, Maladies infectieuses et vecteurs : écologie, génétique, évolution et contrôle (MIVEGEC), Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford], Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford]-Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford], University of Oxford [Oxford]-University of Oxford [Oxford], University of California [Irvine] (UCI), University of California-University of California, Graduate School, AII - Infectious diseases, APH - Aging & Later Life, APH - Global Health, APH - Methodology, Global Health, Infectious diseases, APH - Health Behaviors & Chronic Diseases, and APH - Quality of Care

Subjects

Male, Plasmodium, Myanmar, Medical and Health Sciences, Geographical Locations, [SDV.MHEP.MI]Life Sciences [q-bio]/Human health and pathology/Infectious diseases, Medicine and Health Sciences, Cluster Analysis, Malaria, Falciparum, Child, Asia, Southeastern, ComputingMilieux_MISCELLANEOUS, Cross-Over Studies, Pharmaceutics, Drugs, Drug Resistance, Multiple, Vietnam, [SDV.MHEP.MI] Life Sciences [q-bio]/Human health and pathology/Infectious diseases, Medicine, Mass Drug Administration, Female, Cambodia, Research Article, Adult, Drug Administration, Asia, Adolescent, Elimination, Plasmodium falciparum, Microbiology, Antimalarials, Young Adult, Drug Therapy, Microbial Control, General & Internal Medicine, Parasite Groups, parasitic diseases, Parasitic Diseases, Humans, [SDV.MP.PAR]Life Sciences [q-bio]/Microbiology and Parasitology/Parasitology, Disease Eradication, Pharmacology, Biology and Life Sciences, Tropical Diseases, Malaria, [SDV.SPEE] Life Sciences [q-bio]/Santé publique et épidémiologie, People and Places, Parasitology, [SDV.SPEE]Life Sciences [q-bio]/Santé publique et épidémiologie, Antimicrobial Resistance, Apicomplexa

Abstract

Background The emergence and spread of multidrug-resistant Plasmodium falciparum in the Greater Mekong Subregion (GMS) threatens global malaria elimination efforts. Mass drug administration (MDA), the presumptive antimalarial treatment of an entire population to clear the subclinical parasite reservoir, is a strategy to accelerate malaria elimination. We report a cluster randomised trial to assess the effectiveness of dihydroartemisinin-piperaquine (DP) MDA in reducing falciparum malaria incidence and prevalence in 16 remote village populations in Myanmar, Vietnam, Cambodia, and the Lao People’s Democratic Republic, where artemisinin resistance is prevalent. Methods and findings After establishing vector control and community-based case management and following intensive community engagement, we used restricted randomisation within village pairs to select 8 villages to receive early DP MDA and 8 villages as controls for 12 months, after which the control villages received deferred DP MDA. The MDA comprised 3 monthly rounds of 3 daily doses of DP and, except in Cambodia, a single low dose of primaquine. We conducted exhaustive cross-sectional surveys of the entire population of each village at quarterly intervals using ultrasensitive quantitative PCR to detect Plasmodium infections. The study was conducted between May 2013 and July 2017. The investigators randomised 16 villages that had a total of 8,445 residents at the start of the study. Of these 8,445 residents, 4,135 (49%) residents living in 8 villages, plus an additional 288 newcomers to the villages, were randomised to receive early MDA; 3,790 out of the 4,423 (86%) participated in at least 1 MDA round, and 2,520 out of the 4,423 (57%) participated in all 3 rounds. The primary outcome, P. falciparum prevalence by month 3 (M3), fell by 92% (from 5.1% [171/3,340] to 0.4% [12/2,828]) in early MDA villages and by 29% (from 7.2% [246/3,405] to 5.1% [155/3,057]) in control villages. Over the following 9 months, the P. falciparum prevalence increased to 3.3% (96/2,881) in early MDA villages and to 6.1% (128/2,101) in control villages (adjusted incidence rate ratio 0.41 [95% CI 0.20 to 0.84]; p = 0.015). Individual protection was proportional to the number of completed MDA rounds. Of 221 participants with subclinical P. falciparum infections who participated in MDA and could be followed up, 207 (94%) cleared their infections, including 9 of 10 with artemisinin- and piperaquine-resistant infections. The DP MDAs were well tolerated; 6 severe adverse events were detected during the follow-up period, but none was attributable to the intervention. Conclusions Added to community-based basic malaria control measures, 3 monthly rounds of DP MDA reduced the incidence and prevalence of falciparum malaria over a 1-year period in areas affected by artemisinin resistance. P. falciparum infections returned during the follow-up period as the remaining infections spread and malaria was reintroduced from surrounding areas. Limitations of this study include a relatively small sample of villages, heterogeneity between villages, and mobility of villagers that may have limited the impact of the intervention. These results suggest that, if used as part of a comprehensive, well-organised, and well-resourced elimination programme, DP MDA can be a useful additional tool to accelerate malaria elimination. Trial registration ClinicalTrials.gov NCT01872702, In a cluster-randomized trial, Lorenz von Seidlin & colleagues investigate whether mass drug administration can accelerate malaria elimination in the Greater Mekong Subregion., Author summary Why was this study done? The emergence and spread of multidrug resistance in the Greater Mekong Subregion (GMS) threaten regional and global malaria control. Mass drug administrations (MDAs) are controversial but could be useful in the control and elimination of malaria. We wanted to know whether well-resourced MDAs can accelerate malaria elimination in the GMS. What did the researchers do and find? We randomised 16 villages (clusters) to receive MDAs with antimalarial drugs (dihydroartemisinin-piperaquine [DP] plus low-dose primaquine) either in year 1 or year 2 of the study. The entire village population (except pregnant women and children under the age of 6 months) was invited to take 3 consecutive daily doses of antimalarial drugs 3 times at monthly intervals. Everyone was followed up for 1 year; all malaria cases were recorded, and quarterly malaria surveys were conducted using highly sensitive high-volume PCR detection. Most (87%) of the villagers completed at least 1 round of the antimalarial drugs, which were well tolerated. The intervention had a substantial impact on the prevalence of P. falciparum infections by month 3 after the start of the MDAs. Over the subsequent 9 months, P. falciparum infections returned but stayed below baseline levels. What do these findings mean? MDAs might be a useful tool to accelerate falciparum malaria elimination in low-endemicity settings. The effectiveness of MDAs depends on continued support for village health workers, adequate drug efficacy, high levels of community participation, and carefully planned roll out to minimise the risk of malaria reintroduction.

Published

2019

17. Artemisinin resistance and stage dependency of parasite clearance in Falciparum malaria

Author

Intharabut, B, Kingston, H, Srinamon, K, Ashley, E, Imwong, M, Dhorda, M, Woodrow, C, Stepniewska, K, Silamut, K, Day, N, Dondorp, A, White, N, and Collaboration, Tracking Resistance To Artemisinin

Subjects

Life Cycle Stages, parasite clearance, Genotype, Errata, Plasmodium falciparum, Drug Resistance, Protozoan Proteins, artemisinin resistance, Parasitemia, Artemisinins, Major Articles and Brief Reports, Antimalarials, Mutation, parasitic diseases, microscopy, parasite stage, Humans, Parasites, Drug Therapy, Combination, Falciparum malaria, Malaria, Falciparum

Abstract

Background Artemisinin resistance in falciparum malaria is associated with kelch13 propeller mutations, reduced ring stage parasite killing, and, consequently, slow parasite clearance. We assessed how parasite age affects parasite clearance in artemisinin resistance. Methods Developmental stages of Plasmodium falciparum parasites on blood films performed at hospital admission and their kelch13 genotypes were assessed for 816 patients enrolled in a multinational clinical trial of artemisinin combination therapy. Results Early changes in parasitemia level (ie, 0–6 hours after admission) were determined mainly by modal stage of asexual parasite development, whereas the subsequent log-linear decline was determined mainly by kelch13 propeller mutations. Older circulating parasites on admission were associated with more-rapid parasite clearance, particularly in kelch13 mutant infections. The geometric mean parasite clearance half-life decreased by 11.6% (95% CI 3.4%–19.1%) in kelch13 wild-type infections and by 30% (95% CI 17.8%–40.4%) in kelch13 mutant infections as the mean age of circulating parasites rose from 3 to 21 hours. Conclusion Following the start of antimalarial treatment, ongoing parasite sequestration and schizogony both affect initial changes in parasitemia. The greater dependency of parasite clearance half-life on parasite age in artemisinin resistant infections is consistent with ring stage resistance and consequent parasite clearance by sequestration. The stage of parasite development should be incorporated in individual assessments of artemisinin resistance., The effect of parasite stage of development on the parasite clearance curve was investigated in areas affected by artemisinin resistance. Parasite stage shapes the early part of the clearance curve and also influences the subsequent log-linear decline.

Published

2019

18. Simultaneous quantification of Plasmodium antigens and host factor CRP in asymptomatic individuals with confirmed malaria using a novel multiplex immunoassay

Author

Jang, I, Tyler, A, Lyman, C, Kahn, M, Kalnoky, M, Rek, J, Arinaitwe, E, Adrama, H, Murphy, M, Imwong, M, Ling, C, Proux, S, Haohankhunnatham, W, Rist, M, Seilie, A, Hanron, A, Daza, G, Chang, M, Das, S, Barney, R, Rashid, A, Landier, J, Boyle, D, Murphy, S, McCarthy, J, Nosten, F, Greenhouse, B, and Domingo, G

Subjects

parasitic diseases

Abstract

Malaria rapid diagnostic tests (RDTs) primarily detect Plasmodium falciparum antigen histidine-rich protein 2 (HRP2) and the malaria-conserved antigen lactate dehydrogenase (LDH) for P. vivax and other malaria species. The performance of RDTs and their utility is dependent on circulating antigen concentration distributions in infected individuals in a population in which malaria is endemic and on the limit of detection of the RDT for the antigens. A multiplexed immunoassay for the quantification of HRP2, P. vivax LDH, and all-malaria LDH (pan LDH) was developed to accurately measure circulating antigen concentration and antigen distribution in a population with endemic malaria. The assay also measures C-reactive protein (CRP) levels as an indicator of inflammation. Validation was conducted with clinical specimens from 397 asymptomatic donors from Myanmar and Uganda, confirmed by PCR for infection, and from participants in induced blood-stage malaria challenge studies. The assay lower limits of detection for HRP2, pan LDH, P. vivax LDH, and CRP were 0.2 pg/ml, 9.3 pg/ml, 1.5 pg/ml, and 26.6 ng/ml, respectively. At thresholds for HRP2, pan LDH, and P. vivax LDH of 2.3 pg/ml, 47.8 pg/ml, and 75.1 pg/ml, respectively, and a specificity ≥98.5%, the sensitivities for ultrasensitive PCR-confirmed infections were 93.4%, 84.9%, and 48.9%, respectively. Plasmodium LDH (pLDH) concentration, in contrast to that of HRP2, correlated closely with parasite density. CRP levels were moderately higher in P. falciparum infections with confirmed antigenemia versus those in clinical specimens with no antigen. The 4-plex array is a sensitive tool for quantifying diagnostic antigens in malaria infections and supporting the evaluation of new ultrasensitive RDTs.

Published

2019

19. Contribution of Asymptomatic Plasmodium Infections to the Transmission of Malaria in Kayin State, Myanmar

Author

Chaumeau, V, Kajeechiwa, L, Fustec, B, Landier, J, Naw Nyo, S, Nay Hsel, S, Phatharakokordbun, P, Kittiphanakun, P, Nosten, S, Thwin, MM, Win Tun, S, Wiladphaingern, J, Cottrell, G, Parker, DM, Minh, MC, Kwansomboon, K, Metaane, S, Montazeau, C, Kunjanwong, K, Sawasdichai, S, Andolina, C, Ling, C, Haohankhunnatham, W, Christiensen, P, Wanyatip, S, Konghahong, K, Cerqueira, D, Imwong, M, Dondorp, AM, Chareonviriyaphap, T, White, NJ, Nosten, FH, Corbel, V, Dupuis, Christine, Génétique et évolution des maladies infectieuses (GEMI), Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Shoklo Malaria Research Unit [Mae Sot, Thailand] (SMRU), Mahidol Oxford Tropical Medicine Research Unit (MORU), University of Oxford-Mahidol University [Bangkok]-Wellcome Trust-University of Oxford-Mahidol University [Bangkok]-Wellcome Trust, Centre for Tropical Medicine and Global Health [Oxford, UK], Nuffield Department of Medicine [Oxford, UK] (Big Data Institute), University of Oxford-University of Oxford, Sciences Economiques et Sociales de la Santé & Traitement de l'Information Médicale (SESSTIM - U1252 INSERM - Aix Marseille Univ - UMR 259 IRD), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM), Institut de Recherche pour le Développement (IRD), Mère et enfant en milieu tropical : pathogènes, système de santé et transition épidémiologique (MERIT - UMR_D 216), Institut de Recherche pour le Développement (IRD)-Université Paris Descartes - Paris 5 (UPD5), Department of Population Health and Disease Prevention [Irvine, CA, USA], University of California [Irvine] (UC Irvine), University of California (UC)-University of California (UC), Department of Entomology [Bangkok, Thailand] (Faculty of Agriculture), Kasetsart University (KU), Université de Rennes 1 - Faculté des sciences pharmaceutiques et biologiques (UR1 Pharmacie), Université de Rennes (UR), Nuffield (Nuffield), University of Oxford, University of Oxford-Mahidol University [Bangkok]-Wellcome Trust, This work was supported by the Wellcome Trust (grant 101148, support to the Shoklo Malaria Research Unit, via the Mahidol-Oxford University Research Unit), the Global Fund (grant THA-M-DDC), the Bill and Melinda Gates Foundation (grant GH OPP 1081420), and the Centre Hospitalier Universitaire de Montpellier (support to V. C.)., Maladies infectieuses et vecteurs : écologie, génétique, évolution et contrôle (MIVEGEC), Université de Rennes - Faculté des sciences pharmaceutiques et biologiques (UR Pharmacie), Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford]-Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford], University of Oxford [Oxford]-University of Oxford [Oxford], University of California [Irvine] (UCI), University of California-University of California, Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES), University of Oxford [Oxford], and Wellcome Trust-Mahidol University [Bangkok]-University of Oxford [Oxford]

Subjects

Falciparum, primaquine, Plasmodium falciparum, malaria, Vivax, Mosquito Vectors, Myanmar, artemisinin resistance, Microbiology, Major Articles and Brief Reports, Antimalarials, Rare Diseases, elimination, [SDV.MHEP.MI]Life Sciences [q-bio]/Human health and pathology/Infectious diseases, parasitic diseases, Malaria, Vivax, Prevalence, 2.2 Factors relating to the physical environment, Humans, Parasites, Aetiology, Malaria, Falciparum, Asymptomatic Infections, Disease Reservoirs, entomological inoculation rate, Medical And Health Sciences, Incidence, Biological Sciences, Southeast Asia, Vector-Borne Diseases, Infectious Diseases, Good Health and Well Being, Mass drug administration, [SDV.SPEE] Life Sciences [q-bio]/Santé publique et épidémiologie, [SDV.MHEP.MI] Life Sciences [q-bio]/Human health and pathology/Infectious diseases, HIV/AIDS, [SDV.SPEE]Life Sciences [q-bio]/Santé publique et épidémiologie, Seasons, Infection, Plasmodium vivax

Abstract

Background The objective of mass antimalarial drug administration (MDA) is to eliminate malaria rapidly by eliminating the asymptomatic malaria parasite reservoirs and interrupting transmission. In the Greater Mekong Subregion, where artemisinin-resistant Plasmodium falciparum is now widespread, MDA has been proposed as an elimination accelerator, but the contribution of asymptomatic infections to malaria transmission has been questioned. The impact of MDA on entomological indices has not been characterized previously. Methods MDA was conducted in 4 villages in Kayin State (Myanmar). Malaria mosquito vectors were captured 3 months before, during, and 3 months after MDA, and their Plasmodium infections were detected by polymerase chain reaction (PCR) analysis. The relationship between the entomological inoculation rate, the malaria prevalence in humans determined by ultrasensitive PCR, and MDA was characterized by generalized estimating equation regression. Results Asymptomatic P. falciparum and Plasmodium vivax infections were cleared by MDA. The P. vivax entomological inoculation rate was reduced by 12.5-fold (95% confidence interval [CI], 1.6–100-fold), but the reservoir of asymptomatic P. vivax infections was reconstituted within 3 months, presumably because of relapses. This was coincident with a 5.3-fold (95% CI, 4.8–6.0-fold) increase in the vector infection rate. Conclusion Asymptomatic infections are a major source of malaria transmission in Southeast Asia., This study demonstrates the major contribution of asymptomatic low-density Plasmodium infections to the transmission of malaria in Southeast Asian settings. Mass drug administration with dihydroartemisinin-piperaquine can interrupt malaria transmission rapidly in areas where the prevalence of asymptomatic infection is high.

Published

2019

20. Real time PCR detection of common CYP2D6 genetic variants and its application in a Karen population study

Author

Puaprasert, K, Chu, C, Saralamba, N, Day, N, Nosten, F, White, N, Dondorp, A, and Imwong, M

Subjects

Adult, Male, Karen, lcsh:Arctic medicine. Tropical medicine, Adolescent, Genotyping Techniques, lcsh:RC955-962, Myanmar, Primaquine, Real-Time Polymerase Chain Reaction, Polymorphism, Single Nucleotide, digestive system, lcsh:Infectious and parasitic diseases, Young Adult, Malaria, Vivax, Humans, lcsh:RC109-216, Child, skin and connective tissue diseases, CYP2D6, Methodology, Genetic Variation, Thailand, Malaria, Cytochrome P-450 CYP2D6, Mutation, Female, Plasmodium vivax

Abstract

Background Plasmodium vivax malaria is characterized by relapses arising from the hypnozoite stages in the liver. The only currently registered drug for radical treatment to prevent relapse is primaquine. Primaquine, a prodrug, requires metabolism through the liver cytochrome CYP2D6 isoenzyme to its active metabolite. Mutations in the CYP2D6 gene may thus affect primaquine efficacy. A SNPs genotyping technique was developed to characterize the CYP2D6 genetic variants and tested this in the patients with Plasmodium vivax infection collected in a Karen population on the Thailand–Myanmar border, where P. vivax malaria is endemic. Methods Direct sequencing of PCR-reamplified products (DSP) was used to uncover exonic CYP2D6 sequence variations. Subsequently, an allele-specific oligonucleotide probe real-time SNPs genotyping (ASO) assay was developed for rapid detection of the four clinically relevant CYP2D6 variants occurring in this population. These two in-house developed assays were used to genotype CYP2D6 mutations in blood samples obtained from 70 Karen adults. Results Results showed a high degree of concordance between the DSP and ASO methods. Six CYP2D6 point mutations were identified within the Karen population: C100T, C1039T, G1661C, G1846A, C2850T and G4180C, at frequencies of 0.43, 0.43, 0.76, 0.02, 0.32 and 0.76, respectively. The CYP2D6*2, *4, *5, *10 and *36 allelic frequencies were 0.33, 0.02, 0.03, 0.40 and 0.01, respectively. Alleles conferring an intermediate CYP2D6 metabolizer phenotype comprised 46% of the total number of alleles. Conclusion The newly developed ASO assay is a reliable and rapid tool for large-scale CYP2D6 genotyping. The high frequency of the CYP2D6*10 allele in the Karen population warrants further assessment of its association with the radical curative efficacy of primaquine. Electronic supplementary material The online version of this article (10.1186/s12936-018-2579-8) contains supplementary material, which is available to authorized users.

Published

2018

21. Microsatellite Variation, Repeat Array Length, and Population History of Plasmodium vivax

Author

Imwong, M., Sudimack, D., Pukrittayakamee, S., Osorio, L., Carlton, J. M., Day, N. P. J., White, N. J., and Anderson, T. J. C.

Published

2006

22. The temporal dynamics and infectiousness of subpatent Plasmodium falciparum infections in relation to parasite density (vol 10, 1433, 2019)

Author

Slater, HC, Ross, A, Felger, I, Hofmann, NE, Robinson, L, Cook, J, Goncalves, BP, Bjorkman, A, Ouedraogo, AL, Morris, U, Msellem, M, Koepfli, C, Mueller, I, Tadesse, F, Gadisa, E, Das, S, Domingo, G, Kapulu, M, Midega, J, Owusu-Agyei, S, Nabet, C, Piarroux, R, Doumbo, O, Doumbo, SN, Koram, K, Lucchi, N, Udhayakumar, V, Mosha, J, Tiono, A, Chandramohan, D, Gosling, R, Mwingira, F, Sauerwein, R, Paul, R, Riley, EM, White, NJ, Nosten, F, Imwong, M, Bousema, T, Drakeley, C, Okell, LC, Slater, HC, Ross, A, Felger, I, Hofmann, NE, Robinson, L, Cook, J, Goncalves, BP, Bjorkman, A, Ouedraogo, AL, Morris, U, Msellem, M, Koepfli, C, Mueller, I, Tadesse, F, Gadisa, E, Das, S, Domingo, G, Kapulu, M, Midega, J, Owusu-Agyei, S, Nabet, C, Piarroux, R, Doumbo, O, Doumbo, SN, Koram, K, Lucchi, N, Udhayakumar, V, Mosha, J, Tiono, A, Chandramohan, D, Gosling, R, Mwingira, F, Sauerwein, R, Paul, R, Riley, EM, White, NJ, Nosten, F, Imwong, M, Bousema, T, Drakeley, C, and Okell, LC

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

23. The temporal dynamics and infectiousness of subpatent Plasmodium falciparum infections in relation to parasite density

Author

Slater, HC, Ross, A, Felger, I, Hofmann, NE, Robinson, L, Cook, J, Goncalves, BP, Bjorkman, A, Ouedraogo, AL, Morris, U, Msellem, M, Koepfli, C, Mueller, I, Tadesse, F, Gadisa, E, Das, S, Domingo, G, Kapulu, M, Midega, J, Owusu-Agyei, S, Nabet, C, Piarroux, R, Doumbo, O, Doumbo, SN, Koram, K, Lucchi, N, Udhayakumar, V, Mosha, J, Tiono, A, Chandramohan, D, Gosling, R, Mwingira, F, Sauerwein, R, Riley, EM, White, NJ, Nosten, F, Imwong, M, Bousema, T, Drakeley, C, Okell, LC, Slater, HC, Ross, A, Felger, I, Hofmann, NE, Robinson, L, Cook, J, Goncalves, BP, Bjorkman, A, Ouedraogo, AL, Morris, U, Msellem, M, Koepfli, C, Mueller, I, Tadesse, F, Gadisa, E, Das, S, Domingo, G, Kapulu, M, Midega, J, Owusu-Agyei, S, Nabet, C, Piarroux, R, Doumbo, O, Doumbo, SN, Koram, K, Lucchi, N, Udhayakumar, V, Mosha, J, Tiono, A, Chandramohan, D, Gosling, R, Mwingira, F, Sauerwein, R, Riley, EM, White, NJ, Nosten, F, Imwong, M, Bousema, T, Drakeley, C, and Okell, LC

Abstract

Malaria infections occurring below the limit of detection of standard diagnostics are common in all endemic settings. However, key questions remain surrounding their contribution to sustaining transmission and whether they need to be detected and targeted to achieve malaria elimination. In this study we analyse a range of malaria datasets to quantify the density, detectability, course of infection and infectiousness of subpatent infections. Asymptomatically infected individuals have lower parasite densities on average in low transmission settings compared to individuals in higher transmission settings. In cohort studies, subpatent infections are found to be predictive of future periods of patent infection and in membrane feeding studies, individuals infected with subpatent asexual parasite densities are found to be approximately a third as infectious to mosquitoes as individuals with patent (asexual parasite) infection. These results indicate that subpatent infections contribute to the infectious reservoir, may be long lasting, and require more sensitive diagnostics to detect them in lower transmission settings.

Published

2019

24. Simultaneous Quantification of Plasmodium Antigens and Host Factor C-Reactive Protein in Asymptomatic Individuals with Confirmed Malaria by Use of a Novel Multiplex Immunoassay

Author

Loeffelholz, MJ, Jang, IK, Tyler, A, Lyman, C, Kahn, M, Kalnoky, M, Rek, JC, Arinaitwe, E, Adrama, H, Murphy, M, Imwong, M, Ling, CL, Proux, S, Haohankhunnatham, W, Rist, M, Seilie, AM, Hanron, A, Daza, G, Chang, M, Das, S, Barney, R, Rashid, A, Landier, J, Boyle, DS, Murphy, SC, McCarthy, JS, Nosten, F, Greenhouse, B, Domingo, GJ, Loeffelholz, MJ, Jang, IK, Tyler, A, Lyman, C, Kahn, M, Kalnoky, M, Rek, JC, Arinaitwe, E, Adrama, H, Murphy, M, Imwong, M, Ling, CL, Proux, S, Haohankhunnatham, W, Rist, M, Seilie, AM, Hanron, A, Daza, G, Chang, M, Das, S, Barney, R, Rashid, A, Landier, J, Boyle, DS, Murphy, SC, McCarthy, JS, Nosten, F, Greenhouse, B, and Domingo, GJ

Abstract

Malaria rapid diagnostic tests (RDTs) primarily detect Plasmodium falciparum antigen histidine-rich protein 2 (HRP2) and the malaria-conserved antigen lactate dehydrogenase (LDH) for P. vivax and other malaria species. The performance of RDTs and their utility is dependent on circulating antigen concentration distributions in infected individuals in a population in which malaria is endemic and on the limit of detection of the RDT for the antigens. A multiplexed immunoassay for the quantification of HRP2, P. vivax LDH, and all-malaria LDH (pan LDH) was developed to accurately measure circulating antigen concentration and antigen distribution in a population with endemic malaria. The assay also measures C-reactive protein (CRP) levels as an indicator of inflammation. Validation was conducted with clinical specimens from 397 asymptomatic donors from Myanmar and Uganda, confirmed by PCR for infection, and from participants in induced blood-stage malaria challenge studies. The assay lower limits of detection for HRP2, pan LDH, P. vivax LDH, and CRP were 0.2 pg/ml, 9.3 pg/ml, 1.5 pg/ml, and 26.6 ng/ml, respectively. At thresholds for HRP2, pan LDH, and P. vivax LDH of 2.3 pg/ml, 47.8 pg/ml, and 75.1 pg/ml, respectively, and a specificity ≥98.5%, the sensitivities for ultrasensitive PCR-confirmed infections were 93.4%, 84.9%, and 48.9%, respectively. Plasmodium LDH (pLDH) concentration, in contrast to that of HRP2, correlated closely with parasite density. CRP levels were moderately higher in P. falciparum infections with confirmed antigenemia versus those in clinical specimens with no antigen. The 4-plex array is a sensitive tool for quantifying diagnostic antigens in malaria infections and supporting the evaluation of new ultrasensitive RDTs.

Published

2019

25. The impact of targeted malaria elimination with mass drug administrations on falciparum malaria in Southeast Asia: A cluster randomised trial

Author

Beeson, JG, von Seidlein, L, Peto, TJ, Landier, J, Thuy-Nhien, N, Tripura, R, Phommasone, K, Pongvongsa, T, Lwin, KM, Keereecharoen, L, Kajeechiwa, L, Thwin, MM, Parker, DM, Wiladphaingern, J, Nosten, S, Proux, S, Corbel, V, Nguyen, T-V, Truong, LP-N, Do, HS, Pham, NH-T, Nguyen, TKT, Nguyen, TT, Le, TD, Dao, VH, Huynh, HQ, Nguon, C, Davoeung, C, Rekol, H, Adhikari, B, Henriques, G, Phongmany, P, Suangkanarat, P, Jeeyapant, A, Vihokhern, B, van der Pluijm, RW, Lubell, Y, White, LJ, Aguas, R, Promnarate, C, Sirithiranont, P, Malleret, B, Renia, L, Onsjo, C, Chan, XH, Chalk, J, Miotto, O, Patumrat, K, Chotivanich, K, Hanboonkunupakarn, B, Jittmala, P, Kaehler, N, Cheah, PY, Pell, C, Dhorda, M, Imwong, M, Snounou, G, Mukaka, M, Peerawaranun, P, Lee, SJ, Simpson, JA, Pukrittayakamee, S, Singhasivanon, P, Grobusch, MP, Cobelens, F, Smithuis, F, Newton, PN, Thwaites, GE, Day, NPJ, Mayxay, M, Tran, TH, Nosten, FH, Dondorp, AM, White, NJ, Beeson, JG, von Seidlein, L, Peto, TJ, Landier, J, Thuy-Nhien, N, Tripura, R, Phommasone, K, Pongvongsa, T, Lwin, KM, Keereecharoen, L, Kajeechiwa, L, Thwin, MM, Parker, DM, Wiladphaingern, J, Nosten, S, Proux, S, Corbel, V, Nguyen, T-V, Truong, LP-N, Do, HS, Pham, NH-T, Nguyen, TKT, Nguyen, TT, Le, TD, Dao, VH, Huynh, HQ, Nguon, C, Davoeung, C, Rekol, H, Adhikari, B, Henriques, G, Phongmany, P, Suangkanarat, P, Jeeyapant, A, Vihokhern, B, van der Pluijm, RW, Lubell, Y, White, LJ, Aguas, R, Promnarate, C, Sirithiranont, P, Malleret, B, Renia, L, Onsjo, C, Chan, XH, Chalk, J, Miotto, O, Patumrat, K, Chotivanich, K, Hanboonkunupakarn, B, Jittmala, P, Kaehler, N, Cheah, PY, Pell, C, Dhorda, M, Imwong, M, Snounou, G, Mukaka, M, Peerawaranun, P, Lee, SJ, Simpson, JA, Pukrittayakamee, S, Singhasivanon, P, Grobusch, MP, Cobelens, F, Smithuis, F, Newton, PN, Thwaites, GE, Day, NPJ, Mayxay, M, Tran, TH, Nosten, FH, Dondorp, AM, and White, NJ

Abstract

BACKGROUND: The emergence and spread of multidrug-resistant Plasmodium falciparum in the Greater Mekong Subregion (GMS) threatens global malaria elimination efforts. Mass drug administration (MDA), the presumptive antimalarial treatment of an entire population to clear the subclinical parasite reservoir, is a strategy to accelerate malaria elimination. We report a cluster randomised trial to assess the effectiveness of dihydroartemisinin-piperaquine (DP) MDA in reducing falciparum malaria incidence and prevalence in 16 remote village populations in Myanmar, Vietnam, Cambodia, and the Lao People's Democratic Republic, where artemisinin resistance is prevalent. METHODS AND FINDINGS: After establishing vector control and community-based case management and following intensive community engagement, we used restricted randomisation within village pairs to select 8 villages to receive early DP MDA and 8 villages as controls for 12 months, after which the control villages received deferred DP MDA. The MDA comprised 3 monthly rounds of 3 daily doses of DP and, except in Cambodia, a single low dose of primaquine. We conducted exhaustive cross-sectional surveys of the entire population of each village at quarterly intervals using ultrasensitive quantitative PCR to detect Plasmodium infections. The study was conducted between May 2013 and July 2017. The investigators randomised 16 villages that had a total of 8,445 residents at the start of the study. Of these 8,445 residents, 4,135 (49%) residents living in 8 villages, plus an additional 288 newcomers to the villages, were randomised to receive early MDA; 3,790 out of the 4,423 (86%) participated in at least 1 MDA round, and 2,520 out of the 4,423 (57%) participated in all 3 rounds. The primary outcome, P. falciparum prevalence by month 3 (M3), fell by 92% (from 5.1% [171/3,340] to 0.4% [12/2,828]) in early MDA villages and by 29% (from 7.2% [246/3,405] to 5.1% [155/3,057]) in control villages. Over the following 9 months, th

Published

2019

26. Asymptomatic natural human infections with the Simian malaria parasites plasmodium cynomolgi and plasmodium knowlesi

Author

Imwong, M, Madmanee, W, Suwannasin, K, Kunasol, C, Peto, T, Tripura, R, von Seidlein, L, Nguon, C, Davoeung, C, Day, N, Dondorp, A, and White, N

Subjects

parasitic diseases

Abstract

Background In Southeast Asia, Plasmodium knowlesi, a parasite of long-tailed macaques (Macaca fascicularis), is an important cause of human malaria. Plasmodium cynomolgi also commonly infects these monkeys, but only one naturally acquired symptomatic human case has been reported previously. Methods Malariometric studies involving 5422 subjects (aged 6 months to 65 years) were conducted in 23 villages in Pailin and Battambang, western Cambodia. Parasite detection and genotyping was conducted on blood samples, using high-volume quantitative PCR (uPCR). Results Asymptomatic malaria parasite infections were detected in 1361 of 14732 samples (9.2%). Asymptomatic infections with nonhuman primate malaria parasites were found in 21 individuals living close to forested areas; P. cynomolgi was found in 11, P. knowlesi was found in 8, and P. vivax and P. cynomolgi were both found in 2. Only 2 subjects were female, and 14 were men aged 20–40 years. Geometric mean parasite densities were 3604 parasites/mL in P. cynomolgi infections and 52488 parasites/mL in P. knowlesi infections. All P. cynomolgi isolates had wild-type dihydrofolate reductase genes, in contrast to the very high prevalence of mutations in the human malaria parasites. Asymptomatic reappearance of P. cynomolgi occurred in 2 subjects 3 months after the first infection. Conclusions Asymptomatic naturally acquired P. cynomolgi and P. knowlesi infections can both occur in humans.

Published

2018

27. Performance of a high-sensitivity rapid diagnostic test for Plasmodium falciparum malaria in asymptomatic individuals from Uganda and Myanmar and naive human challenge infections

Author

Das, S, Jang, IK, Barney, B, Peck, R, Rek, JC, Arinaitwe, E, Adrama, H, Murphy, M, Imwong, M, Ling, CL, Proux, S, Haohankhunnatham, W, Rist, M, Seilie, AM, Hanron, A, Daza, G, Chang, M, Nakamura, T, Kalnoky, M, Labarre, P, Murphy, SC, McCarthy, JS, Nosten, F, Greenhouse, B, Allauzen, S, and Domingo, GJ

Subjects

Diagnostic Tests, Routine, Reverse Transcriptase Polymerase Chain Reaction, Plasmodium falciparum, Protozoan Proteins, Infant, Antigens, Protozoan, Enzyme-Linked Immunosorbent Assay, Articles, Myanmar, Sensitivity and Specificity, Specimen Handling, Child, Preschool, parasitic diseases, Humans, Uganda, Malaria, Falciparum, Child, Asymptomatic Infections

Abstract

Sensitive field-deployable diagnostic tests can assist malaria programs in achieving elimination. The performance of a new Alere™ Malaria Ag P.f Ultra Sensitive rapid diagnostic test (uRDT) was compared with the currently available SD Bioline Malaria Ag P.f RDT in blood specimens from asymptomatic individuals in Nagongera, Uganda, and in a Karen Village, Myanmar, representative of high- and low-transmission areas, respectively, as well as in pretreatment specimens from study participants from four Plasmodium falciparum-induced blood-stage malaria (IBSM) studies. A quantitative reverse transcription PCR (qRT-PCR) and a highly sensitive enzyme-linked immunosorbent assay (ELISA) test for histidine-rich protein II (HRP2) were used as reference assays. The uRDT showed a greater than 10-fold lower limit of detection for HRP2 compared with the RDT. The sensitivity of the uRDT was 84% and 44% against qRT-PCR in Uganda and Myanmar, respectively, and that of the RDT was 62% and 0% for the same two sites. The specificities of the uRDT were 92% and 99.8% against qRT-PCR for Uganda and Myanmar, respectively, and 99% and 99.8% against the HRP2 reference ELISA. The RDT had specificities of 95% and 100% against qRT-PCR for Uganda and Myanmar, respectively, and 96% and 100% against the HRP2 reference ELISA. The uRDT detected new infections in IBSM study participants 1.5 days sooner than the RDT. The uRDT has the same workflow as currently available RDTs, but improved performance characteristics to identify asymptomatic malaria infections. The uRDT may be a useful tool for malaria elimination strategies.

Published

2017

28. Association between subclinical malaria infection and inflammatory host response in a pre-elimination setting

Author

Peto, Thomas, Tripura, R, Lee, Sue, Althaus, T, Dunachie, Susanna, Nguon, C, Dhorda, Mehul, Promnarate, C, Chalk, Jeremy, Imwong, M, von Seidlein, Lorenz, Day, Nicholas, Dondorp, Adrianus, White, Nicholas, Lubell, Yoel, Luty, AJF, and Luty, A

Subjects

Male, Plasmodium, Physiology, Fevers, lcsh:Medicine, Parasitemia, Pathology and Laboratory Medicine, Polymerase Chain Reaction, 0302 clinical medicine, Interquartile range, Medicine and Health Sciences, 030212 general & internal medicine, Malaria, Falciparum, Child, lcsh:Science, Asymptomatic Infections, Immune Response, Subclinical infection, Protozoans, Multidisciplinary, Malarial Parasites, Hematology, Body Fluids, 3. Good health, C-Reactive Protein, Blood, Infectious Diseases, Child, Preschool, Biomarker (medicine), Female, Anatomy, medicine.symptom, Cambodia, Research Article, Adult, Adolescent, Infectious Disease Control, Plasmodium falciparum, Immunology, 030231 tropical medicine, Inflammation, Biology, Asymptomatic, Blood Plasma, 03 medical and health sciences, Signs and Symptoms, Diagnostic Medicine, Immunity, Parasite Groups, parasitic diseases, Malaria, Vivax, Parasitic Diseases, medicine, Humans, lcsh:R, Organisms, Infant, Biology and Life Sciences, Odds ratio, Tropical Diseases, medicine.disease, Parasitic Protozoans, Malaria, Case-Control Studies, Parasitology, lcsh:Q, Plasmodium vivax, Apicomplexa

Abstract

Background Subclinical infections in endemic areas of Southeast Asia sustain malaria transmission. These asymptomatic infections might sustain immunity against clinical malaria and have been considered benign for the host, but if they are associated with chronic low-grade inflammation this could be harmful. We conducted a case-control study to explore the association between subclinical malaria and C-reactive protein (CRP), an established biomarker of inflammation. Methods Blood samples from asymptomatic villagers in Pailin, Western Cambodia were tested for malaria by high-volume ultra-sensitive polymerase chain reaction (uPCR) to determine the Plasmodium species. Plasma CRP concentration was measured in 328 individuals with parasitaemia (cases) and compared with: i) the same individual’s value at the first time point when they had no detectable parasites (n = 282); and ii) age- sex- and village-matched controls (n = 328) free of Plasmodium infection. Plasma CRP concentrations were compared against thresholds of 3mg/L and 10mg/L. Subgroup analysis was carried out for cases with P vivax and P falciparum mono-infections. Results Median plasma CRP level for all samples was 0.59mg/L (interquartile range: 0.24–1.64mg/L). CRP concentrations were higher in parasitaemic individuals compared with same-person-controls (p = 0.050); and matched-controls (p = 0.025). 4.9% of samples had CRP concentrations above 10mg/L and 14.6% were above 3mg/L. Cases were more likely to have plasma CRP concentrations above these thresholds than age/sex matched controls, odds ratio 3.5 (95%CI 1.5–9.8) and 1.8 (95%CI 1.1–2.9), respectively. Amongst cases, parasite density and CRP were positively correlated (p

Published

2017

29. Safety and effectiveness of mass drug administration to accelerate elimination of artemisinin-resistant falciparum malaria: A pilot trial in four villages of Eastern Myanmar.

Author

Landier, J, Kajeechiwa, L, Thwin, MM, Parker, DM, Chaumeau, V, Wiladphaingern, J, Imwong, M, Miotto, O, Patumrat, K, Duanguppama, J, Cerqueira, D, Malleret, B, Rénia, L, Nosten, S, von Seidlein, L, Ling, C, Proux, S, Corbel, V, Simpson, JA, Dondorp, AM, White, NJ, Nosten, FH, Landier, J, Kajeechiwa, L, Thwin, MM, Parker, DM, Chaumeau, V, Wiladphaingern, J, Imwong, M, Miotto, O, Patumrat, K, Duanguppama, J, Cerqueira, D, Malleret, B, Rénia, L, Nosten, S, von Seidlein, L, Ling, C, Proux, S, Corbel, V, Simpson, JA, Dondorp, AM, White, NJ, and Nosten, FH

Abstract

Background: Artemisinin and partner drug-resistant falciparum malaria is expanding over the Greater Mekong Sub-region (GMS). Eliminating falciparum malaria in the GMS while drugs still retain enough efficacy could prevent global spread of antimalarial resistance. Eliminating malaria rapidly requires targeting the reservoir of asymptomatic parasite carriers. This pilot trial aimed to evaluate the acceptability, safety, feasibility and effectiveness of mass-drug administration (MDA) in reducing malaria in four villages in Eastern Myanmar. Methods: Villages with ≥30% malaria prevalence were selected. Long-lasting insecticidal bednets (LLINs) and access to malaria early diagnosis and treatment (EDT) were provided. Two villages received MDA immediately and two were followed for nine months pre-MDA. MDA consisted of a 3-day supervised course of dihydroartemisinin-piperaquine and single low-dose primaquine administered monthly for three months. Adverse events (AE) were monitored by interviews and consultations. Malaria prevalence was assessed by ultrasensitive PCR quarterly for 24 months. Symptomatic malaria incidence,entomological indices, and antimalarial resistance markers were monitored. Results: MDA was well tolerated. There were no serious AE and mild to moderate AE were reported in 5.6%(212/3931) interviews. In the smaller villages, participation to three MDA courses was 61% and 57%, compared to 28% and 29% in the larger villages. Baseline prevalence was higher in intervention than in control villages (18.7% (95%CI=16.1-21.6) versus 6.8%(5.2-8.7), p<0.0001) whereas three months after starting MDA, prevalence was lower in intervention villages (0.4%(0.04-1.3) versus 2.7%(1.7-4.1), p=0.0014). After nine months the difference was no longer significant (2.0%(1.0-3.5) versus 0.9%(0.04-1.8), p=0.10). M0-M9 symptomatic falciparum incidence was similar between intervention and control. Before/after MDA comparisons showed that asymptomatic P. falciparum carriage and anophel

Published

2017

30. Erratum: Association of genetic mutations in Plasmodium vivax dhfr with resistance to sulfadoxine-pyrimethamine: Geographical and clinical correlates (Antimicrobrial Agents and Chemotherapy (2001) 45:11 (3122-3127))

Author

Imwong, M, Pukrittayakamee, S, Looareesuwan, S, Pasvol, G, Poirriez, J, White, NJ, and Snounou, G

Published

2016

31. Characteristics and risk factors of Plasmodium falciparum malaria in Eastern and Central Nepal

Author

Banjara, MR, Sirawaraporn, W, Petmitr, S, Imwong, M, Joshi, AB, and Chavalitshewinkoon-Petmitr, P

Subjects

parasitic diseases

Abstract

BACKGROUND: Very limited information is available on epidemiology of falciparum malaria in Nepal. Such information is very important for malaria control programmes. It is believed that malaria in Eastern region is imported from border districts of India and local transmission follows whereas it is indigenous in Central region. Therefore, the characteristics and risk factors of malaria are believed to be different in Eastern and Central Nepal. OBJECTIVE: The objective of the study is to describe and compare the characteristics and risk factors of falciparum malaria in Eastern and Central Nepal. MATERIALS AND METHODS: This cross-sectional study was conducted in falciparum malaria endemic districts of Eastern and Central Nepal, during the period 2007 to 2008. We identified and collected information from 106 patients (62 from Eastern and 44 from Central region). Patient examination, clinical and laboratory assessment were done and patients were interviewed using structured questionnaire for malaria related characteristics, risk factors and behaviours. RESULTS: There were significant differences in risk factors and characteristics of falciparum malaria in the Central than the Eastern region. In the Central region, male, illiteracy and thatched roof hut were significant risk factors of falciparum malaria patients as compared to the Eastern region. Visits outside within three months, previous malaria within three months, taking antimalarial before confirmatory diagnosis were significantly higher in patients of the Eastern region as compared to the Central region. CONCLUSION: Falciparum malaria in Nepal should not be seen as similar entity, and different strategies for prevention and control is needed for its diverse characteristics and endemicity.

Published

2016

32. Increased Blood Levels of Phosphatidyl Serine-Microparticles in Patients With Essential Hypertension

Author

Nantakomol, D, Imwong, M, Mas-Oodi, S, Plabplueng, CD, Isarankura-Na-Ayudhya, C, Prachayasittikul, V, and Nuchnoi, P

Published

2016

33. Analysis of Plasmodium falciparum diversity in natural infections by deep sequencing

Author

Manske, M, Miotto, O, Campino, S, Auburn, S, Almagro-Garcia, J, Maslen, G, O'Brien, J, Djimde, A, Doumbo, O, Zongo, I, Ouedraogo, JB, Michon, P, Mueller, I, Siba, P, Nzila, A, Borrmann, S, Kiara, SM, Marsh, K, Jiang, H, Su, XZ, Amaratunga, C, Fairhurst, R, Socheat, D, Nosten, F, Imwong, M, White, NJ, Sanders, M, Anastasi, E, Alcock, D, Drury, E, Oyola, S, Quail, MA, Turner, DJ, Ruano-Rubio, V, Jyothi, D, Amenga-Etego, L, Hubbart, C, Jeffreys, A, Rowlands, K, Sutherland, C, Roper, C, Mangano, V, Modiano, D, Tan, JC, Ferdig, MT, Amambua-Ngwa, A, Conway, DJ, Takala-Harrison, S, Plowe, CV, Rayner, JC, Rockett, KA, Clark, TG, Newbold, CI, Berriman, M, MacInnis, B, and Kwiatkowski, DP

Subjects

Genotype, 030231 tropical medicine, Population, Plasmodium falciparum, Genomics, Biology, Polymorphism, Single Nucleotide, Deep sequencing, Article, 03 medical and health sciences, 0302 clinical medicine, parasitic diseases, Humans, Genetic variability, Malaria, Falciparum, education, Genotyping, Alleles, Phylogeny, 030304 developmental biology, Genetics, Whole genome sequencing, 0303 health sciences, Genetic diversity, education.field_of_study, Principal Component Analysis, Multidisciplinary, High-Throughput Nucleotide Sequencing, Biodiversity, biology.organism_classification, 3. Good health, Genome, Protozoan

Abstract

methods for the large-scale analysis of genetic variation in Plasmodium falciparum by deep sequencing of parasite DNA obtained from the blood of patients with malaria, either directly or after short-term culture. Analysis of 86,158 exonic single nucleotide polymorphisms that passed genotyping quality control in 227 samples from Africa, Asia and Oceania provides genomewide estimates of allele frequency distribution, population structure and linkage disequilibrium. By comparing the genetic diversity of individual infections with that of the local parasite population, we derive a metric of within-host diversity that is related to the level of inbreeding in the population. An open-access web application has been established for the exploration of regional differences in allele frequency and of highly differentiated loci in the P. falciparum genome. The genetic diversity and evolutionary plasticity of P. falciparum are major obstacles for malaria elimination. New forms of resistance against antimalarial drugs are continually emerging 1,2 , and new forms of antigenic variation are a critical point of vulnerability for future malaria vaccines. Effective tools are needed to detect evolutionary changes in the parasite population and to monitor the spread of genetic variants that affect malaria control. Here we describe the use of deep sequencing to analyse P. falciparum diversity, using blood samples from patients with malaria. The P. falciparum genome has several unusual features that greatly complicate sequence analysis, such as extreme AT bias, large tracts of nonunique sequence and several large families of intensely polymorphic genes 3 . Our aim was therefore not to determine the entire genome sequence of individual field samples—which would be prohibitively expensive with current technologies—but to define an initial set of single nucleotide polymorphisms (SNPs) distributed across the P. falciparum genome, whose genotype can be ascertained with confidence in parasitized blood samples by deep sequencing. An additional complication in the analysis of P. falciparum genome variation is that the billions of haploid parasites that infect a single individual can be a complex mixture of genetic types. Previous studies 4–8 have largely focused on laboratory-adapted parasite clones, but the within-host diversity of natural infections is of fundamental biological interest. Parasites in the blood replicate asexually, but when they are taken up in the blood meal of an Anopheles mosquito they undergo sexual mating. If the parasites in the blood are of diverse genetic types, this process of sexual mating can generate novel recombinant forms. Deep sequencing provides new ways of investigating within-host diversity and the role of sexual recombination in parasite evolution.

Published

2016

34. Association of genetic mutations in Plasmodium vivax dhfr with resistance to sulfadoxine-pyrimethamine: Geographical and clinical correlates (vol 45, pg 3122, 2001)

Author

Imwong, M, Pukrittayakamee, S, Looareesuwan, S, Pasvol, G, Poirriez, J, White, NJ, and Snounou, G

Published

2016

35. Drug resistance. Population transcriptomics of human malaria parasites reveals the mechanism of artemisinin resistance

Author

Mok, S, Ashley, E, Ferreira, P, Zhu, L, Lin, Z, Yeo, T, Chotivanich, K, Imwong, M, Pukrittayakamee, S, Dhorda, M, Nguon, C, Lim, P, Amaratunga, C, Suon, S, Hien, T, Htut, Y, Faiz, M, Onyamboko, M, Mayxay, M, Newton, P, Tripura, R, Woodrow, C, Miotto, O, Kwiatkowski, D, and Nosten, F

Abstract

Artemisinin resistance in Plasmodium falciparum threatens global efforts to control and eliminate malaria. Polymorphisms in the kelch domain-carrying protein K13 are associated with artemisinin resistance, but the underlying molecular mechanisms are unknown. We analyzed the in vivo transcriptomes of 1043 P. falciparum isolates from patients with acute malaria and found that artemisinin resistance is associated with increased expression of unfolded protein response (UPR) pathways involving the major PROSC and TRiC chaperone complexes. Artemisinin-resistant parasites also exhibit decelerated progression through the first part of the asexual intraerythrocytic development cycle. These findings suggest that artemisinin-resistant parasites remain in a state of decelerated development at the young ring stage, whereas their up-regulated UPR pathways mitigate protein damage caused by artemisinin. The expression profiles of UPR-related genes also associate with the geographical origin of parasite isolates, further suggesting their role in emerging artemisinin resistance in the Greater Mekong Subregion.

Published

2016

36. Factors associated with regional bias of pfcrt (plasmodium falciparum chloroquine resistance transporter) haplotypes in Nepal

Author

Banjara, MR, Imwong, M, Petmitr, S, Sirawaraporn, W, Joshi, AB, and Chavalitshewinkoon-Petmitr, P

Subjects

parasitic diseases

Abstract

Evidences of reappearance of chloroquine sensitive Plasmodium falciparum haplotypes after cessation of chloroquine in many countries provide a rationale for the search of chloroquine sensitive haplotypes in P. falciparum isolates in Nepal where the use of chloroquine for falciparum malaria treatment has been ceased since 1988. P. falciparum chloroquine resistant transporter gene (pfcrt) haplotypes were determined and the factors associated with pfcrt haplotypes in the Eastern and Central regions of Nepal were identified. Blood samples from 106 microscopy-positive falciparum malaria patients (62 from the Eastern and 44 from the Central region) were collected on filter paper. Pfcrt region covering codons 72-76 was amplified by PCR and sequenced. SVMNT haplotype was predominant in the Central region, whereas CVIET haplotype significantly more common in the Eastern region. In multivariable analysis of factors associated with CVIET haplotype, the Eastern region and parasite isolates from patients visiting India within one month are significant at 5% level of significance. These findings suggest that antimalarial pressure is different between Eastern and Central regions of Nepal and there is a need of an effective malaria control program in the border areas between India and Nepal.

Published

2016

37. Plasmodium vivax resistance to chloroquine in Dawei, southern Myanmar

Author

Guthmann, JP, Pittet, A, Lesage, A, Imwong, M, Lindegardh, N, Min Lwin, M, Zaw, T, Annerberg, A, de Radiguès, X, and Nosten, F

Subjects

parasitic diseases

Abstract

OBJECTIVE: To assess the efficacy of chloroquine in the treatment of Plasmodium vivax malaria in in Dawei District, southern Myanmar. METHODS: Enrolled patients at Sonsinphya clinic >6 months of age were assessed clinically and parasitologically every week for 28 days. To differentiate new infections from recrudescence, we genotyped pre- and post-treatment parasitaemia. Blood chloroquine was measured to confirm resistant strains. RESULTS: Between December 2002 and April 2003, 2661 patients were screened, of whom 252 were included and 235 analysed. Thirty-four per cent (95% CI: 28.1-40.6) of patients had recurrent parasitaemia and were considered treatment failures. 59.4% of these recurrences were with a different parasite strain. Two (0.8%) patients with recurrences on day 14 had chloroquine concentrations above the threshold of 100 ng/ml and were considered infected with chloroquine resistant parasites. 21% of failures occurred during the first 3 weeks of follow-up: early recurrence and median levels of blood chloroquine comparable to those of controls suggested P. vivax resistance. CONCLUSIONS: Plasmodium vivax resistance to chloroquine seems to be emerging in Dawei, near the Thai-Burmese border. While chloroquine remains the first-line drug for P. vivax infections in this area of Myanmar, regular monitoring is needed to detect further development of parasite resistance.

Published

2016

38. Artemisinin Resistance in Plasmodium falciparum Malaria (vol 361, pg 455, 2009)

Author

Dondorp, AM, Nosten, F, Yi, P, Das, D, Phyo, AP, Tarning, J, Lwin, KM, Ariey, F, Hanpithakong, W, Lee, SJ, Ringwald, P, Silamut, K, Imwong, M, Chotivanich, K, Lim, P, Herdman, T, An, SS, Yeung, S, Singhasivanon, P, Day, NPJ, Lindegardh, N, Socheat, D, and White, NJ

Published

2016

39. Drug resistance. Population transcriptomics of human malaria parasites reveals the mechanism of artemisinin resistance

Author

Mok, S, Ashley, EA, Ferreira, PE, Zhu, L, Lin, Z, Yeo, T, Chotivanich, K, Imwong, M, Pukrittayakamee, S, Dhorda, M, Nguon, C, Lim, P, Amaratunga, C, Suon, S, Hien, TT, Htut, Y, Faiz, MA, Onyamboko, MA, Mayxay, M, Newton, PN, Tripura, R, Woodrow, CJ, Miotto, O, Kwiatkowski, DP, Nosten, F, Day, NP, Preiser, PR, White, NJ, Dondorp, AM, Fairhurst, RM, and Bozdech, Z

Subjects

parasitic diseases

Abstract

Artemisinin resistance in Plasmodium falciparum threatens global efforts to control and eliminate malaria. Polymorphisms in the kelch domain-carrying protein K13 are associated with artemisinin resistance, but the underlying molecular mechanisms are unknown. We analyzed the in vivo transcriptomes of 1043 P. falciparum isolates from patients with acute malaria and found that artemisinin resistance is associated with increased expression of unfolded protein response (UPR) pathways involving the major PROSC and TRiC chaperone complexes. Artemisinin-resistant parasites also exhibit decelerated progression through the first part of the asexual intraerythrocytic development cycle. These findings suggest that artemisinin-resistant parasites remain in a state of decelerated development at the young ring stage, whereas their up-regulated UPR pathways mitigate protein damage caused by artemisinin. The expression profiles of UPR-related genes also associate with the geographical origin of parasite isolates, further suggesting their role in emerging artemisinin resistance in the Greater Mekong Subregion.

Published

2015

40. The numerical distributions of parasite densities in asymptomatic malaria

Author

White, N, Imwong, M, Stepniewska, K, Tripura, R, Peto, T, Lwin, K, Vihokhern, B, Wongsaen, K, von Seidlein, L, Dhorda, M, Snounou, G, Keereecharoen, L, Sirithiranont, P, Chalk, J, Nguon, C, Day, N, Nosten, F, Dondorp, A, and Singhasivanon, P

Subjects

parasitic diseases

Abstract

Background. Asymptomatic parasitemia is common even in areas of low seasonal malaria transmission, but the true proportion of the population infected has not been estimated previously because of the limited sensitivity of available detection methods. Methods. Cross-sectional malaria surveys were conducted in areas of low seasonal transmission on the Northwestern Thailand-Myanmar border and in Western Cambodia. Using an ultra- sensitive PCR DNA quantitation method (uPCR: limit of accurate detection 22 parasites/mL) parasite density distributions for Plasmodium falciparum and Plasmodium vivax were characterised and the proportions of undetected infections imputed. Results. The prevalence of asymptomatic malaria by uPCR was 19.9% (988 of 4,975 people tested). Both P. vivax and P. falciparum density distributions were unimodal and log normally distributed with modal values well within the quantifiable range. The estimated proportions of all parasitemic individuals identified by uPCR were over 70% for P. falciparum and over 85% for P. vivax. Predicted proportions overall were 83% P. vivax, 13% P. falciparum and 4% mixed. Geometric mean parasite densities were similar; P. vivax: 5,601/mL and P. falciparum: 5,158/mL. Conclusions. This uPCR method identified most infected individuals in malaria endemic areas. Malaria parasitemias persist in humans at levels which optimise the probability of generating transmissible gametocyte densities without causing illness.

Published

2015

41. History of malaria treatment as a predictor of subsequent subclinical parasitaemia: A cross-sectional survey and malaria case records from three villages in Pailin, western Cambodia

Author

Peto, T.J. (Thomas J.), Kloprogge, S.E. (Sabine E.), Tripura, R. (Rupam), Nguon, C. (Chea), Sanann, N. (Nou), Yok, S. (Sovann), Heng, C. (Chhouen), Promnarate, C. (Cholrawee), Chalk, J. (Jeremy), Song, N. (Ngak), Lee, S.J. (Sue), Lubell, Y. (Yoel), Dhorda, M. (Mehul), Imwong, M. (Mallika), White, N.J. (Nicholas J.), Von Seidlein, L. (Lorenz), Dondorp, A.M., Peto, T.J. (Thomas J.), Kloprogge, S.E. (Sabine E.), Tripura, R. (Rupam), Nguon, C. (Chea), Sanann, N. (Nou), Yok, S. (Sovann), Heng, C. (Chhouen), Promnarate, C. (Cholrawee), Chalk, J. (Jeremy), Song, N. (Ngak), Lee, S.J. (Sue), Lubell, Y. (Yoel), Dhorda, M. (Mehul), Imwong, M. (Mallika), White, N.J. (Nicholas J.), Von Seidlein, L. (Lorenz), and Dondorp, A.M.

Abstract

Background: Treatment of the sub-clinical reservoir of malaria, which may maintain transmission, could be an important component of elimination strategies. The reliable detection of asymptomatic infections with low levels of parasitaemia requires high-volume quantitative polymerase chain reaction (uPCR), which is impractical to conduct on a large scale. It is unknown to what extent sub-clinical parasitaemias originate from recent or older clinical episodes. This study explored the association between clinical history of malaria and subsequent sub-clinical parasitaemia. Methods: In June 2013 a cross-sectional survey was conducted in three villages in Pailin, western Cambodia. Demographic and epidemiological data and blood samples were collected. Blood was tested for malaria by high-volume qPC

Published

2016

42. Genomic epidemiology of artemisinin resistant malaria

Author

Amato, R., Miotto, O., Woodrow, C.J., Almagro-Garcia, J., Sinha, I., Campino, S., Mead, D., Drury, E., Kekre, M., Sanders, M., Amambua-Ngwa, A., Amaratunga, C., Amenga-Etego, L., Andrianaranjaka, V., Apinjoh, T., Ashley, E., Auburn, S., Awandare, G.A., Baraka, V., Barry, Alyssa, Boni, M.F., Borrmann, S., Bousema, T., Branch, O., Bull, P.C., Chotivanich, K., Conway, D.J., Craig, A., Day, N.P., Djimdé, A., Dolecek, C., Dondorp, A.M., Drakeley, C., Duffy, P., Echeverry, D.F., Egwang, T.G., Fairhurst, R.M., Faiz, A., Fanello, C.I., Hien, T.T., Hodgson, A., Imwong, M., Ishengoma, D., Lim, P., Lon, C., Marfurt, J., Marsh, K., Mayxay, M., Michon, P., Mobegi, V., Mokuolu, O.A., Montgomery, J., Mueller, I., Kyaw, M.P., Newton, P.N., Nosten, F., Noviyanti, R., Nzila, A., Ocholla, H., Oduro, A., Onyamboko, M., Ouedraogo, J.B., Phyo, A.P.P., Plowe, C., Price, R.N., Pukrittayakamee, S., Randrianarivelojosia, M., Ringwald, P., Ruiz, L., Saunders, D., Shayo, A., Siba, P., Takala-Harrison, S., Thanh, T.N.N., Thathy, V., Verra, F., Wendler, J., White, N.J., Ye, H., Cornelius, V.J., Giacomantonio, R., Muddyman, D., Henrichs, C., Malangone, C., Jyothi, D., Pearson, R.D., Rayner, J.C., McVean, G., Rockett, K.A., Miles, A., Vauterin, P., Jeffery, B., Manske, M., Stalker, J., Macinnis, B., Kwiatkowski, D.P., Amato, R., Miotto, O., Woodrow, C.J., Almagro-Garcia, J., Sinha, I., Campino, S., Mead, D., Drury, E., Kekre, M., Sanders, M., Amambua-Ngwa, A., Amaratunga, C., Amenga-Etego, L., Andrianaranjaka, V., Apinjoh, T., Ashley, E., Auburn, S., Awandare, G.A., Baraka, V., Barry, Alyssa, Boni, M.F., Borrmann, S., Bousema, T., Branch, O., Bull, P.C., Chotivanich, K., Conway, D.J., Craig, A., Day, N.P., Djimdé, A., Dolecek, C., Dondorp, A.M., Drakeley, C., Duffy, P., Echeverry, D.F., Egwang, T.G., Fairhurst, R.M., Faiz, A., Fanello, C.I., Hien, T.T., Hodgson, A., Imwong, M., Ishengoma, D., Lim, P., Lon, C., Marfurt, J., Marsh, K., Mayxay, M., Michon, P., Mobegi, V., Mokuolu, O.A., Montgomery, J., Mueller, I., Kyaw, M.P., Newton, P.N., Nosten, F., Noviyanti, R., Nzila, A., Ocholla, H., Oduro, A., Onyamboko, M., Ouedraogo, J.B., Phyo, A.P.P., Plowe, C., Price, R.N., Pukrittayakamee, S., Randrianarivelojosia, M., Ringwald, P., Ruiz, L., Saunders, D., Shayo, A., Siba, P., Takala-Harrison, S., Thanh, T.N.N., Thathy, V., Verra, F., Wendler, J., White, N.J., Ye, H., Cornelius, V.J., Giacomantonio, R., Muddyman, D., Henrichs, C., Malangone, C., Jyothi, D., Pearson, R.D., Rayner, J.C., McVean, G., Rockett, K.A., Miles, A., Vauterin, P., Jeffery, B., Manske, M., Stalker, J., Macinnis, B., and Kwiatkowski, D.P.

Published

2016

43. Genomic epidemiology of artemisinin resistant malaria

Author

Amato, R, Miotto, O, Woodrow, CJ, Almagro-Garcia, J, Sinha, I, Campino, S, Mead, D, Drury, E, Kekre, M, Sanders, M, Amambua-Ngwa, A, Amaratunga, C, Amenga-Etego, L, Andrianaranjaka, V, Apinjoh, T, Ashley, E, Auburn, S, Awandare, GA, Baraka, V, Barry, A, Boni, MF, Borrmann, S, Bousema, T, Branch, O, Bull, PC, Chotivanich, K, Conway, DJ, Craig, A, Day, NP, Djimde, A, Dolecek, C, Dondorp, AM, Drakeley, C, Duffy, P, Echeverry, DF, Egwang, TG, Fairhurst, RM, Faiz, MA, Fanello, CI, Tran, TH, Hodgson, A, Imwong, M, Ishengoma, D, Lim, P, Lon, C, Marfurt, J, Marsh, K, Mayxay, M, Michon, P, Mobegi, V, Mokuolu, OA, Montgomery, J, Mueller, I, Kyaw, MP, Newton, PN, Nosten, F, Noviyanti, R, Nzila, A, Ocholla, H, Oduro, A, Onyamboko, M, Ouedraogo, J-B, Phyo, APP, Plowe, C, Price, RN, Pukrittayakamee, S, Randrianarivelojosia, M, Ringwald, P, Ruiz, L, Saunders, D, Shayo, A, Siba, P, Takala-Harrison, S, Thanh, T-NN, Thathy, V, Verra, F, Wendler, J, White, NJ, Ye, H, Cornelius, VJ, Giacomantonio, R, Muddyman, D, Henrichs, C, Malangone, C, Jyothi, D, Pearson, RD, Rayner, JC, McVean, G, Rockett, KA, Miles, A, Vauterin, P, Jeffery, B, Manske, M, Stalker, J, Maclnnis, B, Kwiatkowski, DP, Amato, R, Miotto, O, Woodrow, CJ, Almagro-Garcia, J, Sinha, I, Campino, S, Mead, D, Drury, E, Kekre, M, Sanders, M, Amambua-Ngwa, A, Amaratunga, C, Amenga-Etego, L, Andrianaranjaka, V, Apinjoh, T, Ashley, E, Auburn, S, Awandare, GA, Baraka, V, Barry, A, Boni, MF, Borrmann, S, Bousema, T, Branch, O, Bull, PC, Chotivanich, K, Conway, DJ, Craig, A, Day, NP, Djimde, A, Dolecek, C, Dondorp, AM, Drakeley, C, Duffy, P, Echeverry, DF, Egwang, TG, Fairhurst, RM, Faiz, MA, Fanello, CI, Tran, TH, Hodgson, A, Imwong, M, Ishengoma, D, Lim, P, Lon, C, Marfurt, J, Marsh, K, Mayxay, M, Michon, P, Mobegi, V, Mokuolu, OA, Montgomery, J, Mueller, I, Kyaw, MP, Newton, PN, Nosten, F, Noviyanti, R, Nzila, A, Ocholla, H, Oduro, A, Onyamboko, M, Ouedraogo, J-B, Phyo, APP, Plowe, C, Price, RN, Pukrittayakamee, S, Randrianarivelojosia, M, Ringwald, P, Ruiz, L, Saunders, D, Shayo, A, Siba, P, Takala-Harrison, S, Thanh, T-NN, Thathy, V, Verra, F, Wendler, J, White, NJ, Ye, H, Cornelius, VJ, Giacomantonio, R, Muddyman, D, Henrichs, C, Malangone, C, Jyothi, D, Pearson, RD, Rayner, JC, McVean, G, Rockett, KA, Miles, A, Vauterin, P, Jeffery, B, Manske, M, Stalker, J, Maclnnis, B, and Kwiatkowski, DP

Abstract

The current epidemic of artemisinin resistant Plasmodium falciparum in Southeast Asia is the result of a soft selective sweep involving at least 20 independent kelch13 mutations. In a large global survey, we find that kelch13 mutations which cause resistance in Southeast Asia are present at low frequency in Africa. We show that African kelch13 mutations have originated locally, and that kelch13 shows a normal variation pattern relative to other genes in Africa, whereas in Southeast Asia there is a great excess of non-synonymous mutations, many of which cause radical amino-acid changes. Thus, kelch13 is not currently undergoing strong selection in Africa, despite a deep reservoir of variations that could potentially allow resistance to emerge rapidly. The practical implications are that public health surveillance for artemisinin resistance should not rely on kelch13 data alone, and interventions to prevent resistance must account for local evolutionary conditions, shown by genomic epidemiology to differ greatly between geographical regions.

Published

2016

44. Optimal health and disease management using spatial uncertainty: a geographic characterization of emergent artemisinin-resistant Plasmodium falciparum distributions in Southeast Asia

Author

Grist, EPM, Flegg, JA, Humphreys, G, Mas, IS, Anderson, TJC, Ashley, EA, Day, NPJ, Dhorda, M, Dondorp, AM, Abul Faiz, M, Gething, PW, Hien, TT, Hlaing, TM, Imwong, M, Kindermans, J-M, Maude, RJ, Mayxay, M, McDew-White, M, Menard, D, Nair, S, Nosten, F, Newton, PN, Price, RN, Pukrittayakamee, S, Takala-Harrison, S, Smithuis, F, Nguyen, NT, Tun, KM, White, NJ, Witkowski, B, Woodrow, CJ, Fairhurst, RM, Sibley, CH, Guerin, PJ, Grist, EPM, Flegg, JA, Humphreys, G, Mas, IS, Anderson, TJC, Ashley, EA, Day, NPJ, Dhorda, M, Dondorp, AM, Abul Faiz, M, Gething, PW, Hien, TT, Hlaing, TM, Imwong, M, Kindermans, J-M, Maude, RJ, Mayxay, M, McDew-White, M, Menard, D, Nair, S, Nosten, F, Newton, PN, Price, RN, Pukrittayakamee, S, Takala-Harrison, S, Smithuis, F, Nguyen, NT, Tun, KM, White, NJ, Witkowski, B, Woodrow, CJ, Fairhurst, RM, Sibley, CH, and Guerin, PJ

Abstract

BACKGROUND: Artemisinin-resistant Plasmodium falciparum malaria parasites are now present across much of mainland Southeast Asia, where ongoing surveys are measuring and mapping their spatial distribution. These efforts require substantial resources. Here we propose a generic 'smart surveillance' methodology to identify optimal candidate sites for future sampling and thus map the distribution of artemisinin resistance most efficiently. METHODS: The approach uses the 'uncertainty' map generated iteratively by a geostatistical model to determine optimal locations for subsequent sampling. RESULTS: The methodology is illustrated using recent data on the prevalence of the K13-propeller polymorphism (a genetic marker of artemisinin resistance) in the Greater Mekong Subregion. CONCLUSION: This methodology, which has broader application to geostatistical mapping in general, could improve the quality and efficiency of drug resistance mapping and thereby guide practical operations to eliminate malaria in affected areas.

Published

2016

45. Assessment of therapeutic responses to gametocytocidal drugs in Plasmodium falciparum malaria.

Author

White, N.J., Ashley, E.A., Recht, J., Delves, M.J., Ruecker, A., Smithuis, F.M., Eziefula, A.C., Bousema, T., Drakeley, C., Chotivanich, K., Imwong, M., Pukrittayakamee, S., Prachumsri, J., Chu, C., Andolina, C., Bancone, G., Hien, T.T., Mayxay, M., Taylor, W.R., Seidlein, L. von, Price, R.N., Barnes, K.I., Djimdé, A., Kuile, F. ter, Gosling, R., Chen, I., Dhorda, M.J., Stepniewska, K., Guérin, P., Woodrow, C.J., Dondorp, A.M., Day, N.P., Nosten, F.H., White, N.J., Ashley, E.A., Recht, J., Delves, M.J., Ruecker, A., Smithuis, F.M., Eziefula, A.C., Bousema, T., Drakeley, C., Chotivanich, K., Imwong, M., Pukrittayakamee, S., Prachumsri, J., Chu, C., Andolina, C., Bancone, G., Hien, T.T., Mayxay, M., Taylor, W.R., Seidlein, L. von, Price, R.N., Barnes, K.I., Djimdé, A., Kuile, F. ter, Gosling, R., Chen, I., Dhorda, M.J., Stepniewska, K., Guérin, P., Woodrow, C.J., Dondorp, A.M., Day, N.P., and Nosten, F.H.

Abstract

Contains fulltext : 154582.pdf (publisher's version ) (Open Access)

Published

2015

46. Intervals to Plasmodium falciparum recurrence after anti-malarial treatment in pregnancy: a longitudinal prospective cohort

Author

Laochan, N, Zaloumis, SG, Imwong, M, Lek-Uthai, U, Brockman, A, Sriprawat, K, Wiladphaingern, J, White, NJ, Nosten, F, McGready, R, Laochan, N, Zaloumis, SG, Imwong, M, Lek-Uthai, U, Brockman, A, Sriprawat, K, Wiladphaingern, J, White, NJ, Nosten, F, and McGready, R

Abstract

BACKGROUND: Plasmodium falciparum infections adversely affect pregnancy. Anti-malarial treatment failure is common. The objective of this study was to examine the duration of persistent parasite carriage following anti-malarial treatment in pregnancy. METHODS: The data presented here are a collation from previous studies carried out since 1994 in the Shoklo Malaria Research Unit (SMRU) on the Thailand-Myanmar border and performed using the same unique methodology detailed in the Materials and Methods section. Screening for malaria by microscopy is a routine part of weekly antenatal care (ANC) visits and therapeutic responses to anti-malarials were assessed in P. falciparum malaria cases. Women with microscopy confirmed P. falciparum malaria had a PCR blood spot from a finger-prick sample collected. Parasite DNA was extracted from the blood-spot samples using saponin lysis/Chelex extraction method and genotyped using polymorphic segments of MSP1, MSP2 and GLURP. Recurrent infections were classified by genotyping as novel, recrudescent or indeterminate. Factors associated with time to microscopy-detected recrudescence were analysed using multivariable regression techniques. RESULTS: From December 1994 to November 2009, 700 women were treated for P. falciparum and there were 909 recurrent episodes (481 novel and 428 recrudescent) confirmed by PCR genotyping. Most of the recurrences, 85% (770/909), occurred after treatment with quinine monotherapy, artesunate monotherapy or artesunate-clindamycin. The geometric mean number of days to recurrence was significantly shorter in women with recrudescent infection, 24.5 (95%: 23.4-25.8), compared to re-infection, 49.7 (95%: 46.9-52.7), P<0.001. The proportion of recrudescent P. falciparum infections that occurred after days 28, 42 and 63 from the start of treatment was 29.1% (124/428), 13.3% (57/428) and 5.6% (24/428). Recrudescent infections≥100 days after treatment occurred with quinine and mefloquine monotherapy, and quinine

Published

2015

47. Plasma concentration of parasite DNA as a measure of disease severity in falciparum malaria

Author

Imwong, M., Woodrow, C., Hendriksen, I.C.E., Veenemans, J., Verhoef, J.C.M., Imwong, M., Woodrow, C., Hendriksen, I.C.E., Veenemans, J., and Verhoef, J.C.M.

Abstract

In endemic areas malaria parasitemia is common in apparently healthy children and severe malaria is commonly misdiagnosed in patients with incidental parasitemia. We assessed the performance of plasma P. falciparum DNA concentration measurement in distinguishing uncomplicated from severe malaria in African children and Asian adults. P. falciparum DNA concentrations were measured by real-time PCR in 224 African children (111 uncomplicated, 113 severe) and 211 Asian adults (100 uncomplicated, 111 severe) presenting with acute falciparum malaria. The diagnostic accuracy of plasma PfDNA concentrations in identifying severe malaria was 0.834 in children and 0.788 in adults, similar to that of plasma PfHRP2, and substantially superior to parasite density (p

Published

2015

48. OPTIMIZING THE CULTURE OF PLASMODIUM FALCIPARUM IN HOLLOW FIBER BIOREACTORS

Author

Preechapornkul, P., Chotivanich, K., Imwong, M., Dondorp, A. M., Lee, S. J., Day, N. P. J., Nicholas White, and Pukrittayakamee, S.

Subjects

Bioreactors, Plasmodium falciparum, Cell Culture Techniques, Article, Culture Media

Abstract

The hollow fiber bioreactor (HFBR) is a cell culturing system allowing continuous perfusion of medium. It was designed to grow microorganisms in a dynamically altering medium mimicking change in the in vivo intravascular and extravascular compartments. The cell compartment (extra capillary space) and medium compartment (intra capillary space) are connected through pores of semipermeable fiber membranes. These membranes allow exchange of gas and nutrients. We have adapted this system for the ex vivo culture of Plasmodiumfalciparum at high parasite densities. A Thai P. falciparum isolate (TM036) cultured in RPMI, supplemented with 0.5% Albumax II, could be maintained continuously in the system by daily changes of a small volumes of medium. Under optimized conditions the HFBR cultures attained 8% parasitemia in 40% hematocrit, thereby providing a total parasite biomass of 6.0 x 10(9) parasitized erythrocytes. The main problem encountered was clogging of micropores in the hollow fiber system by cellular debris over time. Although 'reverse flushing' partly prevented this, a larger pore size might be needed to overcome this problem. The system opens new possibilities for the study of in vitro drug sensitivity under conditions mimicking in vivo pharmacokinetics, and the selection of anti-malarial drug resistance and associated parasite biological and genomic changes.

Published

2010

49. Analysis of Plasmodium falciparum diversity in natural infections by deep sequencing

Author

Manske, M, Miotto, O, Campino, S, Auburn, S, Almagro-Garcia, J, Maslen, G, O'Brien, J, Djimde, A, Doumbo, O, Zongo, I, Ouedraogo, J-B, Michon, P, Mueller, I, Siba, P, Nzila, A, Borrmann, S, Kiara, SM, Marsh, K, Jiang, H, Su, X-Z, Amaratunga, C, Fairhurst, R, Socheat, D, Nosten, F, Imwong, M, White, NJ, Sanders, M, Anastasi, E, Alcock, D, Drury, E, Oyola, S, Quail, MA, Turner, DJ, Ruano-Rubio, V, Jyothi, D, Amenga-Etego, L, Hubbart, C, Jeffreys, A, Rowlands, K, Sutherland, C, Roper, C, Mangano, V, Modiano, D, Tan, JC, Ferdig, MT, Amambua-Ngwa, A, Conway, DJ, Takala-Harrison, S, Plowe, CV, Rayner, JC, Rockett, KA, Clark, TG, Newbold, CI, Berriman, M, MacInnis, B, Kwiatkowski, DP, Manske, M, Miotto, O, Campino, S, Auburn, S, Almagro-Garcia, J, Maslen, G, O'Brien, J, Djimde, A, Doumbo, O, Zongo, I, Ouedraogo, J-B, Michon, P, Mueller, I, Siba, P, Nzila, A, Borrmann, S, Kiara, SM, Marsh, K, Jiang, H, Su, X-Z, Amaratunga, C, Fairhurst, R, Socheat, D, Nosten, F, Imwong, M, White, NJ, Sanders, M, Anastasi, E, Alcock, D, Drury, E, Oyola, S, Quail, MA, Turner, DJ, Ruano-Rubio, V, Jyothi, D, Amenga-Etego, L, Hubbart, C, Jeffreys, A, Rowlands, K, Sutherland, C, Roper, C, Mangano, V, Modiano, D, Tan, JC, Ferdig, MT, Amambua-Ngwa, A, Conway, DJ, Takala-Harrison, S, Plowe, CV, Rayner, JC, Rockett, KA, Clark, TG, Newbold, CI, Berriman, M, MacInnis, B, and Kwiatkowski, DP

Abstract

Malaria elimination strategies require surveillance of the parasite population for genetic changes that demand a public health response, such as new forms of drug resistance. Here we describe methods for the large-scale analysis of genetic variation in Plasmodium falciparum by deep sequencing of parasite DNA obtained from the blood of patients with malaria, either directly or after short-term culture. Analysis of 86,158 exonic single nucleotide polymorphisms that passed genotyping quality control in 227 samples from Africa, Asia and Oceania provides genome-wide estimates of allele frequency distribution, population structure and linkage disequilibrium. By comparing the genetic diversity of individual infections with that of the local parasite population, we derive a metric of within-host diversity that is related to the level of inbreeding in the population. An open-access web application has been established for the exploration of regional differences in allele frequency and of highly differentiated loci in the P. falciparum genome.

Published

2012

50. Population Genetic Analysis of Plasmodium falciparum Parasites Using a Customized Illumina GoldenGate Genotyping Assay

Author

Fitzgerald, JR, Campino, S, Auburn, S, Kivinen, K, Zongo, I, Ouedraogo, J-B, Mangano, V, Djimde, A, Doumbo, OK, Kiara, SM, Nzila, A, Borrmann, S, Marsh, K, Michon, P, Mueller, I, Siba, P, Jiang, H, Su, X-Z, Amaratunga, C, Socheat, D, Fairhurst, RM, Imwong, M, Anderson, T, Nosten, F, White, NJ, Gwilliam, R, Deloukas, P, MacInnis, B, Newbold, CI, Rockett, K, Clark, TG, Kwiatkowski, DP, Fitzgerald, JR, Campino, S, Auburn, S, Kivinen, K, Zongo, I, Ouedraogo, J-B, Mangano, V, Djimde, A, Doumbo, OK, Kiara, SM, Nzila, A, Borrmann, S, Marsh, K, Michon, P, Mueller, I, Siba, P, Jiang, H, Su, X-Z, Amaratunga, C, Socheat, D, Fairhurst, RM, Imwong, M, Anderson, T, Nosten, F, White, NJ, Gwilliam, R, Deloukas, P, MacInnis, B, Newbold, CI, Rockett, K, Clark, TG, and Kwiatkowski, DP

Abstract

The diversity in the Plasmodium falciparum genome can be used to explore parasite population dynamics, with practical applications to malaria control. The ability to identify the geographic origin and trace the migratory patterns of parasites with clinically important phenotypes such as drug resistance is particularly relevant. With increasing single-nucleotide polymorphism (SNP) discovery from ongoing Plasmodium genome sequencing projects, a demand for high SNP and sample throughput genotyping platforms for large-scale population genetic studies is required. Low parasitaemias and multiple clone infections present a number of challenges to genotyping P. falciparum. We addressed some of these issues using a custom 384-SNP Illumina GoldenGate assay on P. falciparum DNA from laboratory clones (long-term cultured adapted parasite clones), short-term cultured parasite isolates and clinical (non-cultured isolates) samples from East and West Africa, Southeast Asia and Oceania. Eighty percent of the SNPs (n = 306) produced reliable genotype calls on samples containing as little as 2 ng of total genomic DNA and on whole genome amplified DNA. Analysis of artificial mixtures of laboratory clones demonstrated high genotype calling specificity and moderate sensitivity to call minor frequency alleles. Clear resolution of geographically distinct populations was demonstrated using Principal Components Analysis (PCA), and global patterns of population genetic diversity were consistent with previous reports. These results validate the utility of the platform in performing population genetic studies of P. falciparum.

Published

2011