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Malaria Journal

, 18:176 | Cite as

A cluster of the first reported Plasmodium ovale spp. infections in Peru occuring among returning UN peace-keepers, a review of epidemiology, prevention and diagnostic challenges in nonendemic regions

  • Rosio I. Guerra
  • Marianela Ore
  • Hugo O. Valdivia
  • Danett K. Bishop
  • Mariana Ramos
  • Christopher N. Mores
  • Wesley R. CampbellEmail author
Open Access
Case report

Abstract

Background

Plasmodium ovale curtisi and Plasmodium ovale wallikeri are regarded as less virulent forms of malaria with a geographic distribution including Southeast Asia, Central and West Africa, and is increasingly reported as an infection in returning travellers. A species of malaria that may have delayed or relapsing presentations similar to Plasmodium vivax, the clinical presentation of P. ovale spp. has been described to have prepatent periods of 2 weeks or slightly longer with reports of relapse following primary infection out to 8–9 months. This presentation may be obscured further in the setting of anti-malarial exposure, with report of delayed primary infection out to 4 years. Presented is a cluster of 4 imported P. ovale spp. cases in returning Peruvian military personnel assigned to United Nations peace-keeping operations in the Central African Republic.

Case presentation

From January to December 2016, Peruvian peace-keepers were deployed in support of United Nations (UN) operations in the Central African Republic (CAR). While serving abroad, Navy, Army, and Air Force members experienced 223 episodes of Plasmodium falciparum malaria following interruption of prophylaxis with mefloquine. Diagnosis was made using rapid diagnostics tests (RDTs) and/or smear with no coinfections identified. Cases of malaria were treated with locally-procured artemether-lumefantrine. Returning to Peru in January 2017, 200 peace-keepers were screened via thick and thin smear while on weekly mefloquine prophylaxis with only 1 showing nucleic acid within red blood cells consistent with Plasmodium spp. and 11 reporting syndromes of ill-defined somatic complaints. Between a period of 5 days to 11 months post return, 4 cases of P. ovale spp. were diagnosed using smear and polymerase chain reaction (PCR) following febrile complaints. All cases were subsequently treated with chloroquine and primaquine, with cure of clinical disease and documented clearance of parasitaemia.

Conclusion

These patients represent the first imported cases in Peru of this species of malaria as well as highlight the challenges in implementing population level prophylaxis in a deployed environment, and the steps for timely diagnosis and management in a non-endemic region where risk of introduction for local transmission exists.

Keywords

Plasmodium ovale Relapse Traveler Malaria Non-falciparum malaria 

Abbreviations

NFM

non falciparum malaria

CAR

Central African Republic

UK

United Kingdom

UN

United Nations

RDT

rapid diagnostic test

Background

Plasmodium ovale curtisi and P. ovale wallikeri are two non-falciparum malaria (NFM) disease-causing sympatric species endemic to areas in Southeast Asia and particularly in Central and West Africa [1, 2]. A recent systematic review of P. ovale spp. infection describes only 18 cases of reported relapse of P. ovale spp., 22 reported serious cases, and 5 related deaths in the published literature [3]. Severe cases and mortality are rare, with symptoms of fever occurring when parasitaemia exceeds 800 parasites/µl in populations with endemic circulation [3, 4, 5, 6]. Imported cases of this species outside of endemic regions are rare, and the true burden of P. ovale spp. disease among residents of endemic areas and among international travellers remains incompletely described.

Reported here are the first imported cases of P. ovale spp. in Peru presenting 5 days to 11 months after departure from the Central African Republic (CAR). These cases and the circumstances surrounding the clinical presentation demonstrate the known relapse window for P. ovale spp. and highlights the difficulties inherent to assessing risk of transmission to large groups of travellers when making prophylaxis decisions, and the role of diagnostic modalities upon return to permit timely diagnosis and definitive management.

Case presentation

From January to December 2016, Peruvian forces deployed for 12 months in support of United Nations (UN) peace-keeping operations in the CAR. These forces experienced an outbreak of 223 episodes of malaria attributed to Plasmodium falciparum following an interruption in mefloquine prophylaxis. The diagnoses were made in symptomatic individuals using microscopy and locally procured rapid diagnostic tests (RDTs); there were no identified coinfections, and cases were treated with artemether-lumefantrine. In December 2016, prior to return to Peru, deployed personnel received a final month of prophylaxis with weekly dosed mefloquine.

In January 2017, 200 Peruvian peacekeepers underwent thick and thin smear assessment in Lima. Nucleic acid staining within red blood cells was visualized in only one smear. Among the tested personnel, 11 reported non-specific febrile symptoms, with an additional 4 complaining of headache without fever. Personnel were recommended to delay returning to their normal duties at outposts in the Amazon basin while close clinical follow-up and evaluation could be conducted.

In April 2017, one of the peacekeepers who originally presented with vague complaints and who remained in Lima was diagnosed with P. ovale spp. infection on microscopy (Fig. 1a) with a parasitaemia of 778 parasites/µl. He was treated with chloroquine 250 mg daily for 3 days and provided primaquine radical cure dosed at 30 mg (base) daily for 14 days. In November 2017, an additional 3 cases were identified after complaints of fever prompted assessment with microscopy (Table 1). All 4 cases responded to therapy with resolution of symptoms and no evidence of recrudescent malaria on follow-up microscopy.
Fig. 1

Giemsa thin smear of the PCR confirmed cases: a MIS2709 sample (patient 1), ×100 schizont with an estimated 10 merozoites with fimbriation, normal to slightly enlarged red blood cell, consistent with P. ovale spp. b MIS2712 sample (patient 2), ×100 trophozoite with large chromatin dot

Table 1

Plasmodium ovale spp. cases

Patient

Service

Age

Episodes P. falciparum (+) in CAR

Primary treatment regimen

Delay in presentation (months)

Presenting complaint

Lab abnormalities

Parasitemia (parasites/µl)

Diagnosis

Treatment regimen

1a

Navy

44

1

Artemether 80 mg lumefantrine 480 mg

< 1

BP; (F, HA, GF)a

None

778

PCR microscopy

Chloroquine 250 mg primaquine 30 mg (14 days)

2b

Army

38

1

Artemether 80 mg lumefantrine 480 mg

11

F, HA, M, A

Th, Tr, IHB

27,339

PCR microscopy

Chloroquine 250 mg primaquine 30 mg (7 days)

3

Army

44

1

Artemether 80 mg lumefantrine 480 mg

11

F, HA, M

Th, Tr, IHB

433

Microscopy

Chloroquine 250 mg primaquine 30 mg (7 days)

4

Army

50

2

Artemether 80 mg lumefantrine 480 mg

11

F, HA, GF, T

Tr

481

Microscopy

Chloroquine 250 mg primaquine 30 mg (7 days)

Delayed presentation time in months from date of return to Peru to seeking care

CAR Central Africa Republic, PCR polymerase chain reaction, BP back pain, F fever, HA headache, M myalgia, A arthralgia, GF general fatigue, T thoracic pain, Th thrombocytopenia, Tr transaminitis, IHB indirect hyperbilirubinemia

aPatient with P. ovale. curtisi, originally presented with BP 5 days after returning from CAR, symptoms then continued intermittently until April 2017 when diagnosis was made after 2 weeks HA, at 3½ months was admitted with F, BP, M

bPatient with P. ovale. wallikeri (MIS2712)

DNA was successfully extracted using established methods from two out of the four cases and used for molecular testing [7, 8]. Plasmodium ovale spp. was confirmed for one of the samples by a ≈ 787 bp species-specific band whereas another sample returned positive for Plasmodium spp. by a ≈ 1200 bp genus-specific band (Fig. 2). In order to verify the PCR results and confirm the species in the genus positive sample, sequence analysis on the genus PCR product was completed (Fig. 2). The resulting maximum likelihood phylogenetic tree showed that one sample (MIS2595) was phylogenetically related to P. ovale curtisi whereas the other (MIS2712) was related to P. ovale wallikeri (Fig. 3) [9]. These results were further confirmed following this initial analysis using P. ovale spp. specific PCR [10].
Fig. 2

The figure shows the nested species-specific PCR for P. ovale. Lanes 1–4 correspond to the P. vivax reaction, lanes 5–8 correspond to the P. falciparum reaction and lanes 9–12 correspond to the P. ovale specific reaction. P. ovale was detected on MIS2595, whereas MIS2712 was only positive for Plasmodium spp. (≈ 1200 bp). We later determined via sequencing that MIS2712 was P. ovale wallikeri which is not detected by the PCR method we employed here

Fig. 3

Maximum likelihood phylogenetic tree of the small subunit ribosomal RNA sequence. The tree shows that MIS2595 is phylogenetically related to P. ovale curtisi strains whereas MIS2712 is related to P. ovale wallikeri. The tree was rooted with the P. falciparum 3D7 sequence which show 100% bootstrap support for the P. ovale curtisi and P. ovale wallikeri nodes

Discussion and conclusions

Plasmodium ovale spp. has historically been described as endemic to sub-Saharan and West Africa and Asia and clinically as a less severe form of malaria with lower parasite density [1]. With a prepatent period estimated at 15 days, a reported delayed primary infection presentation on the order of years, and possessing the ability for relapse, this species of malaria can be cause for difficult diagnosis and management for larger groups who travel and for clinicians in non-endemic regions [3, 11]. The context behind this cluster of cases raises these and other questions including just how much of a contribution this species makes to reported imported cases of malaria in South America, how best to prevent infection with prophylaxis, and ultimately is there a risk for introduction of this species and autochthonous spread in the correct setting.

The gold standard for diagnosis and correlation of parasitaemia to presentation remains visualization on microscopy [12]. Although P. ovale spp. may be diagnosed with microscopy and species confirmed with PCR, P. ovale spp. may be confused for Plasmodium vivax, making the diagnostic approach balanced to the resources available, the patient or population affected, and the expertise of the lab assisting in confirming diagnosis [13, 14, 15, 16]. RDTs are less sensitive for detection and rely on aldolase or pLDH antigen to detect NFM. Performance of RDTs for NFM is consistently below 90% sensitivity, with correct identification ranging between 28.3 and 35.6% [16, 17]. Overall, the sensitivity of available diagnostic tests for NFM is noted to be lowest for RDTs, increased with microscopy, and the highest with PCR [17].

The role of PCR in regions where a species may be non-endemic has been recognized as a valuable tool for confirming or making a diagnosis. One reference laboratory-based study in Israel reported a low rate of 11% correct diagnosis for P. ovale spp. with smear or RDTs and demonstrated the value of PCR technology [18]. In a similar population to these cases, universal PCR screening has been instituted by Guatemalan forces following a documented case of P. ovale spp. in a returning UN peace-keeper [13]. The detection limits of P. ovale spp. PCR can be as low as 1 parasite/µl of blood depending on the target and type PCR of method, and despite being time consuming is useful in aiding diagnosis in smear or RDT negative cases [18, 19]. When used as a tool in epidemiological evaluation for control, PCR as a diagnostic tool has been critical when exploring the suspected reemergence of P. vivax in an area of prior eradication, only to be identified as Plasmodium simium cases [20].

Treatment of P. ovale spp. is largely based on experience from P. vivax, with the role of primaquine in radical cure not as elucidated for this species. The mechanism of P. ovale spp. relapse is a matter of recent debate in the literature, and the parallels with P. vivax with regard to latent sporozoite activation or a form of merozoite development having not been clearly described [21]. Periods between primary infection and periods of clinical illness or relapse may be on the order of years and add to the clinical complexity of making the diagnosis [11]. Treatment is further complicated by uncertainty regarding the dosing of primaquine for P. ovale spp., with variation in practice based on regional experience and courses ranging from 7 to 14 days, weight-based recommendations ranging from 0.25 to 0.5 mg of base/kg/day, and dosing dependent on interpretation of base for salt components [22, 23]. Peruvian treatment experience and guidelines for P. vivax support a 7-day course of primaquine dosed at 0.5 mg base/kg/day [24]. These cases were managed as described in Table 1, with primaquine dosing and course at 7–14 days, matching recommendations of either U.S. Centers for Disease Control (CDC) and local Peruvian guidelines for P. vivax [25].

The contribution of P. ovale spp. to the burden of malaria in Africa is estimated as high as 10%, commonly in the background of mixed infection with P. falciparum, to as low as 2.5% in asymptomatic cross-sectional assessments in one 20-year longitudinal study [4]. Concerning the risk of P. ovale spp. emerging following or being missed by control measures for P. falciparum, Roucher et al. [4] demonstrated a near-absence of P. ovale spp. following the introduction of general malaria control measures when switching from chloroquine to amodiaquine and sulfadoxine/pyrimethamine in Senegal. The absence of the Duffy antigen group in South and West African populations, considered to be somewhat protective for P. vivax infection and modulate clinically apparent disease based on recent evidence [26, 27, 28], is not protective for infection with P. ovale spp. [1]. Evidence suggests that P. ovale spp. inoculation induces the rapid acquisition of immunity and that asymptomatic relapses are likely to occur [4, 5, 6] True relapses have been rarely reported, making delayed primary presentation in the setting of exposure to anti-malarials a likely scenario for our cluster of cases [1, 3].

Peruvian personnel have supported international UN peacekeeping missions since 2004, with deployments to Haiti as well as the CAR. Increasingly, P. ovale spp. is recognized as a cause of fever due to malaria in returning travellers to areas around the world. Researchers in Spain identified 102 cases imported between 2005 and 2011 in a multi-centre retrospective review, ranging between 2 and 8% of cases in a subgroups of immigrants and travellers [16]. Similarly, in Portugal, 6 confirmed cases of P. ovale spp. were identified with a possible 3 additional cases identified as P. ovale spp. or P. vivax [15]. Additional cases have been described in Latin America, most frequently in the context of travel to Africa and until recently, relied solely upon microscopy [29, 30, 31]. Cases in deployed forces returning from Africa with well-described periods of symptom onset or relapse as far out as 5 years have been described, while the U.S. military reported 1 case of P. ovale spp. from Afghanistan 2016 [11, 14, 32].

This cluster of cases experienced either a delayed primary presentation or relapse in the context of mefloquine prophylaxis and treatment for P. falciparum, a known potential confounder of P. ovale spp. presentation [11, 33]. Delay in presentation between the two species in relation to season of exposure and malaria prophylaxis use among travellers from nonendemic regions has been described as a clinical feature of these species [34, 35]. Of 757 cases in a UK database spanning 8 years, 33% used prophylaxis with P. ovale curtisi and P. ovale wallikeri possessing mean latency periods of 85.7 and 40.6 days, respectively [35]. Of the small subgroup in this retrospective study with P. ovale wallikeri and P. ovale curtisi, latency appeared to be decreased to 69.9 days and lengthened to 60.4 days respectively when prophylaxis regimens were used. Our patients, presenting between 1 and 11 months (Table 1) and with a presumed acquisition risk transcending the transmission season (August through November), mirror findings of a retrospective UK analysis [34]. In this study 23.4% of presentations were beyond 90 days of latency and that latency may be driven by timing of exposure as it relates to malaria season, 44 days within vs. 94 days outside the peak transmission season and is postulated to be an evolutionary adaptation to improve success of transmission [34]. Mefloquine with a prolonged termination half-life of 13.8–40.9 days, coupled with artemether–lumefantrine treatment may have delayed or altered the presentation of P. ovale spp. among these cases [36, 37]. Presumptive anti-relapse therapy with primaquine as part of prophylaxis strategies is recommended when traveling to P. vivax and P. ovale spp. endemic regions and is recognized as a strategy to prevent relapse in P. ovale spp. infections [38]. Nevertheless, its use in travellers or large military units requires providers to forecast risk of acquisition of this species of malaria and consider possible consequences of importation of this NFM to a non-endemic region [38, 39, 40].

As regions and countries progress in malaria elimination campaigns, imported cases of malaria become an increasing risk for reestablishing endemicity or introduction of new species [41]. Reintroduction of once eliminated species of malaria has been a noted concern in the literature, centering around cross border migration of populations to areas where competent vectors exist and where the proportion of imported cases is increasing [40, 42]. This is especially a concern during the prevention and reintroduction periods of elimination campaigns where malaria may be near eradication and where competent vectors exist or expanding their geographic distribution to suitable areas of transmission in the era of climate change [43]. These same concerns have been shared by UN peace-keeping forces from Sri Lanka, a country with malaria eradication since 2012, experiencing malaria outbreaks during their time of service in the CAR [44].

This is the first reported instance of imported P. ovale spp. to Peru, occurring in the context of international operations. These 4 cases bring to the forefront many of the limitations in the understanding of this NFM; risk to the individual and large groups of travellers, and how best to diagnose and manage these patients. While this particular infecting species may be considered less severe than other Plasmodium species, the clinical significance of the subspecies of P. ovale spp. is still being described [16]. There is much to be learned from this cluster of P. ovale spp. cases as an aetiology of ill-defined fever in large groups of travellers returning to a non-endemic region with the potential for its autochthonous transmission by the local competent vector, Anopheles darlingi.

Notes

Acknowledgements

Peruvian Navy Medical Center staff Dr. Victor Llerena, Dr. Miluska Delgado and Dr. Cecilia Gomez. Peruvian Navy Health Directorate, Peruvian Navy Medical Center Department of Naval Operations, Peruvian Navy Liaison Office DISAMAR/NAMRU-6. Peruvian Army Center medical staff BSc. Gloria Calderón Orellana and BSc. Flor Díaz de Alvarado. Peruvian Army Health Command, Peruvian Army Medical Center, Medical and lab staff. NAMRU-6 staff MSc. Carmen Lucas, Dr. Carola Salas, BSc. Keare Barazorda and BSc. Fredy Villena.

Copyright statement

Several authors of this manuscript are military service members or employees of the U.S. Government. This work was prepared as part of their duties. Title 17 U.S.C. § 105 provides that ‘Copyright protection under this title is not available for any work of the United States Government. Title 17 U.S.C. § 101 defines a U.S. Government work as a work prepared by a military service member or employee of the U.S. Government as part of that person’s official duties.

Disclaimer

The views expressed in this article are those of the authors and do not necessarily reflect the official policy or position of the Department of the Navy, Department of Defense, nor the U.S. Government.

Authors’ contributions

RIG: co-primary author, provided direct clinical care to cases. MO: co-primary author, epidemiological support to case management. HOV: co-author, performed diagnostics, technical review. DKB: co-author, editorial role. MR: co-author, technical review. CNM: co-author, editorial review, technical review. WRC: senior author, participated in clinical management. All authors read and approved the final manuscript.

Funding

Funding for this work was received from the Armed Forces Health Surveillance Branch (AFHSB) Global Emerging Infections Surveillance (GEIS) section, ProMIS ID: 17_N6_1.1.2

Ethics approval and consent to participate

This case report was reviewed by the US Naval Medical Research Unit No. 6, Lima, Peru IRB and approved for publication. Peruvian Army and Navy leadership have reviewed and approved the content for publication. This work represents a case report/series, standard of care was provided to the reported cases with no studied intervention or hypothesis tested.

Consent for publication

Not applicable. No personal or identifiable information is used in this report.

Competing interests

The authors declare that they have no competing interests.

References

  1. 1.
    Collins WE, Jeffery GM. Plasmodium ovale: parasite and disease. Clin Microbiol Rev. 2005;18:570–81.CrossRefGoogle Scholar
  2. 2.
    Sutherland CJ, Tanomsing N, Nolder D, Oguike M, Jennison C, Pukrittayakamee S, et al. Two nonrecombining sympatric forms of the human malaria parasite Plasmodium ovale occur globally. J Infect Dis. 2010;201:1544–50.CrossRefGoogle Scholar
  3. 3.
    Groger M, Fischer HS, Veletzky L, Lalremruata A, Ramharter M. A systematic review of the clinical presentation, treatment and relapse characteristics of human Plasmodium ovale malaria. Malar J. 2017;16:112.CrossRefGoogle Scholar
  4. 4.
    Roucher C, Rogier C, Sokhna C, Tall A, Trape J-F. A 20-Year longitudinal study of Plasmodium ovale and Plasmodium malariae prevalence and morbidity in a West African population. PLoS ONE. 2014;9:e87169.CrossRefGoogle Scholar
  5. 5.
    Sinton JA. Studies of infections with Plasmodium ovale. V. The effects of multiple inoculations upon the degree and nature of the immunity developed. Trans R Soc Trop Med Hyg. 1940;33:585–95.CrossRefGoogle Scholar
  6. 6.
    Sinton JA, Hutton EL, Shute PG. Studies of infections with Plasmodium ovale. II.—Acquired resistance to ovale infections. Trans R Soc Trop Med Hyg. 1939;33:47–68.CrossRefGoogle Scholar
  7. 7.
    Snounou G, Viriyakosol S, Jarra W, Thaithong S, Brown KN. Identification of the four human malaria parasite species in field samples by the polymerase chain reaction and detection of a high prevalence of mixed infections. Mol Biochem Parasitol. 1993;58:283–92.CrossRefGoogle Scholar
  8. 8.
    Snounou G. Detection and identification of the four malaria parasite species infecting humans by PCR amplification. Methods Mol Biol. 1996;50:263–91.PubMedGoogle Scholar
  9. 9.
    Guindon S, Delsuc F, Dufayard J-F, Gascuel O. Estimating maximum likelihood phylogenies with PhyML. Bioinformatics for DNA sequence analysis. Totowa: Humana Press; 2009. p. 113–37.CrossRefGoogle Scholar
  10. 10.
    Dinko B, Oguike MC, Larbi JA, Bousema T, Sutherland CJ. Persistent detection of Plasmodium falciparum, P. malariae, P. ovale curtisi and P. ovale wallikeri after ACT treatment of asymptomatic Ghanaian school-children. Int J Parasitol Drugs Drug Resist. 2013;3:45–50.CrossRefGoogle Scholar
  11. 11.
    Mellon G, Ficko C, Thellier M, Kendjo E, Aoun O, Adriamanantena D, et al. Two cases of late Plasmodium ovale presentation in military personnel. J Travel Med. 2014;21:52–4.CrossRefGoogle Scholar
  12. 12.
    WHO. Universal access to malaria diagnostic testing: an operational manual. Geneva: World Health Organization; 2011.Google Scholar
  13. 13.
    Castellanos ME, Díaz S, Parsons E, Peruski LF, Enríquez F, Ramírez JL, et al. First imported Plasmodium ovale malaria in Central America: case report of a Guatemalan soldier and a call to improve its accurate diagnosis. Mil Med Res. 2015;2:3.CrossRefGoogle Scholar
  14. 14.
    de Laval F, Oliver M, Rapp C, Pommier de Santi V, Mendibil A, Deparis X, et al. The challenge of diagnosing Plasmodium ovale malaria in travellers: report of six clustered cases in french soldiers returning from West Africa. Malar J. 2010;9:358.CrossRefGoogle Scholar
  15. 15.
    Ruas R, Pinto A, Nuak J, Sarmento A, Abreu C. Non-falciparum malaria imported mainly from Africa: a review from a Portuguese hospital. Malar J. 2017;16:298.CrossRefGoogle Scholar
  16. 16.
    Rojo-Marcos G, Rubio-Muñoz JM, Ramírez-Olivencia G, García-Bujalance S, Elcuaz-Romano R, Díaz-Menéndez M, et al. Comparison of imported Plasmodium ovale curtisi and P. ovale wallikeri infections among patients in Spain, 2005–2011. Emerg Infect Dis. 2014;20:409–16.CrossRefGoogle Scholar
  17. 17.
    Khairnar K, Martin D, Lau R, Ralevski F, Pillai DR. Multiplex real-time quantitative PCR, microscopy and rapid diagnostic immuno-chromatographic tests for the detection of Plasmodium spp.: performance, limit of detection analysis and quality assurance. Malar J. 2009;8:284.CrossRefGoogle Scholar
  18. 18.
    Grossman T, Schwartz E, Vainer J, Agmon V, Glazer Y, Goldmann D, et al. Contribution of real-time PCR to Plasmodium species identification and to clinical decisions: a nationwide study in a non-endemic setting. Eur J Clin Microbiol Infect Dis. 2017;36:671–5.CrossRefGoogle Scholar
  19. 19.
    Akerele D, Ljolje D, Talundzic E, Udhayakumar V, Lucchi NW. Molecular diagnosis of Plasmodium ovale by photo-induced electron transfer fluorogenic primers: PET-PCR. PLoS ONE. 2017;12:e0179178.CrossRefGoogle Scholar
  20. 20.
    Brasil P, Zalis MG, de Pina-Costa A, Siqueira AM, Júnior CB, Silva S, et al. Outbreak of human malaria caused by Plasmodium simium in the Atlantic Forest in Rio de Janeiro: a molecular epidemiological investigation. Lancet Glob Health. 2017;5:e1038–46.CrossRefGoogle Scholar
  21. 21.
    Richter J, Franken G, Mehlhorn H, Labisch A, Häussinger D. What is the evidence for the existence of Plasmodium ovale hypnozoites? Parasitol Res. 2010;107:1285–90.CrossRefGoogle Scholar
  22. 22.
    Chu CS, White NJ. Management of relapsing Plasmodium vivax malaria. Expert Rev Anti Infect Ther. 2016;14:885–900.CrossRefGoogle Scholar
  23. 23.
    Meltzer E, Morrison L, Stienlauf S, Schwartz E. Primaquine dosing errors: the human cost of a pharmaceutical anachronism. Am J Trop Med Hyg. 2015;93:123–4.CrossRefGoogle Scholar
  24. 24.
    Durand S, Cabezas C, Lescano AG, Galvez M, Gutierrez S, Arrospide N, et al. Efficacy of three different regimens of primaquine for the prevention of relapses of Plasmodium vivax malaria in the Amazon basin of Peru. Am J Trop Med Hyg. 2014;91:18–26.CrossRefGoogle Scholar
  25. 25.
    CDC. Malaria—diagnosis & treatment (United States). https://www.cdc.gov/malaria/diagnosis_treatment/index.html. Accessed 23 Apr 2019.
  26. 26.
    Niang M, Sane R, Sow A, Sadio BD, Chy S, Legrand E, et al. Asymptomatic Plasmodium vivax infections among Duffy-negative population in Kedougou, Senegal. Trop Med Health. 2018;46:45.CrossRefGoogle Scholar
  27. 27.
    Kano FS, de Souza AM, de Menezes Torres L, Costa MA, Souza-Silva FA, Sanchez BAM, et al. Susceptibility to Plasmodium vivax malaria associated with DARC (Duffy antigen) polymorphisms is influenced by the time of exposure to malaria. Sci Rep. 2018;8:13851.CrossRefGoogle Scholar
  28. 28.
    Brazeau NF, Whitesell AN, Doctor SM, Keeler C, Mwandagalirwa MK, Tshefu AK, et al. Plasmodium vivax infections in Duffy-negative individuals in the Democratic Republic of the Congo. Am J Trop Med Hyg. 2018;99:1128–33.CrossRefGoogle Scholar
  29. 29.
    Limongi JE, Costa DC, Carvalho LH, Lopes IS, Silva AA, Ferreira MS. Plasmodium ovale malaria in Brazil: report of an imported case with a prolonged incubation period. J Infect Dev Ctries. 2014;8:554–7.CrossRefGoogle Scholar
  30. 30.
    Meneses BE, Blair S. Malaria por Plasmodium ovale. Presentación del primer caso colombiano. Acta Med Colomb. 1995;20:288–91.Google Scholar
  31. 31.
    Giles ÁV. Paludismo. Reporte de un caso y revisión de la literatura. Medica Sur. 2006;13:129–35.Google Scholar
  32. 32.
    Armed Forces Health Surveillance Branch. Update: Malaria, U.S. Armed Forces, 2016. MSMR. 2017;24:2–7.Google Scholar
  33. 33.
    Trager W, Most H. A long-delayed primary attack of ovale malaria. Am J Trop Med Hyg. 1963;12:837–9.CrossRefGoogle Scholar
  34. 34.
    Nabarro LEB, Nolder D, Broderick C, Nadjm B, Smith V, Blaze M, et al. Geographical and temporal trends and seasonal relapse in Plasmodium ovale spp. and Plasmodium malariae infections imported to the UK between 1987 and 2015. BMC Med. 2018;16:218.CrossRefGoogle Scholar
  35. 35.
    Nolder D, Oguike MC, Maxwell-Scott H, Niyazi HA, Smith V, Chiodini PL, et al. An observational study of malaria in British travellers: Plasmodium ovale wallikeri and Plasmodium ovale curtisi differ significantly in the duration of latency. BMJ Open. 2013;3:e002711.CrossRefGoogle Scholar
  36. 36.
    Karbwang J, White NJ. Clinical pharmacokinetics of mefloquine. Clin Pharmacokinet. 1990;19:264–79.CrossRefGoogle Scholar
  37. 37.
    Gutman J, Green M, Durand S, Rojas OV, Ganguly B, Quezada WM, et al. Mefloquine pharmacokinetics and mefloquine-artesunate effectiveness in Peruvian patients with uncomplicated Plasmodium falciparum malaria. Malar J. 2009;8:58.CrossRefGoogle Scholar
  38. 38.
    Arguin PM, Tan KR. Malaria. In: CDC yellow book: health information for international travelers 2018. 2018th ed. https://wwwnc.cdc.gov/travel/yellowbook/2018/infectious-diseases-related-to-travel/malaria. Accessed 7 May 2019.
  39. 39.
    Baird JK. Management of Plasmodium vivax risk and illness in travelers. Trop Dis Travel Med Vaccines. 2017;3:7.CrossRefGoogle Scholar
  40. 40.
    Dong X, Yang J, Lou L, Zhu L, Feng X, Yao L. Once malaria is eliminated, more attention should be paid to imported malaria: data from five years of surveillance in the City of Yiwu in eastern China. Biosci Trends. 2017;11:360–2.CrossRefGoogle Scholar
  41. 41.
    WHO. World malaria report 2018. Geneva: World Health Organization; 2018. https://www.who.int/malaria/publications/world-malaria-report-2018/report/en/. Accessed 7 May 2019.
  42. 42.
    van Eer ED, Bretas G, Hiwat H. Decreased endemic malaria in Suriname: moving towards elimination. Malar J. 2018;17:56.CrossRefGoogle Scholar
  43. 43.
    Hundessa S, Li S, Liu DL, Guo J, Guo Y, Zhang W, et al. Projecting environmental suitable areas for malaria transmission in China under climate change scenarios. Environ Res. 2018;162:203–10.CrossRefGoogle Scholar
  44. 44.
    Fernando SD, Booso R, Dharmawardena P, Harintheran A, Raviraj K, Rodrigo C, et al. The need for preventive and curative services for malaria when the military is deployed in endemic overseas territories: a case study and lessons learned. Mil Med Res. 2017;4:19.CrossRefGoogle Scholar

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Authors and Affiliations

  1. 1.Dirección de Salud de la MarinaLimaPeru
  2. 2.Comando de Salud del EjércitoLimaPeru
  3. 3.U.S. Naval Medical Research Unit No. 6LimaPeru
  4. 4.Department of Global HealthMilken Institute School of Public Health, The George Washington UniversityWashingtonUSA
  5. 5.Division of Infectious Diseases, Department of Internal MedicineWalter Reed National Military Medical CenterBethesdaUSA

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