Fig 6. The number of cases positive with delayed parasite clearance and K13 mutant alleles

            The presence of C580Y mutant was obtained mostly in the mild DPC group, followed by severe DPC group. In general, the number cases of mild DPC and severe DPC correlated with the frequency of K₁₃ propeller C580Y. Almost patients have no delayed parasite clearance were obtained with wild type K₁₃ mutant alleles. The sensitivity and specificity of the SNP 580Y at day 0 to identify delayed clearance (PCT, ? 72h) were therefore estimated at 71.88% (22/32) and 82.35% (14/17), respectively; the positive predictive value of the mutation was 88% (22/25), while the negative predictive value of the wild-type allele was 58.33% (14/24). The cases positive with K₁₃ mutation and also DPC mostly occurred in Gia Lai.

3.4.2. Correlation between the frequency ofK13-propeller alleles and the proportion D3 (+)

The mutant allele obtained were in Gia Lai with extremely high prevalence 75.86% (22/29), compared to the frequency of C580Y in Ninh Thuan was 15% (3/20). 22 cases were positive of K₁₃ mutantation and DPC, mostly occurred in Gia Lai,just2 cases were obtained in Ninh Thuan. Within a large number of patients had the C580Y allele (25/49), all of 6 patients of severe DPC group had C580Y mutation were obtained in Gia Lai. No patient of severe DPC with C580Y was obtained in Ninh Thuan. Just o­nly 2 patients had C580Y allele were found in mild DPC group and the other o­ne in No DPC group. All most No DPC patients with K₁₃ wild type allele were found in Ninh Thuan, 12 in 14 totally.

3.4.3.Correlation between the frequency ofK₁₃-propeller alleles and several cases were positive at D28 after ACT treatment

Fig 7. The number of cases positive with delayed parasite clearance and K13 mutant alleles

Within totally 49 patients, 16 (32.7%) patients completed the 28-day follow-up, there were 9 (56.3%) cases were positive at D28 by qPCR with low parasitemia (from 1-43 parasites/µl). Just o­nly 2 cases in Gia Lai were confirmed to carry K₁₃ mutant allele C580Y.

4. DISCUSSION

4.1.Baseline characterization of the patients and efficacy of DHA-PPQ in parasite clearance

All of 49 patients with the median malaria parasite density of asexual P. falciparum at two sites Gia Lai and Ninh Thuan were 14.150 and 9.038 parasites/µ respectively. The low median parasitemia in two provinces are not an effect to be considered as the factor contributing to delay in parasite clearance [5],[6]. Compared to microscopy, the prevalence of parasite densities by qPCR detected increasingly more infections over time, and the difference became significant at day 3, when the prevalence by PCR was 3.3 times higher than that by microscopy (67.3% vs. 20.4%; p < 0.01). Notably, the proportion of positive parasitemia at D₃ in Gia Lai province was extremely high, 86.2% by qPCR and 31 % by microscopy; in Ninh Thuan was 40% by qPCR and 5% by microscopy, which is currently the indicator of choice for routine monitoring to identify suspected artemisinin resistance in P. falciparum.
         Using qPCR with high sensitivity and specificity, the number of positive parasitemia o­n D3 observed by qPCR much higher in comparing with microscopic evaluation. However, within the large range of parasitemia o­n D₃ observed by qPCR, we divided all 33 delayed parasite clearance cases into two group mild DPC (with residual parasitemia <1%) and severe DPC (residual parasitemia >1%). In the mild DPC group, the parasitemia was low, from 1 to less 10 parasites/µl. No evidence showed that the very low parasitemia detected by qPCR probably was death parasite or not. Almost mild DPC cases focussed in Gia Lai and in contrast, No DPC cases focussed in Ninh Thuan mainly, and it is necessary to have further study about it. 
           About the DHA-PPQ efficacy in Gia Lai, specially, there were just o­nly 6 cases in severe DPC group which located in Gia Lai, where the median parasitemia and the prevalence of D₃ positive after ACTs treatment were confirmed to be higher than in Ninh Thuan. High parasitemia o­n D3 after using DHA-PPQ in severe DPC group is unlikely that was the immunity profile cause of the observed delayed parasite clearance. It is necessary to complete futher study about the immunity profile of the community and the individual, also the pharmacokinetics and pharmacodynamics of the antimalarial drug to understand this situation. High prevalence of positive parasitemia o­n D₃ was also similar to the other sites in the Gia Lai, Dak Nong, Quang Nam [8], Khanh Hoa, Binh Phuoc [5],[6]. The the proportion of positive parasitemia at D3 in Binh Phuoc was from 15% up to 22%; 30%; 36%, and 36.8% year by year from 2010 to 2015, in Quang Nam of 29.2%, Kon Tum of 14%, Khanh Hoa of 17.4%, Dak Nong was from 29% up to 26.7% from 2012 to 2014, and Gia Lai was from 11% up to 23%; 26.4% and 38.5% from 2010 to 2014. Not o­nly Vietnam but also the other countries in South East Asia, the the proportion of positive parasitemia at D3 in Cambodia increased continuously year by year 26% up to 33%; 45% and 54% from 2008 to 2012, in Myanmar from 14% up to 19%; 23% from 2012 to 2013 or Thailand was from 9% up to 14%; 17%; 25% and 48% from 2009 to 2014.

About the DHA-PPQ efficacy, with 16 cases followed up to D₂₈, the adequate clinical and parasitological response (100% in Ninh Thu?n and 97.4% in Gia Lai), negative parasitaemia o­n D₂₈ was 56.3% (9/16) confirmed by qPCR, divided into two province equally. And all of cases were positive at D₂₈ had the proportion of positive asexual P. falciparum at D₃ by qPCR. This result is different to previous researchs of Vietnam [5],[6]. It probably caused by using different sensitivity methods to detect parasitemia. It is necessary to to apply with the other samples to assess the DHA-PPQ efficacy.

Moreover, age distributions followed No DPC, mild DPC and servere DPC have no significantly difference (Fig 12). As expected from previous work, young children had slower parasite clearance rates compared to older patients. However, this was observed o­nly in artemisinin-sensitive parasite populations, with most data coming from Africa. Resistant parasite populations, present o­nly in Southeast Asia, did not demonstrate an age effect. The lack of an age effect o­n DPC could be due to o­ne or more of the following factors: lower background immunity in those patients from low transmission settings, different age distributions studied with 87.5% of patients aged older than 15 years.

4.2.Frequency of non synonymous Kelch 13 polymorphisms observed in P. falciparum isolates

In this study, the overall prevalence of the mutant allele was 51% (25/49). And the C580Y mutant allele was o­nly o­ne SNPs K₁₃ propeller found in all cases positive with K₁₃ mutation. Notably, the C580Y substitutions that was confirmed to correlate to in vitro resistance or delayed parasite clearance - a confirmed mutation alleles inclassification of K₁₃ polymorphism as WHO reference in Southeast Asia.About the correlation between the K₁₃ polymorphisms and delayed parasite clearance, the presence of C580Y mutant was obtained mostly in the mild DPC group, followed by severe DPC group. In addition, almost no DPC cases had wild-type K₁₃ mutant allele. In general, the number cases of mild DPC and severe DPC correlated with the frequency of K₁₃ propeller C580Y.

However, the mutant allele obtained were in Gia Lai with extremely high prevalence compared to the prevalence of C580Y in Ninh Thuan (75.86% vs. 15%). The cases positive with K₁₃ mutation and also DPC mostly occurred in Gia Lai. Furthermore, C580Y K₁₃ alleles mainly were obtained in mild DPC group. This data gave the correlation between the delayed parasite clearance and the K₁₃ mutation in this sites (p = 0.002). o­n the contrary, in Ninh Thuan, no DPC showed a relevent data to K₁₃ wild-type. Considering that the high prevalence of delayed parasite clearance and K₁₃ mutant alleles, Gia lai fulfills the WHO definition of confirmed artemisinin resistance and Ninh Thuan as suspected artemisinin resistance.

4.4. The correlation between the K₁₃ mutations, DPC, and artermisinin resistant P. falciparum

The frequency distribution of mutant alleles over two provinces matches that of day 3 positivity in ACTs-treated patients. The mutant parasites cluster in Gia Lai provinces where the delayed parasite clearance is well established and are less prevalent where DPC is less common in Ninh Thuan. The study was designed as a 28-day follow-up study to assess the efficacy of DHA-PPQ in treating falciparum malaria. Despite the fact that no recrudescent case was obtained during the researching time, there were 9 cases were positive at D₂₈ by qPCR with low parasitemia. The hypothesis of death parasite could be detected until D₂₈. It also means that the parasite could be still alive until after day 20 at least. Within 9 cases were positive of asexual parasite o­n D₂₈, two of them also carried C580Y mutant alleles. It seems to be a strong evidence of the correlation between K₁₃ mutation and delayed parasite clearance [9]. Nevertheless, no evidence of rescrudescence was showed. It leads to the other hypothesis that the patiens with positive of parasite o­n D₂₈ could become a asymptomatic carrier [10].

In study, the frequency of mutant alleles correlates strongly with the prevalence of D3 positivity after ACT treatment; however, both K₁₃ mutant alleles and DPC were not associated with artemisinin resistance. In fact, totalof186K₁₃alleles,including108non-synonymousmutations havebeenreporteduntil now. However, notallnon-synonymouspropeller-regionK₁₃ mutantsreportedindicateemergingartemisinin resistance. Besides, the emergence of SNPs K₁₃ propeller and the spread of artemisinin seem to be independent. Notebly, the widespread 580Y mutation seems to have emerged twice. Given that frequency distribution suggests a Cambodian origin, where the mutations are most prevalent, with subsequent spread to Vietnam and maybe to Africa [9]. Howerver, our study site in Krong Pa, Gia Lai does not share the border with Cambodia, therefore, C580Y allele maybe o­ne of indigenous mutation. It created ?the gap, the blacklash? o­n Tier 1 map o­n Central highland of Vietnam. Although few P. falciparum isolates were recruited in Ninh Thuan, it shows the high prevalence of DPC with low frequency of K₁₃ mutations, it is indispensable to continue further study to assess the DHA-PPq efficacy for P. falciparum infection in this area and interprete the role of K₁₃ mutant alleles in this area.

CONCLUSION

Up-to-date information o­n whether artemisinin resistance has already disseminated or independently emerged is a critical issue. If resistance were limited to a small, well-defined area, then elimination of drug-resistant malaria from these regions would be possible. More works are needed to delineate the normal function of K₁₃ and the effect of various mutations besides studies are therefore required to identify additional genetic determinants of artemisinin resistance.

Conflict of interest

The authors have no other conflicts of interest.

Acknowledment

This study is partly supported by the donations of World Health Organization (WHO), Sassari University, Institute of Malariology, Parasitology, and Entomology (IMPE) Quy Nhon, Vietnam and Hue University of Medicine and Pharmacy.

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