Background
Plasmodium vivax is the causative agent of relapsing benign tertian human malaria, the second most common type of malaria in humans, that afflicts several hundred million people annually in the world. Vivax malaria is a major public health problem in many tropical and semi-tropical regions and temperate countries, including the Democratic People’s Republic of Korea (DPRK) and the Republic of Korea (ROK) [
1].
The first scientific documentation of malaria was published in 1913, although it had been prevalent throughout the Korean peninsula for several centuries [
2]. As a result of a national malaria eradication programme conducted in cooperation with the World Health Organization (WHO), the incidence of vivax malaria in the ROK rapidly decreased until in 1979 when WHO declared the ROK to be malaria free [
3‐
5]. In the 1980’s two sporadic cases were detected [
6] and in 1993, a ROK soldier serving in northern Gyeonggi Province [
7], and two civilians were diagnosed with vivax malaria [
8]. Thereafter, a number of malaria cases were reported near the demilitarized zone (DMZ), which centers on Paju-si, Yeoncheon-gun, Cheorwon-gun, Gimpo-si, Ganghwa-gun, Goyang-si, and Dongducheon-si.
During the first few years of re-emergence of vivax malaria in the ROK, most cases occurred in ROK military personnel deployed near the DMZ. But some civilians who live in Daeseongdong where located inside of DMZ and Tongilchon surrounded by ROK military installations near the DMZ showed high infection rate as much as ROK military personnel. In addition, as the number of malaria cases increased, the ratio of civilian cases were increased [
9].
Thus, it was of considerable concern that vivax malaria might become re-established through out the ROK as veteran soldiers returned to their hometowns throughout all of Korea [
10‐
12].
The aim of this study was to determine the annual number of patients with malaria among military personnel, veterans, and civilians in the ROK; the mean daily incidence for weekly intervals; the geographic distribution of cases among military personnel and civilians; and the number of Anopheles mosquitoes captured by black light trap in the malaria risk from 2010–2012 to analyse the current status of malaria in the ROK.
Discussion
In North Korea, the high-risk areas of vivax malaria are Gaeseong City, the South and North Hwanghae Provinces, and Gangwon Province, which border the DMZ. The DMZ is a 4-km-wide, 250-km-long corridor that extends across the middle part of the Korean peninsula. In general, no civilians have been allowed to enter the DMZ for more than 60 years, even though one exceptional village called “Daesungdong” is located inside of DMZ; therefore, natural ecosystems and biodiversity are highly conserved in the DMZ [
18]. To control malaria, North Korea has provided presumptive anti-relapse chemoprophylaxis with primaquine (15 mg for 14 days) before the malaria transmission season for civilians living in these areas since 2002 [
19]. As a result, it was believed that transmission of malaria occurred mainly in these areas in North Korea [
20]. Therefore, the adjacent to malaria risk areas in North Korea, high risk areas were observed in the ROK, e.g., Incheon Metropolitan City and northern Gyeonggi and Gangwon provinces. There is no objective opinion that mass chemoprophylaxis might largely decrease the number of malaria cases among military personnel, which may alternatively decrease numbers of cases among civilian populations. Chemoprophylaxis started with approximately 16,000 military personnel in 1997 and expanded to more than 200,000 military personnel who are currently serving in malaria high risk areas [
13]. Unfortunately, it was found that prophylactic failure occurred even in those who had sufficient plasma concentrations of hydroxychloroquine. It means that a chloroquine-resistant
P. vivax strain has been reported in the ROK [
21]. The appearance of this drug-resistant strain is troublesome for the treatment of patients in the future. Therefore, another standard regimen should be considered to replace the current regimen of chloroquine-primaquine. However, it is not easy to find the next defensive line of anti-malaria drugs because it has been reported that Korean
P. vivax isolates are already resistant to pyrimethamine, which is recommended for use in patients with malaria who fail to respond to chloroquine chemotheraphy [
22]. It was shown that the existence of antifolate-resistant
P. vivax in the ROK. Further detailed geographic mapping of current and changing patterns of vivax malaria drug resistance on a national or regional scale would prove a valuable aid for developing and updating national anti-malarial policy guidelines in the ROK. Control measures and inter-governmental co-operation are also needed to block the spread of drug-resistant malaria in the ROK.
It was reported that six Anopheles species in the ROK:
Anopheles sinensis sensu stricto
, Anopheles lesteri, Anopheles pullus, Anopheles sineroides, Anopheles kleini, and
Anopheles belenrae[
23‐
26]. These six species comprise a species complex called
An. sinensis s.l. Because they occur in sympatry and it is hard to distinguish by morphology. Thus, molecular methods are needed to identify the species. But it is hard to apply the newly developed methods for classifications in the surveillance system until developing more precise methods for identification of
Anopheles complex in real time manners. Therefore,
An. sinensis s.l. was presented in this study. Analysis of the mosquito density of
An. sinensis s.l. in study areas over three years showed an extremely higher density in Ganghwa County compared to Cheorwon County (Figure
7). Therefore, the potential unknown threatening factors including mosquito density still may exist on the west side of malaria foci compared with the east side; this explains why the API of Gangwon Province, which is the representative location of the east side, was reduced dramatically from 0.123 in 2010 to 0.063 in 2011 and to 0.009 in 2012 and the API of Incheon Metropolitan City changed from 0.093 in 2010 to 0.045 in 2011 but increased to 0.052 in 2012 (Table
3).
PHCs are responsible for controlling the transmission of malaria in each of the vivax malaria risk area. As a result of the anti-malaria efforts of the PHC in Cheorwon County, which is a high-risk area in Gangwon Province, the number of cases of malaria decreased dramatically to low level, 27 cases in 2010, 14 cases in 2011, and two cases in 2012. In Cheorwon County, nine cases were first reported in 1997, while there was a peak of 166 cases in 2000 [
27]. It took an average of 5.4 average days (4.2–7.0) to confirm a case of malaria after onset during 2010–2012 (unpublished data). Anti-mosquito activities, including fogging and residual spray, took place from April 8 to October 5 in 2010, May 4 to October 4 in 2011, and May 4 to October 9 in 2012. In total, 748 L of insecticide and 129 L of larvicide were used in 2010, 1,037 L of insecticide and 188 L of larvicide were used in 2011, and 807 L of insecticide and 21 L of larvicide were used in 2012 to cover an area of 36,592 m
2. To obtain this level of coverage, activities were repeated approximately 1,442 times in 2010, 1,510 times in 2011, and 1,430 times in 2012 (data from the PHC in Cheorwon County, Gangwon Province).
The interesting finding is that the last peak of each year was shown the similar patterns in three years, that is, increasing the malaria cases in three weeks after Chuseok (Figure
4, ↓). This duration is matched with the incubation period of vivax malaria in the liver. It was probably due to the massive interregional population movement throughout the ROK during Chuseok from high risk areas to malaria free areas, in addition increasing the activities during the night without self protection from malaria vectors. It is suggested that soldiers who leave for vacation to their hometowns should be either checked or treated for malaria just like retiring ex-soldiers from their active military service (primaquine/15 mg/14 days) [
15,
28,
29].
To evaluate transmission of malaria in a given geographic region, many factors, including temperature, mosquito density, vector capacity, climate, rainfall, and humidity, should be considered [
30]. Patient incidence alone cannot provide a complete understanding of the prevalence of malaria in the ROK because there are many factors involved, including the changes in weekly population density of mosquitoes due to environmental factors, vectorial capacity, long- and short-incubation patient ratios, symptomatic and asymptomatic patient ratios, and differences in weekly rainfall and temperatures. This study analysed only two factors: incidence and
An. sinensis s.l. However, all factors indicated that transmission of malaria would apparently be reduced except in Incheon Metropolitan City and Gyeongnam Province. There are opportunities for the eradication of malaria in the ROK due to several efforts of the Korea CDC, Government Public Institute of Health and Environment, PHCs, and related institutes.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
TSK and HWL conceived and designed the study and contributed to the execution of the research. TSK and HWL wrote the manuscript. PYC, SKA, SKL, YJK, JSK, HSK, SHC, YKP and YSH collected the mosquitoes. HCK, WJL, SKY, JG, YS, BKN, and HSK collected the information on patients and performed analysis of the mosquito population. All authors have read and approved the final manuscript.