Epidemiology of Plasmodium infections in Flores Island, Indonesia using real-time PCR

Nangapanda village, Ende district, Flores Island, Indonesia (Figure 1) is a semi-urban village with an estimated population of 22,000 living in 18 sub villages. It is situated near the Equator, characterized by a high uniform temperature in range of 23 to 33.5°C and humidity is 86 to 95%. Average yearly rainfall is 1.822 mm with around 82 rainy days, especially during November to April and the highest in December until March. The local Puskesmas (primary health centre) is responsible for providing health services to people living in the 18 sub villages. Based on the results of a preliminary survey in 2005–2006, three sub villages: Ndeturea (sub village 1), Ndorurea 1 (sub village 2) and Ndorurea (sub village 3) have a high prevalence of malaria cases as reported by the Puskesmas. These three sub villages were enrolled in this study. The purpose of the study was explained and informed consent was requested. Informed consent for children was obtained from their parents or guardians. The name, sex, age, and home address of each participant was recorded by the research team.

Venous blood samples were collected during dry season between June and August 2008 from participants above four years of age in Ndeturea, Ndorurea 1 and Ndorurea. Blood samples (6 ml) were collected in tubes containing sodium heparin as anticoagulant. Eight microlitres and two microlitres from each sample was used to prepare a thick and thin blood smear, respectively; 200 μl was stored at −20°C for real-time PCR and the remainder was used to test a range of immunological markers as part of a larger study [15, 17]. The samples were transported to the central laboratory in Jakarta and stored at −80°C.

Haemoglobin level was measured using a blood analyzer system (COULTER® Ac-T diff2™, Beckman Coulter, USA). Haemoglobin levels were divided into normal and anaemic according to criteria used by the Indonesian General Hospital, Cipto Mangunkusumo. The normal values for children (one month to six years), girls (seven to 13 years), boys (seven to 13 years), women (>13 years) and men (>13 years) are haemoglobin 11.5-15.5 g/dl, 12–16 g/dl, 13–16 g/dl, 12–14 g/dl, and 13–16 g/dl, respectively. Cases with haemoglobin levels below these normal values were categorized as anaemic.

The ABO blood typing was performed using monoclonal grouping kit (Fortress Diagnostics Ltd, UK).

The oral temperature was measured using a digital thermometer (General Care, China) and categorized in three groups: low, normal, and high (fever) for temperature level: <36.1°C, 36.1-37.5°C, and >37.5°C, respectively [18].

Duplo slides of both thin and thick smears for malaria diagnosis were made on the same day of blood collection and Giemsa-stained within 48 hours. The guidelines of the WHO Secretariat for the Coordination of Malaria Training in Asia and the Pacific were used as standard operating procedure. The slides were stored in slide boxes at room temperature. Thin and thick smears were examined using 1,000× oil immersion light microscopy for the presence of malaria parasites [19, 20]. Microscopic examination of the slides was performed blinded by experienced technicians and approximately 10% of the slides were cross-checked randomly for quality control by a second experienced microscopist at the Department of Parasitology, Medical Faculty, University of Indonesia.

Parasite DNA was isolated from 200 μl blood using QIAamp DNA-easy 96-well plates according to the manufacturer’s recommendations (Qiagen, Hilden, Germany). In each sample, 10³ PFU/ml phocin herpes virus-1 (PhHV-1) was added within the isolation lysis buffer to serve as an internal control [21]. DNA was stored at 4°C.

Plasmodium-specific primers and P. falciparum, Plasmodium vivax, Plasmodium ovale and Plasmodium malariae-specific probes were used as described previously [15]. Amplification reactions were performed in white PCR plates, in a volume of 25 μl with PCR buffer (HotstarTaq mastermix; Qiagen, Valencia, USA), a total of 5 mmol/l MgCl2, 12.5 pmol of each Plasmodium-specific primer and 15 pmol of each PhHV-1-specific primer, 1.25 pmol of each P. falciparum, P. vivax, P. malariae-specific XS-probes, and PhHV-1-specific Cy5 double-labelled detection probe, 2.5 pmol of each P. ovale-specific XS-probes (Biolegio, Nijmegen, The Netherlands) and 5 μl of DNA sample. Amplification comprised of 15 min at 95°C, followed by 50 cycles of 15 sec at 95°C, 30 sec at 60°C and 30 sec at 72°C. Negative and positive control samples for each four species were included in each PCR run.

Amplification, detection, and analysis were performed using the CFX real-time detection system (Bio-Rad Laboratories, USA). The PCR output from this system consists of a cycle-threshold (Ct) value, representing the amplification cycle in which the level of fluorescent signal exceeds the background fluorescence reflecting the parasite-specific DNA load in the sample tested. The amplification is considered to be hampered by inhibitory factors if the expected cycle threshold (Ct) value in the PhHV-specific PCR was increased by more than 3.3 cycles. Positive Ct- values were grouped into three groups: Ct < 30.0, 30.0 < Ct < 35.0 and >35.0 representing a high, moderate and low DNA load, respectively.

DNA isolation and set up of the PCR reactions were performed using a custom-made Hamilton robot platform.

A total of 1,516 blood samples were available for microscopy and PCR. Seven samples were excluded due to failure of the DNA isolation or inhibition of the DNA amplification reaction. Figure 2 shows the flow chart of the samples in the study. The final number of samples included in the analysis was 1,509 with ages ranging from four to 79 years, mean and median age of 29 and 27 years, respectively. Participants older than 20 years were over-represented in the analysis group compared to the total population (57.9% vs 42.1%). The proportion of males in the analysis group (41.7%) was slightly less than the proportion of males in population (45.3%). A detailed comparison of the population and participants’ characteristics is given in an additional table [see Additional file 1]. Participant characteristics per sub village are described in Additional file 2.

The results of microscopy and real-time PCR are summarized in Table 1. Fifty-two (3.4%) of all available samples in the study were positive by microscopic examination and confirmed with real-time PCR. Plasmodium falciparum, P. vivax and P. malariae-specific DNA amplification was shown in a total of 399 (26.4%) subjects.

Discrepancies between positive results in the microscopy and real-time PCR were observed in 14 cases. In seven cases real-time PCR revealed another Plasmodium species than the species that was determined with microscopy. In another seven samples Plasmodium-specific DNA could not be detected, neither with the Plasmodium species-specific probes nor when checked for Plasmodium genus-specific amplification using agarose gel-electrophoreses.

Plasmodium falciparum, P. vivax and P. malariae parasites were detected with PCR only (i e, were sub microscopic) in 83.1%, 94.5% and 82.1% of the subjects, respectively. Median Ct-values of P. falciparum, P. vivax and P. malariae-specific amplification in sub microscopic cases were higher (i e, lower DNA load) compared to the median Ct-values of microscopy positive subjects 35.3, 36.3 and 36.4 versus 30.4, 28.7 and 30.8, respectively (p values ≤0.02).

Plasmodium falciparum, P. vivax and P. malariae-specific DNA amplification was shown in 14.5%, 13.2% and 1.9% of the samples, respectively. The distribution of Plasmodium species and infections in each sub village is summarized in Table 1. In all three sub-villages, P. falciparum, P. vivax and P. malariae, and subjects with mixed infections were detected. Mixed infections of P. falciparum and P. vivax were detected in 41 subjects and in six subjects a mixed infection of P. falciparum and P. malariae was found. The highest prevalence of Plasmodium infections was detected in Ndeturea (30.9%) compared by Ndoturea 1 (24.9%), and Ndorurea (25.5%), but the difference was not statistically significant.

Figure 3 shows the parasite-specific DNA loads of P. falciparum and P. vivax in the different age groups. A high load of Plasmodium species-specific DNA (Ct <30) was found for P. falciparum, P. vivax and P. malariae in 10.5%, 4% and 14.3% of the positive cases, respectively. A moderate DNA load (Ct 30–35) was found for P. falciparum (43.8%), P. vivax (31%), and P. malariae (39.3%) and a low DNA load (Ct > 35) was detected for P. falciparum (45.7%), P. vivax (65%) and P. malariae (46.4%). Plasmodium malariae was not detected in subjects below five years of age.

Table 2 summarizes the Plasmodium species-specific real-time PCR results in correlation with age, gender, haematological parameters, and body temperature. The prevalence of P. falciparum in subjects younger than 20 years (22.4%) was significantly higher compared to the prevalence found in subjects older than 20 years (8.7%) (p ≤ 0.001). The same was found for the prevalence of P. vivax in the young and older age group, 18.4% and 9.3%, respectively (p ≤ 0.001). The median Ct-values of the P. falciparum PCR in subjects below 20 years were lower compared to subjects of 20 years and older, 34.2 and 36.0 respectively (p = 0.003). The median Ct-values in the P. vivax PCR were not significantly different in the young and older age group. Both prevalence and median Ct-values of the P. malariae PCR in subjects below 20 years were not significantly different compared to the subjects older than 20 years.

The prevalence of Plasmodium infections in males compared to females was significantly different for P. vivax 15.7% versus 11.4%, respectively (p = 0.01). There was no difference in prevalence of P. falciparum and P. malariae. The median Ct-values of P. falciparum, P. vivax and P. malariae-specific amplification in males were not significantly different compared to those in females.

The haemoglobin concentration was measured in 538 of 1,509 of the participants. Normal haemoglobin level was found in 74.3% of the subjects and 25.7% were categorized as anaemic. The number of P. falciparum- positive subjects was significantly higher (p ≤ 0.001) in anaemic participants as compared to the subjects with a normal haemoglobin level. There was no difference in the number of P. vivax and P. malariae positive subjects in the anaemic and non-anaemic group. The median Ct-values of P. falciparum and P. vivax -specific amplification were lower in the anaemic cases compared to the non-anaemic subjects (p = 0.02 and p = 0.01 respectively).

Blood grouping was performed in 1,263 of 1,509 subjects. Blood group A, B, AB, and O was found in 25.3%, 24.9%, 5.1% and 44.7% of the subjects, respectively. The highest prevalence of Plasmodium infections was found in subjects with blood group AB as compared to the other blood groups. The prevalence and median Ct-values of all three Plasmodium species separately were not different between the subjects with different blood groups.

Body temperature was recorded in 1,496 of 1,509 participants. A low body temperature (<36.1°C) was found in 26.3% of the participants, a normal body temperature (36.1-37.5°C) in 73.1% and eight of 1,509 (0.5%) showed a high body temperature (>37.5°C). There was no difference in the number of Plasmodium infections in the cases with a low and normal body temperature. Plasmodium falciparum was detected in four of eight subjects with a high body temperature. However, the number of subjects in this group was too small for statistical analysis.