Newly contracted (excluding all follow-up patients with P. vivax relapses) malaria cases were confirmed by light microscopy, using standard Giemsa staining according to the World Health Organization (WHO) national malaria treatment and diagnosis guidelines (7–9), and were detected passively in febrile patients seeking treatment in the Provincial Malaria Center, Kundoz City, from January 2001 through December 2005. Annual cases of P. vivax and P. falciparum malaria reported from Kundoz Province from January 2001 through December 2005 are depicted in the Figure. A marked increase in case numbers of both vivax and falciparum malaria occurred from 2001 through 2002, showing an 8.9-fold increase for P. falciparum. After 2002, the height of the epidemic, malaria case numbers steadily declined, with P. vivax cases falling to 10,946 and P. falciparum cases falling to only 27 during 2005. With an estimated population of 3,058,100, the annual incidence rates for P. falciparum malaria in Kundoz Province were from 0.0088 (in 2005) to 4.39 (in 2002) per 1,000 person-years; for P. vivax, the rates were from 3.57 (in 2005) to 13.37 (in 2002) per 1,000 person-years.

From January 2004 through December 2005, adult anopheline mosquitoes were collected outdoors by using New Standard Miniature Light Traps (No. 1012, John W. Hook Co., Gainesville, FL, USA) without an additional CO₂ generator and indoors by using an aspirator in the rice-growing areas of Kundoz City, Kanam, Khanabad, Angor Bag, Alchira, Malaghi, and Jan Guzar. Light Traps were set in housing areas within a 5-km radius of rice fields, which are located in or close to towns, villages, and housing areas. Anopheline larval monitoring was carried out using the WHO-recommended Frisbee disk method (10) once a month from May through October in rice fields associated with mosquito trapping sites. Results represent mean values obtained after 10 replicates.

Indoor trapping showed the following: of 299 anopheline mosquitoes trapped in 2004, 82.6% were A. pulcherrimus, 16.7% were A. superpictus, and 0.7% were A. culicifacies; of 403 anophelines trapped in 2005, 81.1% were A. pulcherrimus and 18.9% were A. superpictus (11). All specimens were female and blood-fed.

Outdoor entomologic surveys showed the following: of 439 anophelines collected in 2004, 60.1% were A. pulcherrimus, 30.0% were A. hyrcanus, and 9.9% were A. superpictus; of 456 anophelines collected in 2005, 47.4% were A. hyrcanus, 42.1% were A. pulcherrimus, and 10.5% were A. superpictus. Among all mosquitoes trapped, 80.8% were female, and 22.9% of these were blood-fed. The mean trap rate was 4.8 ± 3.9 anophelines per trap night (range 0–17 per trap night).

Anopheline adult outdoor abundance peaked in late August, with the following percentage monthly means: May (1.2%), June (9.5%), July (18.6%), August (35.2%), September (26.8%), and October (8.7%). Anopheline larval monitoring yielded 54.7% A. hyrcanus (0–68 larvae per dip; mean 12.3), and 45.3% A. pulcherrimus (0–49 larvae per dip; mean 9.8). No A. superpictus or A. culicifacies larvae could be detected in rice field samples. Anopheline larval abundance peaked in late July and early August with the following monthly means: May (0%), June (17.9%), July (32.3%), August (36.2%), September (12.8%), and October (0.8%).

The P. falciparum and P. vivax polymorphs VK 210 and VK 247 circumsporozoite protein (CSP) positivity rates in anopheline pools (5 females per species) trapped indoors and outdoors from 2004 through 2005 were detected by using the VecTest Malaria Panel Assay dipstick ELISA (Medical Analysis Systems, Inc., Camarillo, CA, USA) and are listed in the Table. The available data indicate that A. superpictus is the principal P. falciparum vector. Three A. pulcherrimus pools positive for P. falciparum CSP indicate that this species may be partly involved in P. falciparum malaria transmission. Plasmodium CSP positivity values were higher in indoor-trapped A. superpictus (2004: χ² = 4.9; df = 1; p = 0.025). Of P. vivax CSP-positive pools, 90.6% were VK 247-reactive, and 9.4% were reactive against both VK 247 and VK 210, indicating a similar P. vivax genospecies distribution pattern as reported previously from eastern Afghanistan (12).

Our results show that malaria quickly reemerged in rice-growing Kundoz Province of northeastern Afghanistan. This may be due to various factors: 1) introduction of P. falciparum and P. vivax malaria by returning refugees (13); 2) environmental changes caused by intensified rice growing in close proximity to towns, villages, and housing areas and therefore within flight range of endemic anopheline vectors (3,5); 3) increased abundance and breeding of the local principal vectors of P. vivax malaria stemming from intensified rice growing and irrigation systems that serve as preferred breeding sites for A. pulcherrimus and A. hyrcanus (3,5); and 4) absence of widespread biological and chemical vector control measures, including effective larviciding in flooded rice fields (8).

Habitat and breeding site preferences of malaria vectors may play a major role in the differing epidemiologies of local P. falciparum malaria and rice-field–dependent, exophilic and endophilic P. vivax malaria. Possible reasons for the decline in annual malaria cases after 2002, especially in endophilic P. falciparum malaria not dependent on rice fields, may include the introduction of insecticide-treated bednets, increased indoor spraying, and improved treatment and health education (7,8), as well as inhibiting climatic conditions (e.g., the extraordinarily cold 2005 spring/summer season). Current P. vivax malaria incidence rates indicate that future control efforts should emphasize large-scale management of potential mosquito breeding sites in rice-growing areas, including biological or chemical larviciding or both. The effectiveness of personal protection from exophilic P. vivax malaria vectors such as A. hyrcanus may be enhanced by simultaneous use of skin repellents and insecticide-treated clothing (14,15).