The naturally derived insecticide spinosad is highly toxic to Aedes and Anopheles mosquito larvae

Spinosad is a naturally derived biorational insecticide with an environmentally favourable toxicity profile, so we investigated its potency against mosquito larvae (Diptera: Culicidae). By laboratory bioassays of a suspension concentrate formulation of spinosad (Tracer), the 24 h lethal concentration (LC50) against Aedes aegypti (L.) third and fourth instars was estimated at 0.025 p.p.m. following logit regression. The concentration-mortality response of third- and fourth-instar Anopheles albimanus Weidemann did not conform to a logit model. The LC50 value of spinosad in Anopheles albimanus was 0.024 p.p.m. by quadratic linear regression. A field trial in southern Mexico demonstrated that spinosad 1 p.p.m. compared with the standard temephos (Abate) 1% granules 100 g/m3 water prevented Ae. aegypti breeding in plastic containers of water for 8 weeks; at 10 p.p.m. spinosad prevented breeding for > 22 weeks. In another field trial, spinosad at 5 p.p.m. and temephos both completely eliminated reproduction of Ae. aegypti for 13 weeks. In contrast, the bacterial insecticide Bacillus thuringiensis var. israelensis (Bti, Vectobac) AS) performed poorly with just 2 weeks of complete inhibition of Ae. aegypti breeding. Spinosad also effectively prevented breeding of Culex mosquitoes and chironomids in both trials to a degree similar to that of temephos. We conclude that spinosad merits evaluation as a replacement for organophosphate or Bti treatment of domestic water tanks in Mesoamerica. We also predict that spinosad is likely to be an effective larvicide for treatment of mosquito breeding sites.     

Use of granulated fertilizers with Actellic EC 50 insecticide in the control of mosquito larvae

Granulated fertilizers [ammonium nitrate, synthetic fertilizer] were used as carriers to prepare an insecticide granulate suitable for the control of Aedes cantans and Aedes vexans mosquito larvae under field conditions. The insecticide granulate was obtained by mixing 1 volume unit of Actellic EC 50 with 50 volume units of fertilizer. The optimal dose required to ensure and effective control of Aedes mosquito larvae was 2--5 g of granulate per 1 m3 of water [i.e. 2--5 kg/ha per each 1- cm depth of water] in hatching areas with a relatively clean water or during periods of slow larval growth and development, and 10 g of granulate per 1 m3 of water for hatching places polluted with organic substances or for periods of accelerated larval growth during summer months. The described Actellic EC 50 application practice ensures a complete survival of numerous non-target water organisms, including Tubifex species, Rhynchelmis species, molluscs, flatworms [Turbellaria], Asellus aquaticus, water mites [Hydrachna sp.] water striders (Gerris lacustris] and Dixella species larvae].     

Synergistic efficacy of botanical blends with and without synthetic insecticides against Aedes aegypti and Culex annulirostris mosquitoes.

Increasing insecticide resistance requires strategies to prolong the use of highly effective vector control compounds. The use of combinations of insecticides with other insecticides and phytochemicals is one such strategy that is suitable for mosquito control. In bioassays with Aedes aegypti and Culex annulirostris mosquitoes, binary mixtures of phytochemicals with or without synthetic insecticides produced promising results when each was applied at a LC25 dose. All mixtures resulted in 100% mortality against Cx. annulirostris larvae within 24 h rather than the expected mortality of 50%. All mixtures acted synergistically against Ae. aegypti larvae within the first 24 h except for one mixture that showed an additive effect. We conclude that mixtures are more effective than insecticides or phytochemicals alone and that they enable a reduced dose to be applied for vector control potentially leading to improved resistance management and reduced costs.     

A mosquito larvicide in Spilanthes mauritiana

The methanol extract of fresh vegetative aerial parts of Spilanthes mauritiana afforded, after repeated chromatographic separations and mosquito larvicidal bioassays, a potent mosquito larvicide N-isobutyl-2E,4E,8^E,10Z-dodeca-2,4,8,10-tetraenamide.The structure of the compound followed from spectroscopic considerations. It gave 100% mortality against third instar larvae of Aedes aegypti at 10⁻⁵ mg/ml.     

Laboratory and field evaluations of industrial formulations of Bacillus thuringiensis serovar. israelensis against some mosquito species of central Italy

Two wettable powder formulations (Bactimos and Vectobac) and a flowable concentrate (Teknar) formulation of Bacillus thuringiensis serovar. israelensis were evaluated as larvicides of Culex pipiens, Aedes caspius, and Aedes detritus. In the laboratory, the levels of susceptibility of these species to the test formulations were essentially similar and corresponded to their relative potencies; the LC₉₀ values ranged from 0.042 to 0.37 ppm. C. pipiens, A. caspius, and A. detritus, in that order, were susceptible to the biocide. Under field conditions in central Italy. Bactimos at 0.5 kg/ha gave 98% control of C. pipiens in an irrigation canal. Teknar at 1.25 liters/ha gave 86–100%, and at 2.5 liters/ha gave 90–100% control of C. pipiens in two natural ponds. Against A. caspius in salt marsh habitats, Bactimos at 0.5 kg/ha and Teknar at 2.5 liters/ha yielded complete control of the larvae, while a lower rate (0.2 kg/ha) of Bactimos, and Vectobac at 0.5 kg/ha resulted in 82–94% and 67–91% control, respectively. Higher rates (0.75 and 1.0 kg/ha) of Vectobac gave 76–100% and 98–100% control of A. caspius. Bactimos at 0.15 kg/ha gave 93–98% control of A. detritus in two salt marsh ponds. B. thuringiensis serovar. israelensis is practically economical for the control of C. pipiens, A. caspius, and A. detritus in the various biotopes in central Italy.     

Evaluation of the naturally-derived insecticide spinosad against Culex pipiens L. (Diptera: Culicidae) larvae in septic tank water in Antalya, Turkey.

The naturally-derived insecticide spinosad (Conserve SC) was evaluated against larval Culex pipiens L. (Diptera: Culicidae) under laboratory and field conditions in Antalya, Turkey. Laboratory bioassays showed that the 24 h LC50 and LC90 against late 3rd and early 4th instars were estimated at 0.027 and 0.111 parts per million, respectively, while adult emergence was eliminated at concentrations above 0.06 ppm. Larval mortality from septic tanks that were treated with spinosad at rates of 25, 50, 100, and 200 g ai/ha ranged between 22 to 78% 1 day after application. At 7 days post-treatment, larval mortality ranged from 2 to 50% and at 14 days mortality was <10% for all treatments. Larval bioassays of the water from those septic tanks treated at 100 and 200 g ai/ha resulted in an elimination of Cx. pipiens larvae 7 days after treatment. After this time, larval reduction declined to 79 and 83%, respectively, 14 days after treatment. Larval reduction in septic tanks treated at the two lowest rates (i.e. 25 and 50 g ai/ha) ranged from 14 to 74% during the 14-day study. These results indicated that spinosad can be considered an effective larvicide for treatment of septic tanks against Cx. pipiens.     

Factors affecting the efficacy of three commercial formulations of Bacillus thuringiensis var. israelensis against species of European black flies

The efficacy of three commercial formulations of Bacillus thuringiensis var. israelensis against two European black fly species was determined. The effect of seston concentration, temperature and larval size on the efficacy of the formulations was also determined. Teknar‐WDC was found to be almost four times as effective as Bactimos‐WP though only slightly more efficient than Vectobac‐AS against Simulium variegatum gp. larvae. Small larvae ( < 2.5 mm) were more susceptible to both Teknar‐WDC and Vectobac‐AS than large larvae ( > 5 mm) though no difference was seen with Bactimos‐WP. High seston concentrations both before and during bioassays significantly decreased the efficacy of all formulations. Increased temperatures increased the efficacy of all formulations.     

Laboratory and field evaluation of insect repellents as larvicides against the mosquitoes Aedes albopictus and Anopheles albimanus

Acute toxicity and persistence of three insect repellents, deet and two piperidines (AI3-35765 and AI3-37220), were evaluated against mosquito larvae of Aedes albopictus (Skuse) and Anopheles albimanus Wiedemann (Diptera: Culicidae) in the laboratory, and against natural populations of Ae. albopictus in the field. In laboratory studies, the LC50 values of the repellents for first instars ranged between 0.005 and 0.021% (Ae. albopictus) and between 0.01 and 0.014% (An. albimanus) and, for fourth instars, between 0.019 and 0.034% (Ae. albopictus) and between 0.015 and 0.024% (An. albimanus). A 0.1% concentration of deet caused 90-100% mortality in first-instar Ae. albopictus for 4 weeks, whereas AI3-35765 and AI3-37220 at the same concentration killed 95-100% of larvae for 12 weeks and 98-100% of larvae for 33 weeks post-treatment, respectively. Deet and AI3-35765 at 0.1 % concentration resulted in complete mortality of first-instar An. albimanus for 3 weeks post-treatment, whereas AI3-37220 resulted in 91-99% larval mortalities for 35 weeks post-treatment. A 0.1% concentration of A13-37220 provided 77-98% larval mortality for 20 weeks and 63-97% larval mortality for 12 weeks post-treatment, respectively, against fourth-instar Ae. albopictus and An. albimanus.In the field, in artificial containers, the reduction of Ae. albopictus larvae caused by deet, AI3-35765 and AI3-37220 was 88-95% for 3-4 weeks, 98-100% for 7 weeks, and 82-100% for 13 weeks post-treatment, respectively. In used tyres, the same concentration of the repellents resulted in 100% reduction of Ae. albopictus larvae for 2 weeks (deet), 4 weeks (AI3-35765) and 5 weeks (AI3-37220) post-treatment. In cemetery flower vases, Aedes spp. larvae were eliminated for 4 weeks (deet) and 6 weeks post-treatment by both A13-35765 and AI3-37220. These topical repellents (particularly AI3-37220) have good potential for development and use in the management of container-inhabiting mosquitoes because they deter oviposition and kill larvae.     

Aerial ultra-low-volume application of naled: impact on nontarget imperiled butterfly larvae (Cyclargus thomasi bethunebakeri) and efficacy against adult mosquitoes (Aedes taeniorhynchus)

We assessed the exposure and acute toxicity of naled, applied aerially as an ultra-low-volume spray for mosquito control, on late instar larvae of the Miami blue (Cyclargus thomasi bethunebakeri) (Comstock and Huntington 1943) (Lepidoptera: Lycaenidae), an imperiled South Florida butterfly. We concurrently evaluated the control efficacy against caged adult female salt-marsh mosquitoes (Aedes taeniorhynchus) (Wiedemann 1821) (Diptera: Culicidae). This 3-yr study was conducted in north Key Largo (Monroe County, FL) beginning in 2006. The field trials incorporated 15 sampling stations: nine in the target spray zone, three in the spray drift zone at varying distances from the target zone, and three in the control zone not subjected to naled spray drift. A total of six field spray trials were completed, three at an altitude of 30.5 m (100 feet), and three at 45.7 m (150 feet). For all trials, the ultra-low-volume application of Trumpet EC insecticide (78% naled) at a rate of 54.8 ml/ha (0.75 fl. oz/acre) was effective in killing caged adult mosquitoes in the target zone. Butterfly larvae survival was significantly reduced in the spray zone compared with drift and control zones. Analysis of insecticide residue data revealed that the mortality of the late instar butterfly larvae was a result of exposure to excess residues of naled. Additional research is needed to determine mitigation strategies that can limit exposure of sensitive butterflies to naled while maintaining mosquito control efficacy.     

The effect of Brugia pahangi infection on survival of susceptible and refractory species of the Aedes scutellaris complex

Life table statistics were used to examine the survival functions of filarial susceptible and refractory species of the Aedes scutellaris (Walker) group of mosquitoes, following infection with high and moderate doses of Brugia pahangi (Buckley & Edeson). Survivorship curves and hazard function curves were generated, and the median survival times and the proportions of mosquitoes surviving beyond the extrinsic incubation period of the parasite were determined. In the susceptible populations of Aedes polynesiensis Marks, Ae. pseudoscutellaris (Theobald) and Ae.tabu Ramalingam & Belkin a dose-response relationship was detected between parasite load and mortality. This relationship was characterized by a significant reduction in the proportions of infected female mosquitoes surviving at days 1 and 9 postinfection, reduction in the median survival times and an increase in the hazard rates as the infectious dose increased. The survival of the refractory species, Ae.alcasidi Huang and Ae.katherinensis Woodhill was not significantly affected by the infection. A positive correlation between microfilaraemia in the vertebrate host and parasite load in the susceptible mosquito populations was also observed. Regression analysis of the number of parasites recovered from susceptible mosquitoes at the time of death showed that mosquitoes at highest risk of dying harboured from 11.6 to 19.4 infective larvae when fed on a gerbil with sixty-five microfilariae per 20 microliters blood; this resulted in 34.4-40.2% mortality by day 9 postinfection. A mean number of 32.6-46.9 infective larvae was observed when these populations were exposed to a gerbil with a microfilaraemia of 150 mf/20 microliters and resulted in 72.8% to 80% mortality in these populations. Viable infective larvae were recovered from infected mosquitoes up to 50 days postinfection.     

Chemical Variation in Piper aduncum and Biological Properties of Its Dillapiole‐Rich Essential Oil

The essential oils of the specimens of Piper aduncum that occur in deforested areas of Brazilian Amazon, North Brazil, are rich in dillapiole (35–90%), a derivative of phenylpropene, to which are attributed biological properties. On the other hand, the oils of the specimens with occurrence in the Atlantic Forest, and Northeastern and Southeastern Brazil, do not contain dillapiole, but only terpene compounds such as (E)‐nerolidol and linalool. One specimen existing in the Amazon was hydrodistilled. The obtained oil was fractioned on a silica chromatographic column, resulting in fractions rich in dillapiole (95.0–98.9%) utilized for analyses by GC and GC/MS, structural characterization by NMR, confirmation of their biological properties, and to obtain the isomer isodillapiole. Dillapiole showed a fungicide action against the fungus Clinipellis perniciosa (witches' broom) by inhibition of its basidiospores, in concentrations ranging from 0.6 to 1.0 ppm. The larvicide and insecticide actions of dillapiole were tested against the larvae and the adult insects of Anopheles marajoara and Aedes aegypti (malaria and dengue mosquitoes), resulting in mortality of the larvae (48 h, 100%) at a concentration of 100 ppm, and mortality of the insects (30 min, 100%) at a concentration of 600 ppm. The isomeric isodillapiole showed no significant activity in the same biological tests.     

Towards the understanding of tetrahydroquinolines action in Aedes aegypti: larvicide or adulticide?

Aedes aegypti is an important vector of arboviruses such as dengue, yellow fever, chikungunya and Zika. Among the various types of insecticides used to combat this vector, the insect growth regulators have been developed and recommended for control of their larvae. In this work compounds with proven regulatory action, tetrahydroquinolines will be studied. These regulators act on the hormones responsible for the insect development. Ecdysone, one of the main hormones involved in this process has a specific receptor (EcR), where tetrahydroquinolines derivatives can bind, disrupting the normal action of this hormone, because they have structure similar to hormone 20-hydroxyecdysone (20E). In addition, studies show that this class of compounds interacts strongly in the potassium channel activated by calcium (BK channel). Thus, the goal is to study the action of compounds (tetrahydroquinolines) as insecticides and evaluate their larvicidal action (action on the ecdysone receptor) or adulticide (action on the BK channel) through homology modelling techniques, molecular docking and molecular dynamics simulations and aiming to propose a compound that presents both actions (larvicide / adulticide).     

Pyrethroid resistance in Aedes aegypti and Aedes albopictus from Port‐au‐Prince,Haiti

In Port‐au‐Prince, Haiti, the status of insecticide resistance has not recently been evaluated for Aedes aegypti (L) and Aedes albopictus (Skuse) populations. No prophylactics exist for dengue, so prevention is only through vector control methods. An earthquake occurred in Haiti on January 12, 2010, with a magnitude of 7.0 Mw that devastated the area. Dengue became a major concern for the humanitarian relief workers that entered the country. Bottle bioassays were conducted in the field on adult mosquitoes reared from larvae collected from the grounds of the U.S. Embassy and from an adjacent neighborhood in eastern Port‐au‐Prince, Haiti. At the CDC, Fort Collins, CO, bioassays, molecular, and biochemical assays were performed on mosquitoes reared from field‐collected eggs. A small percentage of the population was able to survive the diagnostic dose in bioassays run in Haiti. Mosquitoes tested at the CDC demonstrated no phenotypic resistance. A variety of factors could be responsible for the discrepancies between the field and lab data, but temperature and larval nutrition are probably most important. Knowledge of localized resistance and underlying mechanisms helps in making rational decisions in selection of appropriate and effective insecticides in the event of a dengue outbreak.     

Assessing the Potential of Entomopathogenic Nematodes to Control the Grape Root Borer Vitacea polistiformis (Lepidoptera: Sesiidae) Through Laboratory and Greenhouse Bioassays

Seventeen entomopathogenic nematode species and strains were evaluated for virulence to the grape root borer, Vitacea polistiformis (Harris) in laboratory and greenhouse bioassays. Heterohabditis bacteriophora strain GPS11 and H. zealandica strain X1 produced a larval mortality rate of over 85% of larvae embedded in the root cambium in laboratory bioassays. The nematode species H. marelata and H. bacteriophora strain Oswego produced mortality rates of over 75%. Of the Steinernema species tested, S. carpocapsae strain 'All' performed the best with a mortality rate of 69%. All other nematode species and strains tested, with the exception of S. bicornutum , produced some degree of larval mortality. In the greenhouse bioassays, 93% control was achieved with H. zealandica strain X1 applied at 4 ×109 infective juveniles (IJs) acre1 -1 (9.88 ×10 9 IJs ha -1 ). H. bacteriophora strain GPS11 successfully reproduced in grape root borer larvae. The numbers of IJs produced within infected larvae were related to larval size. The survival rate of neonate larvae on grape root sections was 61%, which thus provides a means to rear the neonate larvae for bioassays.     

啶虫脒对淡色库蚊幼虫的致死和亚致死影响

啶虫脒是日本曹达公司新开发的一种氯代烟碱类杀虫剂,为了探讨其用于蚊虫幼虫控制的可能性,我们在室内用浸渍法测定了啶虫脒对淡色库蚊幼虫的致死和亚致死影响,结果表明,淡色库蚊幼虫对啶虫脒较敏感,幼虫的死亡高峰出现在处理后第3天,幼虫的四个龄期中,一龄最敏感,四龄耐药力最强,二在处理后72h时的LC50值分别为0.020mg/L/升和0.296mg/L。幼虫在亚致死浓度的啶虫脒溶液作用下,发育期延长,蛹重下降。说明啶虫脒可用于蚊虫幼虫的控制。     

LETHAL AND SUBLETHAL EFFECTS OF ACETAMIPRID ON THE LARVAE OF CULEX PIPIENS PALLENS

Abstract Acetamiprid is a novel neonicotinoid insecticide invented by Nippon Soda Co., Ltd. To explore the possibility of acetamiprid as larvicide of mosquitoes, lethal and sublethal effects of acetamiprid on the larvae of Culex pipiens pallens were studied by immersion method in the laboratory. The results indicated that the larvae of Culex pipiens pallens were sensitive to acetamiprid. The mortality of larvae peaked at 72 h after treatment. The 1 st instar larvae was the most susceptible to acetamiprid, and the 4th instar larvae was the most tolerant to acetamiprid, the LC, values were 0. 020 mg/L and 0. 296 mg/L at 72 h after treatment, respectively. Sublethal concentrations of acetamiprid could delay the development of larvae and decrease the weight of pupa. We suggested that acetarniprid is a safe and effective substitute for the using larvicides of mosquitoes.     

Aedes aegypti resistance to temephos during 2001 in several municipalities in the states of Rio de Janeiro, Sergipe, and Alagoas, Brazil

For more than 30 years temephos, an organophosphate insecticide, has been the sole larvicide used in Brazil in the control of Aedes aegypti. Organophosphates were also used for adult control, being replaced by pyrethroids since 1999. In this same year the Brazilian Health Foundation started the coordination of the Ae. aegypti Insecticide Resistance Monitoring Program. In the context of this program, our group was responsible for the detection of temephos resistance in a total of 12 municipalities in the states of Rio de Janeiro (RJ), Alagoas (AL), and Sergipe (SE) during 2001. In each municipality, a pool of mosquitoes collected from different districts was used, with the exception of Rio de Janeiro city, where eight districts have been separately evaluated. Exposure of larvae to the diagnostic dose of temephos revealed resistance in all localities examined, with mortality levels ranging from 4% (Pilares district, Rio de Janeiro, RJ) to 61.9% (Campos dos Goytacazes, RJ). Quantification of mortality showed resistance ratios from 6.1 (Aracaju, SE) to 16.8 (S?o Gon?alo, RJ and Penha district, Rio de Janeiro, RJ). The national dengue control program is presently using these data to subside insecticide resistance management.     

Efficacy of Czechoslovak and Soviet Bacillus thuringiensis (serotype H-14) formulations against mosquito larvae

Laboratory and field comparisons were made with two wettable powder formulations of Bacillus thuringiensis serotype H-14 (B. t. H-14) prepared in Czechoslovakia ("Moskitur") and the USSR ("Baktokulicid"). Expressed in the international Aedes aegypti toxic units (TU X mg-1) the potency of these two test formulations was greater than that of the Institute Pasteur Standard IPS-78 (= 1,000 TU X mg-1), i.e. Moskitur had a potency of about 1,500 TU X mg-1 and the Soviet Baktokulicid 2,000 TU X mg-1. The Baktokulicid and Moskitur LC 90 values for laboratory-reared Aedes aegypti larvae were, respectively, 0.11 and 0.16 mg X l-1. The range of LC 90 values for the Czechoslovak wild-caught mosquito species of the genera Aedes and Culex was 0.14-0.31 mg X liter-1 with Moskitur, 0.11-0.41 mg X l-1 with Baktokulicid, and 0.16-0.48 mg X l-1 with IPS-78. The susceptibility of laboratory Anopheles stephensi larvae was close to that of Aedes aegypti, larvae of An. messeae required many times as much Baktokulicid (1.6 mg X l-1) and Moskitur (more than 6.4 mg X l-1) for 90% mortality as did other mosquito species. The aim of outdoor assays was to establish the minimum Moskitur and Baktokulicid rates giving a 100% control of mosquito larvae. For Ae. cantans breeding habitat in flood plain forest areas these rates ranged between 0.1-0.5 mg X l-1 (0.2-1.0 kg X ha-1), for Ae. vexans control on artificially irrigated meadows between 0.8-2.0 mg X l-1 (1.2-3.0 kg X ha-1). Consistently with laboratory bioassays, Baktokulicid gave 100% control of An. messeae 4th instar larvae at a dose as high as 3.2 mg X l-1, Moskitur gave 23.1% kill at 6.4 mg X l-1. The effect of Moskitur and Baktokulicid formulations was immediate, larvae that hatched 7-14 days posttreatment survived. The efficacy of B. t. H-14 outdoor treatments tended to markedly decrease with the larval densities exceeding 100 larvae per 1 dm2. Species of nontarget aquatic organisms, including the Diptera Chaoborus crystallinus, Mychlonyx sp. and Dixidae, were not noticeably affected by treatments with B. t. H-14 formulations used.     

Area-Wide Ground Applications of Bacillus thuringiensis var. israelensis for the Control of Aedes albopictus in Residential Neighborhoods: From Optimization to Operation

The increasing range of Aedes albopictus, the Asian tiger mosquito, in the USA and the threat of chikungunya and dengue outbreaks vectored by this species have necessitated novel approaches to control this peridomestic mosquito. Conventional methods such as adulticiding provide temporary relief, but fail to manage this pest on a sustained basis. We explored the use of cold aerosol foggers and misting machines for area-wide applications of Bacillus thuringiensis var. israelensis (VectoBac WDG) as a larvicide targeting Aedes albopictus. During 2010–2013 we performed initially open field trials and then 19 operational area-wide applications in urban and suburban residential areas in northeastern USA to test three truck-mounted sprayers at two application rates. Area-wide applications of WDG in open field conditions at 400 and 800 g/ha killed on average 87% of tested larvae. Once techniques were optimized in residential areas, applications with a Buffalo Turbine Mist Sprayer at a rate of 800 g/ha, the best combination, consistently provided over 90% mortality. Importantly, there was no significant decrease in efficacy with distance from the spray line even in blocks of row homes with trees and bushes in the backyards. Under laboratory conditions Bti deposition in bioassay cups during the operational trials resulted in over 6 weeks of residual control. Our results demonstrate that area-wide truck mounted applications of WDG can effectively suppress Ae. albopictus larvae and should be used in integrated mosquito management approaches to control this nuisance pest and disease vector.     

Spontaneous flight activity of Aedes trivittatus infected with Dirofilaria immitis

Spontaneous flight activity of Dirofilaria immitis-infected Aedes trivittatus was evaluated by using an acoustic activity system. The activity of mosquitoes infected with low numbers of filarial larvae (1-4) was similar to that of uninfected mosquitoes. However, mosquitoes infected with more than 4 larvae became more active than uninfected mosquitoes 8 days after infection. Peak flight activity (circadian) occurred at the same time in both infected and uninfected mosquitoes, but infected mosquitoes were much more active during normal periods of quiescence. Flight activity of mosquitoes infected with more than 4 larvae was suppressed on days 10 and 14 postinfection, corresponding to times of greatest disruption of the Malpighian tubules by the developing larvae.