Studies on the behaviour and control of phlebotomine sandflies using experimental houses.

Programmes for the control of phlebotomine sandflies (Diptera: Psychodidae), the vectors of leishmaniases, mainly target adults because larval breeding sites are generally unknown or inaccessible. To determine how blood-questing sandfly females enter homes and to develop means for their control, an experimental house (EH) was constructed in a village endemic for cutaneous leishmaniasis. Initially, carbon dioxide (CO2 )-baited suction traps were installed inside the EH to attract and capture sandflies. For other experiments, the windows of the EH were fitted with CO2 -baited window entrance traps (WETs) that allow each window to be considered as a separate unit. The majority of captures inside the EH and in WETs consisted of Phlebotomus sergenti, a species that enters inhabited houses relatively infrequently. Analyses of collections in WETs and in sticky traps on external walls showed that sandflies entered windows having landed previously on the wall below or either side of the window. Shelves constructed below windows significantly reduced the numbers of sandflies that entered both the EH and inhabited houses. The lining of internal walls with insecticide-impregnated fabric significantly increased mortality rates of sandflies captured inside the EH. To reduce the biting burden imposed by phlebotomine sandflies, several control measures must be integrated and sustained.

Insecticide-treated vertical mesh barriers reduce the number of biting mosquitoes.

Mosquitoes foraging for blood sources normally fly relatively close to the ground where wind velocities do not exceed their flight speed. An experiment designed to block foraging mosquitoes from reaching inhabited houses was conducted in a rural settlement flanked by agricultural fields. Mosquitoes were collected during 9 nights using 30 carbon dioxide-baited traps deployed along the external walls of six houses in the row closest to the settlement's perimeter fence. Thereafter, a deltamethrin-impregnated mesh was draped along 400 m of the perimeter fence to a height of 2 m opposite three of the monitored houses. Mosquitoes were trapped for a further 11 nights. A significant difference in the numbers of mosquitoes caught before and after the intervention was demonstrated near protected houses, whereas no significant difference was observed in catches near control houses. The percentage of Culex perexiguus (Diptera: Culicidae), an important vector of West Nile virus, was significantly lower near protected houses (13%) than around control houses (45%). By contrast, the percentage of Culex pipiens was not significantly affected (16% at experimental and 18% at control houses). Although the results presented here are preliminary, the data demonstrate the potential efficacy of vertical insecticidal barriers for mosquito control.

Exclusion of phlebotomine sand flies from inhabited areas by means of vertical mesh barriers.

Vector control constitutes an important component of integrated disease control campaigns. Source reduction is not an option for phlebotomine sand fly vectors of leishmaniasis, because larval breeding sites remain either unknown or inaccessible. Thus, all control efforts are directed against the adult sand flies, mostly attempting to limit their contact with humans. We describe experiments using an insecticide-treated vertical barrier to prevent sand flies from reaching inhabited areas of an agricultural settlement. A 400 meter long section of the peripheral fence of Kibbutz Sde Eliyahu, Jordan Valley, Israel was draped with a deltamethrin-impregnated net that is impenetrable to sand flies (polyester net, 450 holes/inch(2)). Sand flies were captured before and after construction of the barrier using CO(2)-baited CDC traps. Sand fly numbers, as monitored around three houses internal to the barrier, exhibited an 84.9% decrease once the barrier was erected (P=0.003). Concurrently, the neighboring control group of three houses, not protected by the barrier, exhibited a 15.9% increase in sand fly numbers (P=0.974). These results corroborate previous findings of field tests conducted on a smaller scale in an arid suburban setting. Campaigns for reducing the burden of sand fly bites and curtailing the transmission of leishmaniasis, should consider integrating vertical fine-mesh nets with other sand fly control measures.

Studies on the flight patterns of foraging sand flies.

Phlebotomine sand flies transmit Leishmania parasites that cause leishmaniasis in humans. We report experimental results that improve our understanding of how foraging sand flies proceed over flat or sloping ground and how they negotiate vertical obstacles. Three rows of traps were suspended at different heights on a wire fence. Those just above ground level captured 87% of all flies, traps set at one meter captured 11% while only 2% of the flies were captured in traps set two meters above ground. When traps were deployed on a vertical support wall, the mean catch per trap was much higher than for traps suspended on the fence. Traps suspended just above ground level captured 57% of all flies, traps set at one meter above ground captured 27% of the flies and even traps set at two meters captured 16% of the flies. Although, most flies were still captured close to the ground, a higher percentage reached the second and third rows of traps. Sticky traps on a vertical wall produced similar results with significantly more flies alighting on the lower sections of the trap closest to the ground. On a vertical sand fly-proof net the overall dispersal of the flies was more like on a wall than in open space. Traps suspended just above ground level captured 49%, traps set at one meter above ground captured 36% and traps set at two meters captured 15% of the flies. Following spraying of the net with deltamethrin (1%), fewer sand flies were captured but the reduction was not statistically significant. Our conclusions are that being small and frail, sand flies tend to fly close to the ground probably in order to avoid being swept away by gusts of wind. When they encounter a vertical obstacle, they proceed upwards close to the obstacle with intermittent stops. Therefore, insecticide-sprayed walls or vertical nets should be effective for controlling sand flies approaching human habitation.

Control of phlebotomine sand flies with vertical fine-mesh nets.

Insecticide-treated vertical net barriers were used to intercept foraging sand flies. Two different nets were draped on fenced enclosures (10 by 10 m; 2 m high) in the central Jordan Valley. One enclosure was draped with a deltamethrin-impregnated net (PermaNet, 225 holes/in2). The holes of this net are sufficiently large to allow sand flies to pass through but not without coming in close contact with the mesh. The other enclosure was covered with SpiderNet+ (1,240 holes/in2) and sprayed with beta-cyfluthrin. Sand flies were captured inside and outside the enclosures before and after draping with the nets using CO2-baited CDC traps or CDC light traps. Both barrier types exhibited > 90% efficacy in blocking sand flies from entering the enclosures (P < 0.01). The Spider-Net+ exhibited high efficiency even before being sprayed with insecticide because the small mesh size physically prevented flies from passing through. In Ma'ale Adumim, a 60-m-long, 2-m-high PermaNet barrier was erected to intercept sand flies approaching houses from their natural habitats. Sand flies were monitored on all sides of the barrier using CO2-baited CDC traps or CDC light traps. Results showed a 60% reduction in the mean number of sand flies trapped behind the net compared with the untreated areas adjacent to it (P < 0.05). Integrated vector control campaigns for reducing the burden of sand fly bites should consider vertical fine-mesh nets to reduce the numbers of sand flies arriving at inhabited areas.

Control of phlebotomine sandflies in confined spaces using diffusible repellents and insecticides.

The control of phlebotomine sandflies (Diptera: Psychodidae), the vectors of leishmaniasis, is directed mostly against adults as larvae develop in unknown or inaccessible habitats. In the current study we tested geraniol, a natural plant-derived product, as a space repellent and the synthetic pyrethroid prallethrin as a diffusible insecticide. Geraniol was dispersed in the air using diffusers with an electric fan and prallethrin was evaporated using electrically heated evaporators. Both substances were tested in inhabited bedrooms and in tents. Geraniol failed to effect significant reductions in the numbers of either Phlebotomus papatasi Scopoli in rooms or Phlebotomus sergenti Parrot in tents. In laboratory experiments, geraniol proved ineffective in preventing sandflies from feeding. By contrast, prallethrin was highly effective in reducing the number of sandflies in rooms as well as in tents. Exposure of sandflies to prallethrin in laboratory experiments caused 97% mortality rates. Both prallethrin and, to a lesser extent, geraniol reduced the number of Culex mosquitoes captured in tents. Electric liquid-vaporizers with 1.5% prallethrin are highly effective in protecting people from sandfly bites in confined spaces and may be useful in combating cutaneous leishmaniasis.

Raman spectroscopic studies of different forms of cholesterol and its derivatives in the crystalline state.

A Raman spectroscopic study has been carried out on a number of cholesterols and cholesterol derivatives in the crystalline state, in order to obtaine some empirical correlations between the Raman spectra and structure of each cholesterol form. Although the Raman spectra of the various cholesterols are highly complex it was found that three regions of the spectrum yield considerable information about the crystalline chain packing in each form. They are: (1) the low frequency region below 300 cm-1, giving information on the inter-and intramolecular vibrations in the cholesteryl moiety; (2) the methylene rocking/deformation region between 1400 and 1500 cm-1 giving information on chain packing in the crystalline state, and (3) the C-H stretching region between 2700 and 3100 cm-1 which appears to indicate that there is a correlation between branching in the side chains of the cholesterols, polarity of the substituent groups in the various derivatives studied and relative chain order in the packing arrangements in the crystalline state. A study of two branched chain aerosol derivatives, bis(di2-octyl) sodium sulphosuccinate and its isomer bis(di-2-ethylhexyl) sodium sulphosuccinate, indicate that branched chain amphiphiles are good Raman spectroscopic models for the cholesterols, similar to previous Raman spectroscopic studies which have found straight chain amphiphiles to be good models for more complex phospholipids.