paper on stability revised Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 19 Original Article Stability and Wash Resistance of Local Made Mosquito Bednets and Detergents Treated with Pyrethroids against Anopheles stephensi *H Vatandoost, E Ramin, Y Rassi, MR Abai Department of Medical Entomology and Vector Control, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran (Received 7 Jun 2009; accepted 5 Sep 2009) Abstract Background: We aimed to evaluate different fibres of bednets impregnated with various pyrethroids. The stability of insecticide on the bednet was measured using different methods of washings as well as local made detergents. Methods: The entire test was carried out according to the WHO-recommended methods. In addition, the impact of the numbers of washes on the stability of the insecticides was determined. Permethrin 10% (EC), deltamethrin 10% (SC), lambdacyhalothrin 2.5% (CS) and cyfluthrin 5% (EW) were used at the recommended dosages. Three different local detergents were used. Two kinds of washing methods (shaking, no shaking) were used and in each method four kinds of washings, i.e. no wash, one wash, two washes and three washes was done. The main malaria vectors, Anopheles stephensi, which is susceptible to all insecticides (BEECH strain), was tested with impregnated bednets in 3 minutes exposure time and the mortality was measured after 24 hours recovery period. Knock-down was measured as well using appropriate statistical methods. Results: Lambdacyhalothrin has saved its insecticidal impact after being washed, whereas, deltamethrin has lost its activity faster than other insecticides. Tow other insecticides had moderate effect. Golnar soap detergent has least ef- fect on the durability of insecticides, but the Shoma had the most. Whit increasing the times of washing, insecticidal effects was decreased , but shaking had no influence on the decreasing of the quality of insecticidal impact. Conclusion: Results will be useful for local people who wish to use pyrethroid-impregnated bednets with their own local made detergent and bednets. Keywords: pyrethroid, malaria vector, bednet. Anopheles stephensi Introduction Different methods for mosquito control have been proposed by investigators. An important innovation during the past decade is the wide- spread introduction of insecticidal pyrethroid- treated mosquito nets for protection against ma- laria transmission. Pyrethroids are today the only insecticides recommended for the treatment of mosquito nets. This is due to the rapid knock- down effects and high insecticidal potency of pyrethroids at low dosages combined with rela- tive safety for human contact and domestic han- dling. For the treatment of net, WHO lists the insecticide products which have been passed the WHOPES including alpha-cypermethrin 10% SC, cyfluthrin 5% EW, deltamethrin 1% SC and WT 25%, etofenprox 10% EW, lamb- dacyhalothrin 2.5% CS, permethrin 10% EC (WHO 1997, 2002, Zaim et al. 2000). The concentration, which is recommended, depends on texture of net, but the different dos- ages have been proposed for their effective- ness against malaria vectors. Due to operational use of ITNs for malaria control is now advo- cated as a component of Roll Back Malaria initiative led by the WHO. Iran has been clas- sified into four different strata for malaria epide- *Corresponding author: Dr Hassan Vatandoost, E-mail: hvatandoost@yahoo.com Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 20 miology and vector control (Raeisi et al. 2004). The disease is a major health problem in south- east of Iran. It is unstable with two seasonal peaks mainly in spring and autumn. Outbreaks usually occur after rainy season. Southeastern of Iran includes the provinces of Sistan and Balu- chistan, Hormozgan and the tropical areas of Kerman provinces are characterized by "refrac- tory malaria" (Manou-chehri et al. 1999). In this part of the country six anopheline mosquitoes including Anopheles culicifacies, An. stephensi, An. dthali, An. fluviatilis, An. superpictus, and An. pulcherrimus are known to be the malaria vectors (Zahirnia et al. 1998, Vatandoost 2001, Zahirnia et al. 2001, Naddaf et al. 2003, Enayati et al. 2003, Vatandoost and Moinvaziri 2004, Vatandoost and Borhani 2004, Vatandoost et al. 2004, Vatandoost et al. 2005, Vatandoost et al. 2005, Hanafi-Bojad and Vatandoost 2006, Vatandoost et al. 2006 a, b, Oshaghi et al. 2006 a, b, Davari et al. 2006). According to the na- tional strategic plan the use of impregnated bed net and recently Long Lasting Impregnated Nets (LLITN) is the one important objective (Ministry of Health, unpublished data). In this study, we aimed to evaluate differ- ent fibres of bednets impregnated with various pyrethroids. The stability of insecticide on the bednet was measured using different methods of washings as well as local made detergents. Materials and Methods The supply/material requirements for insec- ticide treatment of nets The supply were water, insecticide for- mulation, measuring device for insecticide (mi- cropipette) and water (measuring cylinder), con- tainer to dip the net (s) and to collect insecti- cide drips after dipping, rubber gloves and pro- tective clothing including a face-mask, spray equipment when nets are sprayed. Pyrethroid insecticides Suspension concentrate formulation (SC) of deltamethrin (%10) from Aventis Company at the dosage of (25 mg/m2), emulsifiable con- centrate formulation (EC) of permethrin (10%) from Aventis Company at the dosage of (500 mg/m2), suspension concentrate formulation (SC) of lamabdacyhalothrin (2.5%) from Zeneca Company, at the dosage of (20 mg/m2), emul- sifiable oil in water formulation (EW) of cy- fluthrin (5%) from Bayer Company at the dos- age of (50 mg/m2) were used at the recom- mended dosages. Detergents Local made detergents such as wash ma- chine powder named SHOMA, handle clothes wash powder named RAKHT and handle clothes wash soap named GOLNAR were used through the study. Nets Local made, nylon net with mesh size of 156 holes per square inch were used and impregnated with recommended dosage of pyrethroids. There was no information about ISO and stability on the local made net. Bioassay tests For determination of biological efficacy of pyrethroids on treated mosquito nets there are three methods recommended by WHO as follows: test using WHO holding and expo- sure tubes as used for adult susceptibility test, test using WHO cones, test using the netting apparatus with wire frame. In this test, we fol- lowed the bioassay test with cones methods as described below (WHO 2005). Composition of test kit: Conical cham- bers of transparent plastic,8.5 cm in diameter at the bas and 5.5 cm high, two glass (or plastic) aspirator tubes of 12 mm internal diameter, together with 60 cm of tubing, and mouthpiece, one role of self-adhesive plastic tape or one sheet of label tag, Instruction sheet, 3 sheets of log-probit papers for plotting regression line for calculating LT50, using variable times with constant concentration, counter, to count the mosquito while releasing in the cones or calculating the knock-down). Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 21 Treatment of netting: Pieces of 25 x 25 cm of netting material will be fold and put in a disposable plastic Petri dish and a pipette on the net will drop carefully and homogene- ously required diluted formulation. Netting will be then soaked carefully for few seconds with fingers, protected by plastic gloves, so that all insecticide solution will be absorbed and nothing left in the Petri dish. Net sample will be left in the same dish to dry. Ideally the treated nets shall be used in 1 to 3 d, but not later than 1 wk after treatment. Separate Petri dishes are used for treatment of each net, and later disposed off properly. Net samples will be treated the day before bio-assay and stored at the refrigerator (WHO 2005) (Fig.1). Fig. 1. Treatment of netting (original) Bioassay One to 3 d after treatment of the netting materials and 24 h after each washing, as well as after dipping insecticide treated nets, the netting sample was subjected to standard WHO bioassays (3 minute exposure under WHO cones, using 1 to 3 d old, non blood fed, standard susceptible Anopheles females (BEECH strain). Four cones gently fitted on the net. Five female mosquitoes introduced at a time in each cone with 8 replicates per net sample (40 mosquitoes tested). Time interval between each set of a “4 cone” was as brief as possible. Mosquitoes from the first 4 cones, tested and were grouped in one plastic cup (n=20). Knock Down (KD) was recorded at regular interval of time during the 20 to 30 min, following exposure, starting once the fourth cone (in each set) was transferred to the cup and ending when about 80% of mosquitoes were KD, stopping in any case after 60 min. Sucrose provided to each cup, added on a cotton plug. In addition to KD rate at 60 min post-expo- sure, mortality recorded after 24 h (Fig. 2). Fig. 2. Bioassay test in conical (original) Study the physical removal of the insecti- cide during washing Washing with no shaking: Insecticide- treated net samples individually introduced in 1 L beakers containing 0.5 litter deionised water, with 2 gram/litter detergent added just before and fully dissolved and left for 20 min without any shaking. Water maintained at 30 °C during exposure to detergent and rinsing. Then, samples were removed and rinsed twice for 10 min in clean still water (without shaking). Solu- tion changed and beaker decontaminated after every wash (WHO 2005, Fig. 3). Wash with shaking: Net samples indi- vidually introduced in 1l glass bottles contain- ing 500 ml deionised water, with 2 g/l de- tergent added just before and fully dissolved. Bottle immediately introduced into a water bath at 30 °C and shacked for 20 min at 155 move- ments per minute. They immediately rinsed twice during 10 min at the same agitation speed (Fig. 4). In both cases, pH of the washing bath ac- Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 22 curately measured. Comparisons made between no wash, 1-, 2-, and 3-times washed nets. Fig. 3. Washing of nets with different detergents (original) Fig. 4. Washing of nets with shaking (original) Test condition Tests carried out ideally at 25±2 °C and 70-80% relative humidity (RH); never at temperature higher than 30 °C. Interpretation of the test results Percentage mortality was recorded af- ter 24 h recovery period on the report form. If the control mortality was between 5-20%, the percentage mortality was corrected by Abbott’s correction. For example if the mortality in the con- trol was 10% and mortality at discriminating concentration was 80%, then the corrected mortality would be 78%. If control mortali- ties exceed 20%, the results should be recorded and test should be repeated again. For calcu- lating KD50 the probit analysis as described by Finney (1971) was used. Statistical methods were used for data analysing using SPSS programme. There were significant difference between variables when P< 0.05%. Results Results of tests with permethrin, deltame- thrin, lambdacyhalothrin and cyfluthrin are ta- bulated in Tables 1-4. Results of permethrin exhibited that there was significant difference between mortalities washed by Rakht deter- gent, by shaking and no shaking methods and two type of washing (P< 0.01). The times of washing also affect on the stability of perme- thrin. Washing impregnated bednets whit del- tamethrin by Rakht detergent, exhibited that no shaking method was similar in mortality rate with other washing method, whereas, in no shaking method, a significant difference was observed between no wash and other washing times (P< 0.01). Washing procedure using lambdacyhalothrin with Rakht detergent, ex- hibited that all washing stages had significant distinction. Additionally, in no shaking method, a significant difference was observed between no wash and three washes. In shaking method, a significant difference was observed be- tween different washes (P< 0.01). Cyflutrhin impregnated nets whit Rakht detergent, showed significant difference in the mortality rate, either in different stages of wash- ing or in both two methods. Washing the same nets whit soap detergent, only washing in no shaking method, had a significant difference in mortality rate between no wash and other stages of washing (P< 0.01). Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 23 Table 1. Mortality rate of An. stephensi in contact to impregnated bednets with permethrin (500 mg/m2) (EC) (%10) in process of washing whit three detergents in different stages of washing with two different kinds of washing Mortality ± SE Shoma Soap Rakht Detergent Kind of wash 50 ± 6.8 59.32 ± 6.4 72.4 ± 5.9 No wash 19.23 ± 5.5 91.93 ± 3.5 72.2 ± 6.1 One wash 15.25 ± 4.7 96.77 ± 2.2 81.66 ± 5 Two washes 13.33 ± 4.4 93.33 ± 3.2 82.45 ± 5 Three washes No Shaking 61.67 ± 6.3 67.27 ± 6.5 51.72 ± 6.6 No wash 38.33 ± 6.3 94.83 ± 2.9 49.1 ± 6.7 One wash 36.67 ± 6.2 89.83 ± 3.9 67.85 ± 6.2 Two washes 21.67 ± 5.7 78.69 ± 5.2 68.42 ± 6.2 Three washes Shaking Table 2. Mortality rate of An. stephensi in contact to impregnated bednets with deltamethrin (25 mg/m2) (SC) (%10) in process of washing whit three detergents in different stages of washing with two different kinds of washing Mortality ± SE Shoma Soap Rakht Detergent Kind of wash 57.63 ± 6.4 54.24 ± 6.5 48.27 ± 6.6 No wash 62.07 ± 6.4 52.54 ± 6.5 16.7 ± 4.8 One wash 42.37 ± 6.4 20.69 ± 5.3 16.1 ± 4.9 Two washes 36.06 ± 6.1 5 ± 2.8 11.86 ± 4.2 Three washes No Shaking 88.33 ± 4.1 54.17 ± 7.2 47.27 ± 6.7 No wash 17.24 ± 5 25.45 ± 5.9 16.67 ± 4.8 One wash 8.93 ± 3.8 23.73 ± 5.5 15 ± 4.6 Two washes 8.33 ± 3.6 6.78 ± 3.3 13.33 ± 4.4 Three washes Shaking Table 3. Mortality rate of An. stephensi in contact to impregnated bednets with lambdacyhalothrin (20 mg/m2) (EC) (%2.5) in process of washing detergents in different stages of washing with two different kinds of washing Mortality ± SE Shoma Soap Rakht Detergent Kind of wash 91.80 ± 3.5 91.67 ± 3.6 79.31 ± 5.3 No wash 100 ± 0 100 ± 0 78.9 ± 5.4 One wash 100 ± 0 100 ± 0 78.69 ± 5.2 Two washes 100 ± 0 100 ± 0 56.36 ± 6.7 Three washes No Shaking 95 ± 2.8 89.47 ± 4.1 83.05 ± 4.9 No wash 100 ± 0 100 ± 0 71.19 ± 5.9 One wash 100 ± 0 100 ± 0 62.59 ± 6.3 Two washes 100 ± 0 100 ± 0 37.29 ± 6.3 Three washes Shaking Table 4. Mortality rate of An. stephensi in contact to impregnated bednets with cyfluthrin (50 mg/m2) (EC) (%5) in process of washing detergents in different stages of washing with two different kinds of washing Mortality ± SE Shoma Soap Rakht Detergent Kind of wash 96.49 ± 2.4 80 ± 5.2 89.65 ± 4 No wash 86.67 ± 4.4 63.33 ± 6.2 87.27 ± 4.5 One wash 83.93 ± 4.9 51.66 ± 6.4 81.35 ± 5.1 Two washes 60.34 ± 6.4 53.33 ± 6.4 82.14 ± 5.1 Three washes No Shaking 83.87 ± 4.7 76.67 ± 5.4 89.83 ± 3.9 No wash 33.33 ± 6.1 75.86 ± 5.6 85.96 ± 4.6 One wash 15 ± 4.6 67.24 ± 6.2 84.74 ± 4.7 Two washes 16.67 ± 4.8 63.33 ± 6.2 82.54 ± 4.8 Three washes Shaking Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 24 Discussion To determine the resistance of impreg- nated bed nets with different pyrethroids us- ing washing, shaking and no shaking proce- dure, the malaria vectors, An. stephensi (BEECH strain) was used. Four pyrethroids i.e.; permethrin, deltamethrin, lambdacyhalothrin and cyfluthrin were employed. Local made bednet was impregnated with pyrethroids as mentioned above. Three main important deter- gents, which are used frequently in the coun- try, were used for washing. Results showed that there was signifi- cant difference between mortalities of mosquito when using permethrin and washed by Rakht detergent, shaking and no shaking methods and two type of washing (P< 0.01). This difference has been observed es- pecially in one wash which shaking method; the insecticide removed from the nylon nets. As it is shown in tables there was no significant difference in mortality among dif- ferent stages of washing in no shaking method, but there was significant differences between one wash whit two wash or three wash in shaking method (P< 0.05). While washing the impregnated bed- nets with permethrin using soap, there had been a significant reduction only between two washes in shaking and no shaking methods (P< 0.05). There is a significant difference between washing and no washing stages in no shak- ing method (P< 0.01). The results also ob- served in shaking method with increasing in mortality rate (P< 0.01). A difference has been observed between one wash and two wash using Shoma (P< 0.01). It is observed the permethrin stability on nylon bednets using Shoma is maintained and shaking method had no effect on its re- duction, however the number of washing up to three times was effective. The stability of permethrin is reduced whit two washes using soap, although shaking had no effect. Impregnated bednets washed with Rakht using deltamethrin caused no significant differ- ence in mortality rate, whereas, a significant difference has been observed between no wash and other washing times (P< 0.01). Rakht detergent reduced deltamethrin ef- ficacy, A significant decrease has been ob- served in mortality in two washes and three washes compared whit no wash stage (P<0.01). In shaking method, a significant decrease in all stages of washing was met in comparison to no wash stage. (P< 0.01). Therefore, soap was able to decrease the mortality ratio in im- pregnated bednets with deltamethrin. When de- ltamethrin impregnated bednets was washed by Shoma detergent, an obvious reduction was seen in each stages (P< 0.01). More reduc- tion in mortality also observed using shaking. Shaking method whit Shoma decreased the mortality. It was clear that use of soap de- creases the stability of this insecticide, how- ever shaking had no effect. Washing the lambdacyhalothrin impreg- nated bednets with Rakht exhibited all wash- ing stages had significant effect. In shaking method, a significant difference has been ob- served between no wash, two and three washes (P< 0.01). Soap and Shoma detergents resulted an increase up to 100% in mortality. The sta- bility of lamdacyhalothrin insecticide has been reduced by the use of Rakht detergent. The number of washing and shaking method was also effective. Cyflutrhin impregnated nets which was washed with Rakht, no significant difference was observed in the mortality rate, in any time of washing and methods. Washing the same nets whit soap, only washing in no shaking me- thod, had a significant difference in mortality rate (P< 0.01). Shoma, exhibited a significant difference between one wash, wo washes and three washes (P< 0.01). A significant differ- ence in mortality ratio in no wash, two and three wash stages in no shaking method was observed (P< 0.01). Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 25 In conclusion, washing by Shoma de- tergent decreased the mortality rate in An. stephensi and more intensive decreases were observed in shaking method. A decrease in the stability of cyfluthrin was observed using Shoma. In addition, both shaking and number of washing has more ef- fect. Rakht was not able to decreased the sta- bility of cyfluthrin. Residual effect of pyrethroid impregnated bednets reduced due to UV light, dust, fog- ging, weather condition, washing method, type of insecticide (Rozendaal 1989). Kayedi et al (2008) found that washing is more effective than UV light for degradation of insecticide on net. Many fields research exhibited that if pyrethroid impregnated bednets was not ex- posed to washing, the residual effect of in- secticide will be remained up to 6 to 12 months. This residual effect depends on type and quanti- ties of insecticide used as well as type and characteristics of bed net. In practice, washing methods, type of detergents, the numbers and method of washing, are not as the same as in different parts of the world. It is determined that remaining soap on nets will demolish the molecular structure of pyrethroids (WHO 1989). For instance, the number of washing in Suri- nam is weekly (Rozendaal, 1989), once every two weeks in Gambia (Snow 1987) and annu- ally in China (Zuzi 1987) was documented. Re- sults of bioassay in different parts of the world are vary. This difference was due to formula- tion of insecticide, species of Anopheles, sus- ceptibility level of mosquito, the time of expo- sure, and texture of bednet, and type of test. (Yaghoobi et al. 2006, Kazemi et al. 2007). In this study, results showed that stabil- ity of permethrin impregnated bednets using Shoma decreased and the numbers of wash- ings up to three times caused more instability. It should be noted that the method of wash- ing (shaking and no shaking had no signifi- cant effect on this phenomenon. The studies for measuring the washing effects on the stability of permethrin showed that washing with washing-machine powder and soap detergent in 50 ˚C, significantly re- moved the effectiveness of permethrin. The results of bioassay test using WHO holding tubes in 30 second exposure, the mortality rate in no wash, one wash, two washes, and three washes were 100%, 95%, 10% and 0%, respectively. The results of washing in cold water were significantly different. The net sam- ples had been impregnated with permethrin at 63% g/m2, showed even 100% mortality after 10 times of washing with soap and cold water (Schreck et al. 1978). During the tests of nylon bednets impregnated with permethrin after seven weeks of impregnation against An. sinensis, the KD50, and KD 95% were esti- mated, 13' 51" and 21' 1" respectively, and knock-down starting time was seven minute after exposure (Jinijiang et al. 1988). The next step of this study was focused on washing of impregnated nets with deltame- thrin. Results showed that stability of deltame- thrin on nets, decreased significantly by using soap an method of washing had not effect, but increasing the numbers of washing up to three times had significant effect. Washing of deltamethin impregnated bed net with soap increased the KD50 . Miller et al (1991) showed that net im- pregnated with deltamethrin washed three times, indicated no signs of the insecticide residues at the end of the processing. Our study revealed that washing of lamb- dacyhalothrin impregnated bednets by Rakht reduced the effectiveness of insecticide. The number and type of washing had significant ef- fect on mortality. Millers et al. (1991) showed that washing impregnated bednets with lambdacyhalothrin for 3 times decreased the effectives of insecticide. Rafinejd et al. (2008) used three meth- ods of bioassay tests against An. stephensi. They found that Permanet® was more effi- cient than Olysetnet® net. Results on ITNs showed that deltamethirn and permethin were more effective than bifenthrin and etofenptorx Iranian J Arthropod-Borne Dis, (2009), 3(1): 19-28 H Vatandoost et al: Stability and Wash Resistance … 26 Result of this study showed that a de- crease in the stability of cyfluthrin by using Shoma, also both shaking and number of wash- ing has been effective, while using Rakht de- tergent are not able to decrease the stability of cyfluthrin. Finally statistical analysis to test the inter- action of four pyrethroids, three detergents and 2 types of washing showed that the stability of permethrin using Shoma and deltemethrin us- ing soap with two type of washing decreased. The stability of lambdacyhalothrin with Rakht and shaking method reduced. The stability of cyfluthrin using Shoma has significantly re- duced. It should be emphasized that the num- ber of washing had negative effect. Results of tests revealed that lambdacy- halothrin more than other insecticides has saved its insecticidal effect after being washed, on the contrary, deltamethrin lost its effectiveness faster than other insecticides. Permethrin and cyfluthrin had moderate effect. Washing by soap had no more effect on the residue of insecticides than other two de- tergents. Increasing in the numbers of washing had significant effect on insecticidal activity. With increasing the number of washing these figures was more significant. Shaking has no overall influence on the decreasing of the qual- ity of insecticidal effect. Monitoring and eva- luation of impregnated bednet in the field condition for adverse effect of washing using different detergents is vital for implementation of any impregnated bednet. 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