Evaluation of the toxicity and molluscicidal and larvicidal activities of <i>Schinopsis brasiliensis</i> stem bark extract and its fractions

Santos, Clisiane C.S.; Araújo, Silvan S.; Santos, André L.L.M.; Almeida, Elis C.V.; Dias, Antônio S.; Damascena, Nicole P.; Santos, Deisylaine M.; Santos, Matheus I.S.; A.L.R. Júnior, Karlos; Pereira, Carla K.B.; Lima, Amanda C.B.; Shan, Andrea Y.K.V.; Sant'ana, Antônio E.G.; Estevam, Charles S.; Araujo, Brancilene S.

doi:10.1016/j.bjp.2014.07.006

Abstract

Dengue fever and schistosomiasis are major public health issues for which vector control using larvicide and molluscicide substances present in plants provides a promising strategy. This study evaluated the potential toxicity of the extract of hydroethanol Schinopsis brasiliensis Engl., Anacardiaceae, stem bark and its chloroform, hexane, ethyl acetate, and hydromethanol fractions against Artemia salina and Aedes Aegypti larvae and snails Biomphalaria glabrata. All of the assays were performed in triplicate and the mean mortality rates were used to determine the LC₅₀and LC₉₀ values using the probit method. The hydroethanol hydromethanol extract and fraction were free of toxicity towards A. salina(LC₅₀ > 1000 µg/ml), while chloroform fraction was moderately toxic (LC₅₀313 µg/ml); ethyl acetate and hexane fractions displayed low toxicity, with LC₅₀ 557 and 582 µg/ml, respectively. Chloroform, hexane, and ethyl acetate fractions showed larvicidal potential towards A. aegypti (LC₅₀ values of 345, 527 and 583 µg/ml, respectively), while chloroform and ethyl acetate fractions were highly toxic to B. glabrata (LC₉₀values of 68 and 73 µg/ml, respectively). Based on these findings, ethyl acetate, chloroform, and hexane fractions should be further investigated for their potential use against the vectors of dengue and schistosomiasis.

Artemia salina; Aedes; Biomphalaria; Larvicide; Molluscicide; Schinopsis brasiliensis

Introduction

Aedes aegypti L. is the vector responsible for transmitting the tropical viral infection known as dengue, dengue fever, or breakbone fever. It is considered a major public health concern because it is largely dispersed in urban areas (Porto et al., 2008Porto, K.R.A., Roel, A.R., Silva, M.M., Coelho, R.M., Schelede, R.E.J.D., Jeller, A.H., 2008. Atividade larvicida do óleo de Anacardium humile Saint Hill sobre Aedes aegypti (Linnaeus, 1762) (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 41, 586-589.). Given that 50 to 80 million people are infected with dengue anually in over 100 countries, vector control is extremely important and consists of eliminating breeding sites and applying insecticides (Lingon, 2005Lingon, B.L., 2005. Dengue fever and dengue hemorrhagic fever: a review of the history, transmission, tratment and prevention. Semin. Pediatr. Infect. 16, 60-65.; Mendonça et al., 2009Mendonça, F.A., Souza, A.V., Dutra, D.A., 2009. Saúde pública, urbanização e dengue no Brasil. Soc. Natur. Resour. 21, 257-269.). However, synthetic insecticides have been observed to have low efficiency due to resistance of insect populations (Barreto, 2005Barreto, C.F., 2005. Aedes aegypti - Resistência aos inseticidas químicos e as novas alternativas de controle. Rev. Elet. FMB 1, 62-73.).

Schistosomiasis is another major problem caused by transmission vectors. According to the World Health Organization (WHO), this ancient disease affects indiviuals over 240 million in over 78 countries (WHO, 2013). Schistosoma mansoni is the flatworm parasite responsible for most cases of infection. In the countries of South America and Central America, primarily S. mansoni uses Biomphalaria glabrata snails of the host to an intermediate to complete its life cycle (Rey, 2010Rey, L., 2010. Bases da Parasitologia Médica. Rio de Janeiro: Editora Guanabara Koogan.). Among the methods used to reduce occurrences of the disease, one promising strategy is the control of populations because malacological eliminating the vector with substances endowed with molluscicide properties interrupts the life cycle of the parasite, and thereby, disease transmission (Santos et al., 2010Santos, A.F., Sant'Ana, A.E.G., 2001. Molluscicidal properties of some species of Annona. Phytomedicine 8, 115-120.).

Dengue fever and schistosomiasis are two major public health problems that many countries, including Brazil, are seeking to solve. In this context, the use of plants to control or eradicate these and other diseases is premised on their availability and lower environmental impact, which are variables for obtaining an effective natural product. Plants are important sources of biologically active products that can be responsible for various biological actions, including the larvicidal and molluscicidal properties shown in several studies (Prophiro et al., 2008Prophiro, J.S., Rossi, L.C.N., Kanis, L.A., Santos, T.G., Silva, O.S., 2008. Estudo comparativo do efeito larvicida de extratos de frutos verdes e maduros de Melia azedarach L. (Sapindales: Meliaceae) em Aedes aegypti L. (Diptera: Culicidae) . BioAssay 3, 1-5.; Santos et al., 2012).

A previous survey of different parts of plants from northeastern Brazil revealed a high toxicity towards A. aegypti and B. glabrata (Luna et al., 2005Luna, J.S., Santos, A.F., Lima, M.R.F., Omena, M.C., Mendonça, F.A.C., Bieber, L.W., Sant'Ana, A.E.G., 2005. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J. Ethnopharmacol. 97, 199-206. ; Oliveira et al., 2006Oliveira, A.M., Humberto, M.M.S., Silva, J.M., Rocha, R.F.A., Sant'Ana, A.E.G., 2006. Estudo fitoquímico e avaliação das atividades moluscicida e larvicida dos extratos da casca do caule e folha de Eugenia malaccensis L. (Myrtaceae) . Rev. Bras. Farmacogn. 16, 618-624.). Although the chemical constituents responsible for causing this toxicity have not been identified, the pharmacological effects of these plants, e.g., molluscicidal and larvicidal activities, are known to be related to the presence of secondary metabolites such as tannins, saponins, terpenoids, steroids, and flavonoids (Treyvaud et al., 2000Treyvaud, V., Marston, A., Dyatmiko, W., Hostettmann, K., 2000. Molluscicidal saponins from Phytolacca icosandra. Phytochemistry 55, 603-609. ; Alcanfor et al., 2001Alcanfor, J.D.X., Ferri, P.H., Santos, S.C., Bezerra, J.C.B., 2001. Plantas moluscicidas no controle dos caramujos transmissores da esquistossomíase, com ênfase na ação de taninos. Rev. Patol. Trop. 30, 167-175.; Hymete et al., 2005Hymete, A., Iversen, T.H., Rohloff, J., Erko, B., 2005. Screening of Echinops ellenbeckii and Echinops longisetus for biological activities and chemical constituents. Phytomedicine 12, 675-679.; Cantanhede et al., 2010Cantanhede, S.P.D., Marques, A.M., Souza, N.S., Valverde, A.L., 2010. Atividade moluscicida de plantas: uma alternativa profilática. Rev. Bras. Farmacogn. 20, 282-288.).

Schinopsis brasiliensis Engl., Anacardiaceae, popularly known as "baraúna," "braúna," or "quebracho," is used in folk medicine to treat various diseases (Almeida et al., 2010Almeida, C.F.C.B.R., Ramos, M.A., Amorim, E.L.C., Albuquerque, U.P., 2010. A comparison of knowledge about medicinal plants for three rural communities in the semi-arid region of northeast of Brazil. J. Ethnopharmacol. 127, 674-684.). Biological studies using a methanol leaf extract from S. brasiliensis demonstrated its antioxidant, antimicrobial, and anti-inflammatory activities (Ferreira-Junior et al., 2011; Saraiva et al., 2011Saraiva, A.M., Castro, R.H.A., Risonildo, P., Cordeiro, R.P., Peixoto, S.T.J.S., Castro, V.T.N.A., Amorim, E.L.C., Xavier, H.S., Pisciottano, M.N.C., 2011. In vitro evaluation of antioxidant, antimicrobial and toxicity properties of extracts of Schinopsis brasiliensis Engl. (Anacardiaceae). African J. Pharm. Pharacol. 5, 1724-1731.), while the extract from the plant seed hydroethanol has been shown to have toxic effects against A. aegypti larvae (Souza et al., 2011Souza, T.M., Farias, D.F., Soares, B.M., Viana, M.P., Lima, G.P.G., Machado, L.K.A., Morais, S.M., Carvalho, A.F.U., 2011. Toxicity of Brazilian plant seed extracts to two strains of Aedes aegypti (Diptera: Culicidae) and Nontarget Animals. J. Med. Chem. Entomol. 48, 846-851.). Therefore, the goal of this study was to evaluate a stem bark extract from S. brasiliensis and its fractions for toxicity and molluscicidal and larvicidal activities.

Materials and methods

Collection and identification of plant material

Schinopsis brasiliensis Engl., Anacardiaceae, stem bark was collected in August 2011 in the city of Piranhas in Alagoas, Brazil, whose geographical coordinates were identified by a Garmin Forerunner GPS function (9°35'54.37" S and 37°46'08.31" W). The species was identified by the biologist Marta Maria Cristina Farias and a voucher specimen was deposited in the herbarium of the Department of Biology of the Federal University of Sergipe under the registration voucher number 24442 ASE.

Preparation of the hydroethanol extract and its fractions

The steam bark of S. brasiliensis was dried at room temperature, reduced to powder using a slicer, and then extracted by cold maceration with 90% ethanol for five days. The equipament was then filtered and concentrated on a rotatory evaporator (LS Logen Scientific, Lagos, Nigeria) under reduced pressure at 45°C to produce the hydroethanol extract (HEE). The extract (40 g) was dissolved in methanol: water (40% v/v) and successively subjected to liquid-liquid extraction with hexane, chloroform, ethyl acetate and hexane to obtain infor (HxF), chloroform (ChlF), ethyl acetate (EAF), and hydromethanol (HMF) fractions.

Phytochemical screening

Extracts and fractions (5 ml, 1 mg/ml) were qualitatively analyzed by precipitation and colorimetric methods described by Matos (2009)Matos, F.J.A., 2009. Introdução à Fitoquímica Experimental. Fortaleza: Editora UFC. to detect anthocyanins, anthocyanidins, aurones, chalcones, flavanols, flavones, flavonols and xanthones [pH-related color variation by adding sodium hydroxide (3 mol/l) and hydrochloric acid (1 mol/l)], leucoanthocyanidins and catechins (acid-base reactions followed by heating), tannins [ferric chloride precipitation (1 mol/l)], steroids and triterpenoids (Lieberman-Buchard reaction), saponins (Lieberman-Buchard reaction and foam formation) and alkaloids (Dragendorff reaction).

Toxicity assay

The toxic activity of the extract and fractions of S. brasiliensiswas assessed by the lethality test against Artemia salina Leach as described by Meyer et al. (1982)Meyer, B.N., Ferrigni, N.R., Putnam, J.E., Jacobsen, L.B., Nichols, D.E., Mclaughlin, J.L., 1982. Brine shrimp, a convenient general bioassy for active-plant constituents. Planta Med. 45, 31-34. with some modifications. A. salina eggs were incubated in cotton-filtered seawater at room temperature for 24 h, after which the larvae were collected with the aid of a light source to attract them. Approximately ten nauplii were transferred to ELISA plate wells containing 1 ml of HEE and the fraction concetrations of solutions at 1, 10, 100, and 1000 µg/ml prepared in seawater containing 1% DMSO. The control group consisted of only the solvent and larvae, and all assays were performed in triplicate. The dead larvae were counted after exposure for 24 h.

Larvicidal assay

Third stage larvae were A. aegypti mosquitoes used to evaluate the larvicidal activity of the HEE and its fractions using the methodology described by the World Health Organization (WHO, 2005) modified by the Ribeiro et al. (2009)Ribeiro, K.A.L., Carvalho, C.M., Molina, M.T., Lima, E.P., Montero, E.L., Reys, J.R.M., Oliveira, M.B.F., Pinto, A.V., Santana, A.E.G., Goulart, M.O.F., 2009. Activities of naphthoquinones against Aedes aegypti (Linnaeus, 1762) (Diptera:Culicidae), vector of dengue and Biomphalaria glabrata (Say, 1818), intermediate host of Schistosoma mansoni. Acta Trop. 111, 44-50.. Larvae were exposed to initially standard solutions of the HEE and its fractions (1000 µg/ml, in distilled water containing 1% DMSO). That ismortalities exceeded 90%, with further tests concentrations lower (100, 250, and 500 µg/ml) were performed to estimate the lethal concentration. Positive controls were treated with temephos [(O,O'-(thiodi-4,1-phenylene) bis (O,O-dimethylphosphorothiolate)], which was obtained as a commercial sample (3 µg/ml) from Funasa, Brazil. The bioassays were performed in triplicate for each experimental group consisting of 25 larvae, which were placed in contact with 50 ml of each test solution. The mortality or paralysis of the larvae was recorded after 24 and 48 h of exposure. Control tests with distilled water containing 1% DMSO were also performed.

Molluscicide assay

The procedure described by Santos and Sant'Ana (2001) was utilized to evaluate the molluscicidal activity. Test solutions of the HEE and fractions were prepared at different concentrations (25, 50, and 100 µg/ml) using dechlorinated water containing 0.1% DMSO. Treatment with 3 µg/ml of niclosamide^(r) (Oliveira and Paumgartten, 2000) acted to the positive control, while the negative controls were exposed to dechlorinated water containing 0.1% DMSO only. Five snails of B. glabrata of uniform size (13-15 mm) were transferred to containers with 250 ml of the test solutions at the established concentrations. The bioassays were performed in triplicate; 24 h after the snails were washed and kept in jars with dechlorinated water and lettuce for feed. The snails examined for lethal effects at 24, 48, 72, and 96 h after exposure, using the absence of motion, muscle contraction, and the change in the shell coloration criteria.

Statistical analysis

From the mortality data obtained in the bioassays, were conducted analyses to estimate the lethal concentrations (LC₅₀ and LC₉₀) at a confidence interval of 95%, using the probit analysis method in the Minitab^(r) version 15 statistical software package. Analysis of variance (ANOVA) and Tukey's HSD test were used to determine statistically significant differences between means (p < 0.05).

Results and discussions

The qualitative phytochemical screening revealed the presence of flavonols and tannins to the main phenolic compounds in the HEE. When the HEE was partitioned in a gradient of increasing polarity, flavanones, flavanonols, flavonols, tannins, and xanthones were found in the HMF, while the EAF contained aurones, catechins, chalcones, flavanones, saponins, and tannins. The ChlF and HxF showed only triterpenes and steroids, respectively. These findings are in accordance with other studies on the chemical composition of S. brasiliensis. In a study by Almeida et al. (2005), the phytochemical analysis of the HEE S. brasiliensis from stem bark indicated the presence of phenolic compounds such as quinones, tannins, and triterpenes, and Saraiva et al. (2011) reported the presence of flavonoids and tannins in the hydromethanol extract of the same species leaf. Martín et al. (2010)Martín, J.S., Velasco, M.G., Heredia, J.B., 2010. Surface water treatment with tannin-based coagulants from Quebracho (Schinopsis balansae). Chem. Eng. J. 165, 851-858. isolated condensed tannins from the stem bark of a plant of the same genus, S. balansae.

According to Bussmann et al. (2011)Bussmann, R.W., Malca, G., Glenn, A., Sharon, D., Nilsen, B., Parris, B., Dubose, D., Ruiz, D., Saleda, J., Martinez, M., Carillo, L., Walker, K., Kuhlman, A., Townesmith, A., 2011. Toxicity of medicinal plants used in traditional medicine in Northern Peru. J. Ethnopharmacol. 137, 121-140., toxicity levels can be defined the high toxicity (LC₅₀ < 249 µg/ml), moderate toxicity (250 < LC₅₀ < 499 µg/ml), low toxicity (500 < LC₅₀ < 1000 µg/ml), and free of toxicity (1000 µg/ml). Based on this, the results from this study showed that the HEE and HMF were free of toxicity, while ChlF was moderately toxic, and EAF and HxF both had low toxicity (Fig. 1). In a previous study, the HEE from S. brasiliensis displayed moderate toxicity towards A. salina(LC₅₀ 428 µg/ml). However, neither the part of the plant nor the ethanol concentration used for prepararing the extract was provided (Silva et al., 2012Silva, H.H.G., Silva, I.G., Santos, R.M.G., Filho-Rodrigues, E., Elias, C.N., 2004. Atividade de taninos isolados de Maginia pubescens St. Hil. (Sapindaceae) sobre Aedes aegypti (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 37, 396-399.). In this study, the activities of the organic fractions obtained from S. brasiliensis HEE was incredibly examined

Figure 1
LC50 values for the toxicities of S. brasiliensis hydroethanol extract (HEE) and its hexane (HxF), chloroform (ChlF), ethyl acetate (EAF) and hydromethanol (HMF) fractions against A. salina. Bars bearing the same lower case letters are not significantly different (ANOVA followed by the Tukey's HSD test at p < 0.05).

According to Stefanello et al. (2006)Stefanello, M.E.A., Salvador, M.J., Ito, I.Y., Macari, P.A.T., 2006. Avaliação da atividade antimicrobiana e citotóxica de extratos de Gochnatia polymorpha ssp fl occosa. Rev. Bras. Farmacogn. 16, 525-530., natural products from that not exhibit toxicity towards A. salina can be tolerated across biological systems. In addition, it has been shown that also toxicity against A. salina correlates with insecticide activity for substances with an LC₅₀ < 1000 µg/ml (Mclaughlin et al., 1995), which corroborates the results in this study in which the fractions with higher larvicidal activity had greater toxicity. Conversely, for plant extracts to be used in natural environments, the low toxicity is considered an interesting feature. Thus, the A. salinaassay could assist in selecting and monitoring studies of phytochemicals in plant extracts in the search for bioactive substances (Nunes et al., 2008Nunes, X.P., Mesquita, R.F., Silva, D.A., Lira, D.P., Costa, V.C.O., Silva, M.V.B., Xavier, A.L., Diniz, M.F.F.M., Agra, M.F., 2008. Constituintes químicos, avaliação das atividades citotóxica e antioxidante de Mimosa paraibana Barneby (Mimosaceae). Rev. Bras. Farmacogn. 18, 718-723.).

When examining the larvicidal activity, only ChlF, HxF, and EAF showed toxicity towards A. aegypti, with the LC₅₀ value for ChlF being only 60-65% that of the other two fractions (Table 1). HEE and HMF were considered to have no toxicity because they were less than 90% lethal when tested at a concentration of 1000 µg/ml. Cheng et al. (2003)Cheng, S.S., Chang, H.T., Chang, S.T., Tsai, K.H., Chen, W.J., 2003. Bioactivity of selected plant essential oils against the yellow fever mosquito Aedes aegypti larvae. Bioresource Technol. 89, 99-102. suggested that substances with LC₅₀ values less than 100 µg/ml could be considered good larvicidal agents. Even though the fractions did not have LC50 values this low, they showed evident toxicity towards A. aegypti, which suggests the presence of chemical constituents with potential larvicidal activity. Further studies to investigate such compounds are needed.

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Table 1
Larvicidal activity of Schinopsis brasiliensis fractions towards A. aegypti larvae.

Souza et al. (2012) previously investigated the toxicity of an ethanol extract from S. brasiliensis seeds against two strains of A. aegypti, with similar results to those obtained in this study. This suggests that the active agents may be distributed in different structures of the plant and in varied concentrations. Among these active agents, triterpenoids, which were detected in ChlF and HxF, have previously been found to have larvicidal activity. Limonoids, which are triterpenoid compounds recognized the insecticides, are growth inhibitors that reduce the reproductive capacity and suppress the appetite of insects (Viegas Junior, 2006). Other studies have found that also tannins and saponins, which are present in EAF, have toxic effects on A. aegypti larvae (Silva et al., 2004; Santiago et al., 2005Santiago, G.M.P., Viana, F.A., Pessoa, O.D.L., Santos, R.P., Pouliquen, Y.B.M., Arriaga, A.M.C., Neto-Andrade, M., Braz-Filho, R., 2005. Avaliação da atividade de saponinas triterpênicas isoladas de Pentaclethra macroloba (Willd.) Kuntze (Fabaceae) e Cordia piauhiensis Fresen (Boraginaceae) sobre Aedes aegypti. Rev. Bras. Farmacogn. 15, 187-190.) by adhering to proteins in the midgut epithelial membranes of their cells, causing starvation and death.

In the biological assay to verify the molluscicidal activity, HEE, HMF, and HxF were active only at 100 µg/ml, with less than 90% of the mortality rate, while ChlF and EAF and resulted in 90% mortality at all of the tested concentrations. Although the LC₉₀ values for the activities of the ChlF and EAF against B. glabrata (Table 2) are not at the same level as Niclosamide^(r), the results were under 100 µg/ml, which is the maximum LC₉₀ value for a substance, extract, or fraction to be considered the potential molluscicidal agent (Adenusi and Odaibo, 2008Adenusi, A.A., Odaibo, A.B., 2008. Laboratory assessment of molluscicidal activity of crude aqueous and ethanolic extracts of Dalbergia sissoo plant parts against Biomphalaria pfeifferi. Travel Med. Infect. Dis. 6, 219-27. ). In addition, the results for activity against B. glabrata and A. aegypti suggest that ChlF and EAF and have a higher potential as a molluscicide than as larvicide, because the LC₉₀values were significantly lower against the mollusk.

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Table 2
Molluscicidal activity of Schinopsis brasiliensis fractions towards B. glabrata snails.

According to McCullough et al. (1980)McCullough, F.S., Gayral, P.H., Duncan, J., Christie, J.D., 1980. Molluscicides in schistosomiasis control. Bull. World Health Organ. 5, 681-689. and Pieri and Jurberg (1981), molluscicidal agents act by disrupting the osmotic balance of the mollusk, which may cause two responses: one, the release of hemolymph and retraction of the mass cephalopodal into the shell, and two, the abnormal cephalopodal projection of the mass out of the shell. In this study, the first response mechanism was observed during the incubation period. This is the first known study to examine the activity of Schinopsis genera against B. glabrata.

Conclusion

The results of this study demonstrated that the ethyl acetate, hexane, and chloroform fractions obtained from the stem bark of S. brasiliensis have potential larvicide, while the chloroform and ethyl acetate fractions are toxic to B. glabrata snails. Both results can be related to the toxicity of these fractions as demonstrated for A. salina. Further investigations of EAF, ChlF, and HxF should be undertaken to isolate the active substances, which may be essential for obtaining more selective and biodegradable compounds to biologically control the vectors for dengue and schistosomiasis.

Acknowledgements

The authors want to thank the CNPq and the CAPES for funding the present study through grants for CCSS, SSA, ALLMS, ECVA, ASD, NPD and DMS.

References

Adenusi, A.A., Odaibo, A.B., 2008. Laboratory assessment of molluscicidal activity of crude aqueous and ethanolic extracts of Dalbergia sissoo plant parts against Biomphalaria pfeifferi. Travel Med. Infect. Dis. 6, 219-27.
Alcanfor, J.D.X., Ferri, P.H., Santos, S.C., Bezerra, J.C.B., 2001. Plantas moluscicidas no controle dos caramujos transmissores da esquistossomíase, com ênfase na ação de taninos. Rev. Patol. Trop. 30, 167-175.
Almeida, C.F.C.B.R., Ramos, M.A., Amorim, E.L.C., Albuquerque, U.P., 2010. A comparison of knowledge about medicinal plants for three rural communities in the semi-arid region of northeast of Brazil. J. Ethnopharmacol. 127, 674-684.
Almeida, C.F.C.B.R., Silva, T.C.L., Amorim, E.L.C., Maia, M.B.S., Albuquerque, U.P., 2005. Life strategy and chemical composition as predictors of the selection of medicinal plants from the Caatinga (Northeast Brazil). J. Arid Environ. 62, 127-142.
Barreto, C.F., 2005. Aedes aegypti - Resistência aos inseticidas químicos e as novas alternativas de controle. Rev. Elet. FMB 1, 62-73.
Bussmann, R.W., Malca, G., Glenn, A., Sharon, D., Nilsen, B., Parris, B., Dubose, D., Ruiz, D., Saleda, J., Martinez, M., Carillo, L., Walker, K., Kuhlman, A., Townesmith, A., 2011. Toxicity of medicinal plants used in traditional medicine in Northern Peru. J. Ethnopharmacol. 137, 121-140.
Cantanhede, S.P.D., Marques, A.M., Souza, N.S., Valverde, A.L., 2010. Atividade moluscicida de plantas: uma alternativa profilática. Rev. Bras. Farmacogn. 20, 282-288.
Cheng, S.S., Chang, H.T., Chang, S.T., Tsai, K.H., Chen, W.J., 2003. Bioactivity of selected plant essential oils against the yellow fever mosquito Aedes aegypti larvae. Bioresource Technol. 89, 99-102.
Ferreira Júnior, W.S., Ladio, A.H., Albuquerque, U.P., 2011. Resilience and adaptation in the use of medicinal plants with suspected anti-inflammatory activity in the Brazilian Northeast. J. Ethnopharmacol. 101, 1-15.
Hymete, A., Iversen, T.H., Rohloff, J., Erko, B., 2005. Screening of Echinops ellenbeckii and Echinops longisetus for biological activities and chemical constituents. Phytomedicine 12, 675-679.
Lingon, B.L., 2005. Dengue fever and dengue hemorrhagic fever: a review of the history, transmission, tratment and prevention. Semin. Pediatr. Infect. 16, 60-65.
Luna, J.S., Santos, A.F., Lima, M.R.F., Omena, M.C., Mendonça, F.A.C., Bieber, L.W., Sant'Ana, A.E.G., 2005. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J. Ethnopharmacol. 97, 199-206.
Martín, J.S., Velasco, M.G., Heredia, J.B., 2010. Surface water treatment with tannin-based coagulants from Quebracho (Schinopsis balansae). Chem. Eng. J. 165, 851-858.
Matos, F.J.A., 2009. Introdução à Fitoquímica Experimental. Fortaleza: Editora UFC.
McCullough, F.S., Gayral, P.H., Duncan, J., Christie, J.D., 1980. Molluscicides in schistosomiasis control. Bull. World Health Organ. 5, 681-689.
McLaughlin, J.L., Saizarbitori, T.C., Anderson, J.E., 1995. Tres bioensayos simples para quimicos de productos naturales. Rev. Soc. Venez. Quim. 18, 13-18.
Mendonça, F.A., Souza, A.V., Dutra, D.A., 2009. Saúde pública, urbanização e dengue no Brasil. Soc. Natur. Resour. 21, 257-269.
Meyer, B.N., Ferrigni, N.R., Putnam, J.E., Jacobsen, L.B., Nichols, D.E., Mclaughlin, J.L., 1982. Brine shrimp, a convenient general bioassy for active-plant constituents. Planta Med. 45, 31-34.
Nunes, X.P., Mesquita, R.F., Silva, D.A., Lira, D.P., Costa, V.C.O., Silva, M.V.B., Xavier, A.L., Diniz, M.F.F.M., Agra, M.F., 2008. Constituintes químicos, avaliação das atividades citotóxica e antioxidante de Mimosa paraibana Barneby (Mimosaceae). Rev. Bras. Farmacogn. 18, 718-723.
Oliveira, A.M., Humberto, M.M.S., Silva, J.M., Rocha, R.F.A., Sant'Ana, A.E.G., 2006. Estudo fitoquímico e avaliação das atividades moluscicida e larvicida dos extratos da casca do caule e folha de Eugenia malaccensis L. (Myrtaceae) . Rev. Bras. Farmacogn. 16, 618-624.
Oliveira, E.C., Paumgartten, F.J.R., 2000. Toxicity of Euphorbia milii latex andniclosamide to snails and nontarget aquatic species. Ecotoxicol. Environ. Saf. 46, 342-350.
Pierre, O.S., Juberg, P., 1981. Aspectos etológicos na sobrevivência dos caramujos vetores da xistossomose ao tratamento com moluscicidas. Mem. I. Oswaldo Cruz 76, 47-55.
Porto, K.R.A., Roel, A.R., Silva, M.M., Coelho, R.M., Schelede, R.E.J.D., Jeller, A.H., 2008. Atividade larvicida do óleo de Anacardium humile Saint Hill sobre Aedes aegypti (Linnaeus, 1762) (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 41, 586-589.
Prophiro, J.S., Rossi, L.C.N., Kanis, L.A., Santos, T.G., Silva, O.S., 2008. Estudo comparativo do efeito larvicida de extratos de frutos verdes e maduros de Melia azedarach L. (Sapindales: Meliaceae) em Aedes aegypti L. (Diptera: Culicidae) . BioAssay 3, 1-5.
Rey, L., 2010. Bases da Parasitologia Médica. Rio de Janeiro: Editora Guanabara Koogan.
Ribeiro, K.A.L., Carvalho, C.M., Molina, M.T., Lima, E.P., Montero, E.L., Reys, J.R.M., Oliveira, M.B.F., Pinto, A.V., Santana, A.E.G., Goulart, M.O.F., 2009. Activities of naphthoquinones against Aedes aegypti (Linnaeus, 1762) (Diptera:Culicidae), vector of dengue and Biomphalaria glabrata (Say, 1818), intermediate host of Schistosoma mansoni. Acta Trop. 111, 44-50.
Santiago, G.M.P., Viana, F.A., Pessoa, O.D.L., Santos, R.P., Pouliquen, Y.B.M., Arriaga, A.M.C., Neto-Andrade, M., Braz-Filho, R., 2005. Avaliação da atividade de saponinas triterpênicas isoladas de Pentaclethra macroloba (Willd.) Kuntze (Fabaceae) e Cordia piauhiensis Fresen (Boraginaceae) sobre Aedes aegypti. Rev. Bras. Farmacogn. 15, 187-190.
Santos, A.F., Sant'Ana, A.E.G., 2001. Molluscicidal properties of some species of Annona. Phytomedicine 8, 115-120.
Santos, E.A., Carvalho, C.M., Costa, A.L.S., Conceição, A.S., Moura, F.B.P., Sant'ana, A.E.G., 2012. Bioactivity evaluation of plant extracts used in indigenous medicine against the snail, Biomphalaria glabrata, and the Larvae of Aedes aegypti. Evid. Based Complement. Alternat. Med. DOI: 10.1155/2012/846583.
» https://doi.org/10.1155/2012/846583
Santos, N.C., Dias, C.N., Coutinho-Moraes, D.F., Vilanova, C.M., Gonçalves, J.R.S., Souza, N.S., Rosa, I.G., 2010. Toxicidade e avaliação de atividade moluscicida de folhas de Turnera ulmifolia L. Rev. Bras. Bioci. 8, 324-329.
Saraiva, A.M., Castro, R.H.A., Risonildo, P., Cordeiro, R.P., Peixoto, S.T.J.S., Castro, V.T.N.A., Amorim, E.L.C., Xavier, H.S., Pisciottano, M.N.C., 2011. In vitro evaluation of antioxidant, antimicrobial and toxicity properties of extracts of Schinopsis brasiliensis Engl. (Anacardiaceae). African J. Pharm. Pharacol. 5, 1724-1731.
Silva, H.H.G., Silva, I.G., Santos, R.M.G., Filho-Rodrigues, E., Elias, C.N., 2004. Atividade de taninos isolados de Maginia pubescens St. Hil. (Sapindaceae) sobre Aedes aegypti (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 37, 396-399.
Silva, M.S., Brandão, D.O., Chaves, T.P., Formiga Filho, A.L., Costa, E.M., Santos, V.L., Medeiros, A.C., 2012. Study bioprospecting of medicinal plant extracts of the semiarid northeast: contribution to the control of oral microorganisms. Evid. Based Complement. Alternat. Med. DOI: 10.1155/2012/681207.
» https://doi.org/10.1155/2012/681207
Souza, T.M., Farias, D.F., Soares, B.M., Viana, M.P., Lima, G.P.G., Machado, L.K.A., Morais, S.M., Carvalho, A.F.U., 2011. Toxicity of Brazilian plant seed extracts to two strains of Aedes aegypti (Diptera: Culicidae) and Nontarget Animals. J. Med. Chem. Entomol. 48, 846-851.
Stefanello, M.E.A., Salvador, M.J., Ito, I.Y., Macari, P.A.T., 2006. Avaliação da atividade antimicrobiana e citotóxica de extratos de Gochnatia polymorpha ssp fl occosa. Rev. Bras. Farmacogn. 16, 525-530.
Treyvaud, V., Marston, A., Dyatmiko, W., Hostettmann, K., 2000. Molluscicidal saponins from Phytolacca icosandra. Phytochemistry 55, 603-609.
Viegas-Júnior, C., 2003. Terpenos com atividade inseticida: uma alternativa para o controle químico de insetos. Quim Nova 26, 390-400.
WHO, 2005. Guidelines for laboratory and field testing of mosquito larvicides. http://whqlibdoc.who.int/hq/2005/WHO_CDS_WHOPES_GCDPP_2005.13.pdf, accessed May 2012.
» http://whqlibdoc.who.int/hq/2005/WHO_CDS_WHOPES_GCDPP_2005.13.pdf
WHO, 2013. The special programme for research and training in tropical diseases (TDR). Schistosomiasis-Fact sheet N° 115. http://www.who.int/mediacentre/factsheets/fs115/en/, accessed December 2013
» http://www.who.int/mediacentre/factsheets/fs115/en/

Publication Dates

Publication in this collection
May-Jun 2014

History

Received
07 Oct 2013
Accepted
05 Mar 2014

[1] Adenusi, A.A., Odaibo, A.B., 2008. Laboratory assessment of molluscicidal activity of crude aqueous and ethanolic extracts of Dalbergia sissoo plant parts against Biomphalaria pfeifferi. Travel Med. Infect. Dis. 6, 219-27.

[2] Alcanfor, J.D.X., Ferri, P.H., Santos, S.C., Bezerra, J.C.B., 2001. Plantas moluscicidas no controle dos caramujos transmissores da esquistossomíase, com ênfase na ação de taninos. Rev. Patol. Trop. 30, 167-175.

[3] Almeida, C.F.C.B.R., Ramos, M.A., Amorim, E.L.C., Albuquerque, U.P., 2010. A comparison of knowledge about medicinal plants for three rural communities in the semi-arid region of northeast of Brazil. J. Ethnopharmacol. 127, 674-684.

[4] Almeida, C.F.C.B.R., Silva, T.C.L., Amorim, E.L.C., Maia, M.B.S., Albuquerque, U.P., 2005. Life strategy and chemical composition as predictors of the selection of medicinal plants from the Caatinga (Northeast Brazil). J. Arid Environ. 62, 127-142.

[5] Barreto, C.F., 2005. Aedes aegypti - Resistência aos inseticidas químicos e as novas alternativas de controle. Rev. Elet. FMB 1, 62-73.

[6] Bussmann, R.W., Malca, G., Glenn, A., Sharon, D., Nilsen, B., Parris, B., Dubose, D., Ruiz, D., Saleda, J., Martinez, M., Carillo, L., Walker, K., Kuhlman, A., Townesmith, A., 2011. Toxicity of medicinal plants used in traditional medicine in Northern Peru. J. Ethnopharmacol. 137, 121-140.

[7] Cantanhede, S.P.D., Marques, A.M., Souza, N.S., Valverde, A.L., 2010. Atividade moluscicida de plantas: uma alternativa profilática. Rev. Bras. Farmacogn. 20, 282-288.

[8] Cheng, S.S., Chang, H.T., Chang, S.T., Tsai, K.H., Chen, W.J., 2003. Bioactivity of selected plant essential oils against the yellow fever mosquito Aedes aegypti larvae. Bioresource Technol. 89, 99-102.

[9] Ferreira Júnior, W.S., Ladio, A.H., Albuquerque, U.P., 2011. Resilience and adaptation in the use of medicinal plants with suspected anti-inflammatory activity in the Brazilian Northeast. J. Ethnopharmacol. 101, 1-15.

[10] Hymete, A., Iversen, T.H., Rohloff, J., Erko, B., 2005. Screening of Echinops ellenbeckii and Echinops longisetus for biological activities and chemical constituents. Phytomedicine 12, 675-679.

[11] Lingon, B.L., 2005. Dengue fever and dengue hemorrhagic fever: a review of the history, transmission, tratment and prevention. Semin. Pediatr. Infect. 16, 60-65.

[12] Luna, J.S., Santos, A.F., Lima, M.R.F., Omena, M.C., Mendonça, F.A.C., Bieber, L.W., Sant'Ana, A.E.G., 2005. A study of the larvicidal and molluscicidal activities of some medicinal plants from northeast Brazil. J. Ethnopharmacol. 97, 199-206.

[13] Martín, J.S., Velasco, M.G., Heredia, J.B., 2010. Surface water treatment with tannin-based coagulants from Quebracho (Schinopsis balansae). Chem. Eng. J. 165, 851-858.

[14] Matos, F.J.A., 2009. Introdução à Fitoquímica Experimental. Fortaleza: Editora UFC.

[15] McCullough, F.S., Gayral, P.H., Duncan, J., Christie, J.D., 1980. Molluscicides in schistosomiasis control. Bull. World Health Organ. 5, 681-689.

[16] McLaughlin, J.L., Saizarbitori, T.C., Anderson, J.E., 1995. Tres bioensayos simples para quimicos de productos naturales. Rev. Soc. Venez. Quim. 18, 13-18.

[17] Mendonça, F.A., Souza, A.V., Dutra, D.A., 2009. Saúde pública, urbanização e dengue no Brasil. Soc. Natur. Resour. 21, 257-269.

[18] Meyer, B.N., Ferrigni, N.R., Putnam, J.E., Jacobsen, L.B., Nichols, D.E., Mclaughlin, J.L., 1982. Brine shrimp, a convenient general bioassy for active-plant constituents. Planta Med. 45, 31-34.

[19] Nunes, X.P., Mesquita, R.F., Silva, D.A., Lira, D.P., Costa, V.C.O., Silva, M.V.B., Xavier, A.L., Diniz, M.F.F.M., Agra, M.F., 2008. Constituintes químicos, avaliação das atividades citotóxica e antioxidante de Mimosa paraibana Barneby (Mimosaceae). Rev. Bras. Farmacogn. 18, 718-723.

[20] Oliveira, A.M., Humberto, M.M.S., Silva, J.M., Rocha, R.F.A., Sant'Ana, A.E.G., 2006. Estudo fitoquímico e avaliação das atividades moluscicida e larvicida dos extratos da casca do caule e folha de Eugenia malaccensis L. (Myrtaceae) . Rev. Bras. Farmacogn. 16, 618-624.

[21] Oliveira, E.C., Paumgartten, F.J.R., 2000. Toxicity of Euphorbia milii latex andniclosamide to snails and nontarget aquatic species. Ecotoxicol. Environ. Saf. 46, 342-350.

[22] Pierre, O.S., Juberg, P., 1981. Aspectos etológicos na sobrevivência dos caramujos vetores da xistossomose ao tratamento com moluscicidas. Mem. I. Oswaldo Cruz 76, 47-55.

[23] Porto, K.R.A., Roel, A.R., Silva, M.M., Coelho, R.M., Schelede, R.E.J.D., Jeller, A.H., 2008. Atividade larvicida do óleo de Anacardium humile Saint Hill sobre Aedes aegypti (Linnaeus, 1762) (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 41, 586-589.

[24] Prophiro, J.S., Rossi, L.C.N., Kanis, L.A., Santos, T.G., Silva, O.S., 2008. Estudo comparativo do efeito larvicida de extratos de frutos verdes e maduros de Melia azedarach L. (Sapindales: Meliaceae) em Aedes aegypti L. (Diptera: Culicidae) . BioAssay 3, 1-5.

[25] Rey, L., 2010. Bases da Parasitologia Médica. Rio de Janeiro: Editora Guanabara Koogan.

[26] Ribeiro, K.A.L., Carvalho, C.M., Molina, M.T., Lima, E.P., Montero, E.L., Reys, J.R.M., Oliveira, M.B.F., Pinto, A.V., Santana, A.E.G., Goulart, M.O.F., 2009. Activities of naphthoquinones against Aedes aegypti (Linnaeus, 1762) (Diptera:Culicidae), vector of dengue and Biomphalaria glabrata (Say, 1818), intermediate host of Schistosoma mansoni. Acta Trop. 111, 44-50.

[27] Santiago, G.M.P., Viana, F.A., Pessoa, O.D.L., Santos, R.P., Pouliquen, Y.B.M., Arriaga, A.M.C., Neto-Andrade, M., Braz-Filho, R., 2005. Avaliação da atividade de saponinas triterpênicas isoladas de Pentaclethra macroloba (Willd.) Kuntze (Fabaceae) e Cordia piauhiensis Fresen (Boraginaceae) sobre Aedes aegypti. Rev. Bras. Farmacogn. 15, 187-190.

[28] Santos, A.F., Sant'Ana, A.E.G., 2001. Molluscicidal properties of some species of Annona. Phytomedicine 8, 115-120.

[29] Santos, E.A., Carvalho, C.M., Costa, A.L.S., Conceição, A.S., Moura, F.B.P., Sant'ana, A.E.G., 2012. Bioactivity evaluation of plant extracts used in indigenous medicine against the snail, Biomphalaria glabrata, and the Larvae of Aedes aegypti. Evid. Based Complement. Alternat. Med. DOI: 10.1155/2012/846583.
» https://doi.org/10.1155/2012/846583

[30] Santos, N.C., Dias, C.N., Coutinho-Moraes, D.F., Vilanova, C.M., Gonçalves, J.R.S., Souza, N.S., Rosa, I.G., 2010. Toxicidade e avaliação de atividade moluscicida de folhas de Turnera ulmifolia L. Rev. Bras. Bioci. 8, 324-329.

[31] Saraiva, A.M., Castro, R.H.A., Risonildo, P., Cordeiro, R.P., Peixoto, S.T.J.S., Castro, V.T.N.A., Amorim, E.L.C., Xavier, H.S., Pisciottano, M.N.C., 2011. In vitro evaluation of antioxidant, antimicrobial and toxicity properties of extracts of Schinopsis brasiliensis Engl. (Anacardiaceae). African J. Pharm. Pharacol. 5, 1724-1731.

[32] Silva, H.H.G., Silva, I.G., Santos, R.M.G., Filho-Rodrigues, E., Elias, C.N., 2004. Atividade de taninos isolados de Maginia pubescens St. Hil. (Sapindaceae) sobre Aedes aegypti (Diptera, Culicidae). Rev. Soc. Bras. Med. Trop. 37, 396-399.

[33] Silva, M.S., Brandão, D.O., Chaves, T.P., Formiga Filho, A.L., Costa, E.M., Santos, V.L., Medeiros, A.C., 2012. Study bioprospecting of medicinal plant extracts of the semiarid northeast: contribution to the control of oral microorganisms. Evid. Based Complement. Alternat. Med. DOI: 10.1155/2012/681207.
» https://doi.org/10.1155/2012/681207

[34] Souza, T.M., Farias, D.F., Soares, B.M., Viana, M.P., Lima, G.P.G., Machado, L.K.A., Morais, S.M., Carvalho, A.F.U., 2011. Toxicity of Brazilian plant seed extracts to two strains of Aedes aegypti (Diptera: Culicidae) and Nontarget Animals. J. Med. Chem. Entomol. 48, 846-851.

[35] Stefanello, M.E.A., Salvador, M.J., Ito, I.Y., Macari, P.A.T., 2006. Avaliação da atividade antimicrobiana e citotóxica de extratos de Gochnatia polymorpha ssp fl occosa. Rev. Bras. Farmacogn. 16, 525-530.

[36] Treyvaud, V., Marston, A., Dyatmiko, W., Hostettmann, K., 2000. Molluscicidal saponins from Phytolacca icosandra. Phytochemistry 55, 603-609.

[37] Viegas-Júnior, C., 2003. Terpenos com atividade inseticida: uma alternativa para o controle químico de insetos. Quim Nova 26, 390-400.

[38] WHO, 2005. Guidelines for laboratory and field testing of mosquito larvicides. http://whqlibdoc.who.int/hq/2005/WHO_CDS_WHOPES_GCDPP_2005.13.pdf, accessed May 2012.
» http://whqlibdoc.who.int/hq/2005/WHO_CDS_WHOPES_GCDPP_2005.13.pdf

[39] WHO, 2013. The special programme for research and training in tropical diseases (TDR). Schistosomiasis-Fact sheet N° 115. http://www.who.int/mediacentre/factsheets/fs115/en/, accessed December 2013
» http://www.who.int/mediacentre/factsheets/fs115/en/

Samples	Concentration (µg/ml)	Dead larvae after 48 h^a	LC (µg/ml)	Confidence Interval 95%
Control^b	-	0	-	-
Niclosamide^c	3	15	LC₉₀ 0.10	-
ChlF	25	6	LC₅₀ 31	29 - 33
	50	11	LC₉₀ 68	62 - 76
	100	15
EAF	25	3	LC₅₀ 39	37 - 42
	50	9	LC₉₀ 73	68 - 80
	100	15

Samples	Concentration (µg/ml)	Dead larvae after 48 h^a	LC (µg/ml)	Confidence Interval 95%
Control^b	-	0	-	-
Temephos^c	0.012	75	-	-
ChlF	100	5	LC₅₀ 345	341 - 349
	250	28	LC₉₀ 895	877 – 916
	500	45
	1000	73
HxF	100	3	LC₅₀ 527	519 - 534
	250	10	LC₉₀1.315	1.285 - 1.348
	500	25
	1000	68
EAF	100	2	LC₅₀ 583	576 - 590
	250	8	LC₉₀ 1.333	1.303 - 1367
	500	17
	1000	68

Brasil