Evaluation of larvicidal activity and brine shrimp toxicity of rhizome
extracts of <i>Zingiber zerumbet</i> (L.) Smith

Bücker, Augusto; Falcão-Bücker, Nádia Cristina; Nunez, Cecília Veronica; Pinheiro, Carlos Cleomir de Souza; Tadei, Wanderli Pedro

doi:10.1590/0037-8682-1309-2013

Abstract

Introduction

In this study, we used dichloromethane (DCM) and methanol (MeOH) extracts of the Zingiber zerumbet rhizome to evaluate brine shrimp lethality and larvicidal activity on Aedes aegypti and Anopheles nuneztovari mosquitoes.

Methods

Bioassays were performed by exposing third-instar larvae of each mosquito species to the DCM or MeOH extracts.

Results

Probit analysis with DCM and MeOH extracts demonstrated efficient larvicidal activity against A. aegypti and A. nuneztovari larvae.

Conclusions

The DCM and MeOH extracts showed higher activity against A. nuneztovari larvae than against A. aegypti larvae, suggesting that the extracts have species-specific activity.

Larvicide; Rhizomes; Zingiber zerumbet

Zingiber zerumbet (L.) Smith, popularly known as gengibre amargo (bitter ginger), is an Asiatic plant introduced into the Amazon region that has long been used in Asian popular medicine for treating a number of illnesses. The literature shows that some compounds isolated from the essential oil of Z. zerumbet, such as zerumbone, humulene, zederone, and camprene, possess anti-inflammatory, antiviral, antitumor, antioxidant, antiallergic, and antimicrobial activities¹1. Abdul AB, Abdelwahab SI, Al-Zubairi AS, Elhassan MM, Murali SM. Anticancer and antimicrobial activities of zerumbone from the rhizomes of Zingiber zerumbet. Int J Pharmacol 2008; 4:301-304.,²2. Yob NJ, Jofrry SM, Affandi MMRMM, Teh LK, Salleh MZ, Zakaria ZA. Zingiber zerumbet (L.) Smith: A Review of Its Ethnomedicinal, Chemical, and Pharmacological Uses. Evid Based Complement Alternat Med 2011; 2011:1-12.. Zederone, a sesquiterpene compound, has been suggested to contribute to the larvicidal activity of the ethanol extract³3. Kader MG, Habib MR, Nikkon F, Yeasmin T, Rashid MA, Rahman MM, et al. Zederone from the rhizomes of Zingiber zerumbet and its anti-staphylococcal activity. Bol Latinoam Caribe Plant Med Aromat 2010; 9:63-68..

Tropical diseases like dengue and malaria still represent a major public health concern, mainly in developing countries⁴4. Tadei WP, Dutary-Thatcher B, Santos JMM, Scarpassa VM, Rodrigues IB, Rafael MS. Ecologic observations on anopheline vectors of malaria in the Brazilian Amazon. Am J Trop Med Hyg 1998; 59:325-335.. Recently, to treat these diseases, botanical and microbial insecticides have been increasingly used for mosquito control because of their efficacy and documented non-toxic effects on non-target organisms⁵5. Vyas N, Dua K, Prakash S. Efficacy of Lagenidium giganteum metabolites on mosquito larvae with reference to nontarget organisms. Parasitol Res 2007; 100:385-390.. Mosquito larval control may prove to be an effective tool that can be incorporated into integrated vector management strategies for reducing malaria transmission⁶6. Becker N. Bacterial control of vector-mosquitoes and black flies. In: Charles JF, Delécluse A, LeRoux CN, editors. Entomopathogenic bacteria: from laboratory to field application. Dordrecht: Kluwer Academic Publishers; 2000. p. 383-398..

The promising larvicidal potential of Z. zerumbet essential oils has been recently reported in literature²2. Yob NJ, Jofrry SM, Affandi MMRMM, Teh LK, Salleh MZ, Zakaria ZA. Zingiber zerumbet (L.) Smith: A Review of Its Ethnomedicinal, Chemical, and Pharmacological Uses. Evid Based Complement Alternat Med 2011; 2011:1-12.. The aim of the present investigation was to evaluate the brine shrimp lethality and larvicidal potential of Z. zerumbet rhizome extracts. The larvicidal assay was performed against larvae of 2 mosquito species (Aedes aegypti and Anopheles nuneztovari). This plant was selected because it has been used for cancer treatment and it also exhibits antimicrobial activity¹1. Abdul AB, Abdelwahab SI, Al-Zubairi AS, Elhassan MM, Murali SM. Anticancer and antimicrobial activities of zerumbone from the rhizomes of Zingiber zerumbet. Int J Pharmacol 2008; 4:301-304., while only a few studies on its larvicidal activity have been reported⁷7. Tewtrakul S, Itchayapruk J, Chaitongruk P. Mosquito larvicidal activity of Zingiber zerumbet Smith rhizomes. Songklanakarin J Sci Technol 1998; 20:183-187.,⁸8. Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, et al. Chemical composition and larvicidal activity of edible plant-derived essential oils against the pyrethroid-susceptible and –resistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol 2010; 35:106-115..

Rhizomes of Z. zerumbet were collected from the Tarumã River region, Manaus, AM, Brazil (03º00′05″S and 60º05′01″W). The rhizomes were crushed, dried, macerated with dichloromethane (DCM) for 72h, and then filtered. The plant material was dried, extracted with methanol (MeOH), for 72h, and filtered. The extracts obtained were concentrated in a low-pressure rotary evaporator to remove excess solvent. The extracts were redissolved in dimethylsulfoxide (DMSO) for further tests. A voucher specimen was deposited in the herbarium of Instituto Nacional de Pesquisas da Amazônia (INPA) (Number 186913).

Both mosquito species were maintained for oviposition in the insectary at 26 ± 2ºC, with a photoperiod of 12:12 (L/D) and a relative humidity of 80-90%, according to the criteria of Scarpassa and Tadei⁹9. Scarpassa VM, Tadei WP. Biologia de anofelinos amazônicos. XIII. Estudo do ciclo biológico de A. nuneztovari. Acta Amaz 1990; 20:95-118..

Aedes aegypti Linnaeus, 1762: Eggs were obtained from the colonies of the Malaria and Dengue Laboratory (INPA) and they were kept in insectaria cages.

Anopheles nuneztovari Gabaldón, 1940: Species collections of the genus Anopheles were carried out at Natan Farm in the east region of Manaus City, State of Amazonas, Brazil (03º04′10″S and 59º51′40″W). Catches were carried out in cattle pens, and only fed females were selected. Samples were collected using an entomological manual captor between 18 and 21h.

The larvicidal bioassay was carried out using 5 different doses of the DCM and MeOH extracts of Z. zerumbet rhizomes. Ten third-instar larvae of each mosquito species were used and 50µL of liquid food added containing DCM or MeOH extracts at concentrations of 100, 200, 300, 400, or 500µg/mL. In each case, 4 replicates of each concentration were assayed. The negative control received only DMSO at the same concentration and a 10% mortality rate and a 95% confidence interval were set as the limits. Readings were collected at 24, 48, and 72h, recording the number of live and dead larvae at each concentration. The larvae were considered dead if they were immobile and unable to reach the water surface.

The extracts were evaluated for lethality to brine shrimp larvae (Artemia salina Leach) according to the procedure described by Meyer et al.¹⁰10. Meyer BN, Ferrigni NR, Putnam JE. Brine shrimp: A convenient general bioassay for active plant constituents. Planta Med 1982; 45:31-34. with some modifications. Briefly, dried brine shrimp eggs were bred in saline medium (Instant Ocean®). After 48h, a few shrimps hatched and were ready for testing. One-day-old larvae (10 per vial) were transferred into 5-mL vials containing saline solution along with 25, 50, 100, 250, 500, or 1,000µg/mL of each DCM and MeOH extract dissolved in DMSO and diluted serially in saline water. In each case, 4 replicates of each concentration were assayed. After 24h, the survivors were counted and the percentage mortality at each dose was recorded. A saline solution containing DMSO (1%) was used as the negative control (LC₅₀ > 1,000µg/mL), while colchicine (LC₅₀ = 25µg/mL) was used as the positive control¹¹11. Déciga-Campos M, Rivero-Cruz I, Arriaga-Alba M, Castañeda-Corral G, Angeles-López GE, Navarrete A, et al. Acute toxicity and mutagenic activity of Mexican plants used in traditional medicine. J Ethnopharmacol 2007; 110:334-342..

For statistical analysis, the lethal concentration (LC₅₀ and LC₉₀) was calculated using Probit analysis. The percentage mortality was calculated and mortality corrections when necessary were carried out using Abbot's formula.

The brine shrimp lethality assay is considered a useful tool for preliminary toxicity assessment, to screen medicinal plants popularly used for several purposes, and for monitoring the isolation of a great variety of biologically active compounds¹²12. Bastos MLA, Lima MRF, Conserva LM, Andrade VS, Rocha EMM, Lemos RPL. Studies on the antimicrobial activity and brine shrimp toxicity of Zeyheria tuberculosa (Vell.) Bur. (Bignoniaceae) extracts and their main constituents. Ann Clin Microbiol Antimicrob 2009; 8:16.. The method is rapid, simple, reproducible, and economical. This in vivo test has been successfully employed for bioassay-guide fractionation of active cytotoxic and antitumor agents¹1. Abdul AB, Abdelwahab SI, Al-Zubairi AS, Elhassan MM, Murali SM. Anticancer and antimicrobial activities of zerumbone from the rhizomes of Zingiber zerumbet. Int J Pharmacol 2008; 4:301-304.. Furthermore, positive correlations have been demonstrated between the antimicrobial¹²12. Bastos MLA, Lima MRF, Conserva LM, Andrade VS, Rocha EMM, Lemos RPL. Studies on the antimicrobial activity and brine shrimp toxicity of Zeyheria tuberculosa (Vell.) Bur. (Bignoniaceae) extracts and their main constituents. Ann Clin Microbiol Antimicrob 2009; 8:16. and larvicidal¹³13. Leite JJG, Brito éHS, Cordeiro RA, Brilhante RSN, Sidrim JJC, Bertini LM, et al. Chemical composition, toxicity and larvicidal and antifungal activities of Persea americana (avocado) seed extracts. Rev Soc Bras Med Trop 2009; 42:110-113. activities, and lethality to brine shrimp and the corresponding lethal dose of medicinal plants.

The results of Artemia salina testing are summarized in Table 1 (mortality % and LC₅₀–LC₉₀). The results revealed that Z. zerumbet extracts showed significant toxicity against Artemia salina for up to 48h, with an LC₅₀ of 30.9µg/mL for the DCM extract, and an LC₅₀ of 64.0µg/mL for the MeOH extract. These results are consistent with the results of Déciga-Campos et al¹¹11. Déciga-Campos M, Rivero-Cruz I, Arriaga-Alba M, Castañeda-Corral G, Angeles-López GE, Navarrete A, et al. Acute toxicity and mutagenic activity of Mexican plants used in traditional medicine. J Ethnopharmacol 2007; 110:334-342., who reported LC₅₀ values ranging from 37 to 227µg/mL, and of Bastos et al¹²12. Bastos MLA, Lima MRF, Conserva LM, Andrade VS, Rocha EMM, Lemos RPL. Studies on the antimicrobial activity and brine shrimp toxicity of Zeyheria tuberculosa (Vell.) Bur. (Bignoniaceae) extracts and their main constituents. Ann Clin Microbiol Antimicrob 2009; 8:16., who reported an LC₅₀ of 29.55µg/mL for hexane acid and an LC₅₀ of 398.05µg/mL for a 1:1 mixture of hexane-CHCl₃ (Table 1).

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TABLE 1
- Percentage mortality of brine shrimp (Artemia salina), and Aedes aegypti and Anopheles nuneztovari larvae, at different time intervals and with different Zingiber zerumbet dichloromethane and methanol extract concentrations.

Larvicide activity involves applying chemicals to habitats to kill pre-adult mosquitoes. This experiment validates and reveals the efficacy of the DCM and MeOH extracts of Z. zerumbet against A. aegypti and A. nuneztovari larvae. Furthermore, a positive correlation was observed between the concentration of the extract and the mortality percentage (Tables 1 and 2), with the mortality rate being directly proportional to concentration. Bioassays showed that the DCM extract was more toxic than the MeOH extract to the larvae of both mosquito species, and that A. nuneztovari (CL₅₀ < 70µg/mL) was more susceptible to the DCM extract than A. aegypti (CL₅₀ < 300µg/mL) in both treatments (Table 2). Zerumbone is the main common component (31.7%) in the rhizome oil of the Asian species of Z. zerumbet⁸8. Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, et al. Chemical composition and larvicidal activity of edible plant-derived essential oils against the pyrethroid-susceptible and –resistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol 2010; 35:106-115., and 97% pure zerumbone was obtained from the essential oil of the rhizomes of the Brazilian species¹⁴14. Pinheiro CCS (inventor), Instituto Nacional de Pesquisas da Amazônia (assignee). Processo de obtenção de zerumbona isolada dos óleos essenciais das raízes de Zingiber zerumbet L. Smith (Zingiberaceae). Brazilian patent BR PI0505343-9 A2; 2005.. Based on these results, the authors suggest that the high activity present in the DCM extract might be associated with a considerable amount of the active principal of Z. zerumbet, which would cause the greater susceptibility of the tested organisms (brine shrimp and mosquito larvae) (Table 2). Rahuman et al.¹⁵15. Rahuman AA, Gopalakrishnan G, Venkatesan P, Geetha K. Isolation and identification of mosquito larvicidal compound from Abutilon indicum (Linn) Sweet. Parasitol Res 2008; 102:981-988. evaluated the larvicidal activity of the petroleum ether extract of Z. officinalis, and their results show that the most effective compound against A. aegypti (4.25ppm) and Culex quinquefasciatus (5.52ppm) was 4-gingerol. Sutthanont et al.⁸8. Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, et al. Chemical composition and larvicidal activity of edible plant-derived essential oils against the pyrethroid-susceptible and –resistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol 2010; 35:106-115. have reported that the essential oils of Z. zerumbet and Kaempferia galanga, two Zingiberaceae, were found to be larvicidal against pyrethroid-susceptible A. aegypti, with LC₅₀ values of 48.88 and 53.64ppm, respectively. Tewtrakul et al.⁷7. Tewtrakul S, Itchayapruk J, Chaitongruk P. Mosquito larvicidal activity of Zingiber zerumbet Smith rhizomes. Songklanakarin J Sci Technol 1998; 20:183-187. reported the effective toxicity of the ethanol extract of Z. zerumbet against Anopheline larvae, with an LD₅₀ of 18.9µg/mL. However, the biological activity of Z. zerumbet as a larvicide has not been studied so far.

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TABLE 2
- Lethal concentration of Zingiber zerumbet dichloromethane and methanol extract against brine shrimp (Artemia salina) and Aedes aegypti and Anopheles nuneztovari larvae at different time intervals.

In conclusion, the present findings support the use of Z. zerumbet as an alternative to combat mosquito vectors of diseases. The results reported here pave the way for further investigations into the larvicidal properties of natural product extracts. We are currently testing the zerumbone component from the rhizomes of Z. zerumbet¹⁴14. Pinheiro CCS (inventor), Instituto Nacional de Pesquisas da Amazônia (assignee). Processo de obtenção de zerumbona isolada dos óleos essenciais das raízes de Zingiber zerumbet L. Smith (Zingiberaceae). Brazilian patent BR PI0505343-9 A2; 2005..

REFERENCES

¹
Abdul AB, Abdelwahab SI, Al-Zubairi AS, Elhassan MM, Murali SM. Anticancer and antimicrobial activities of zerumbone from the rhizomes of Zingiber zerumbet. Int J Pharmacol 2008; 4:301-304.
²
Yob NJ, Jofrry SM, Affandi MMRMM, Teh LK, Salleh MZ, Zakaria ZA. Zingiber zerumbet (L.) Smith: A Review of Its Ethnomedicinal, Chemical, and Pharmacological Uses. Evid Based Complement Alternat Med 2011; 2011:1-12.
³
Kader MG, Habib MR, Nikkon F, Yeasmin T, Rashid MA, Rahman MM, et al. Zederone from the rhizomes of Zingiber zerumbet and its anti-staphylococcal activity. Bol Latinoam Caribe Plant Med Aromat 2010; 9:63-68.
⁴
Tadei WP, Dutary-Thatcher B, Santos JMM, Scarpassa VM, Rodrigues IB, Rafael MS. Ecologic observations on anopheline vectors of malaria in the Brazilian Amazon. Am J Trop Med Hyg 1998; 59:325-335.
⁵
Vyas N, Dua K, Prakash S. Efficacy of Lagenidium giganteum metabolites on mosquito larvae with reference to nontarget organisms. Parasitol Res 2007; 100:385-390.
⁶
Becker N. Bacterial control of vector-mosquitoes and black flies. In: Charles JF, Delécluse A, LeRoux CN, editors. Entomopathogenic bacteria: from laboratory to field application. Dordrecht: Kluwer Academic Publishers; 2000. p. 383-398.
⁷
Tewtrakul S, Itchayapruk J, Chaitongruk P. Mosquito larvicidal activity of Zingiber zerumbet Smith rhizomes. Songklanakarin J Sci Technol 1998; 20:183-187.
⁸
Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, et al. Chemical composition and larvicidal activity of edible plant-derived essential oils against the pyrethroid-susceptible and –resistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol 2010; 35:106-115.
⁹
Scarpassa VM, Tadei WP. Biologia de anofelinos amazônicos. XIII. Estudo do ciclo biológico de A. nuneztovari. Acta Amaz 1990; 20:95-118.
¹⁰
Meyer BN, Ferrigni NR, Putnam JE. Brine shrimp: A convenient general bioassay for active plant constituents. Planta Med 1982; 45:31-34.
¹¹
Déciga-Campos M, Rivero-Cruz I, Arriaga-Alba M, Castañeda-Corral G, Angeles-López GE, Navarrete A, et al. Acute toxicity and mutagenic activity of Mexican plants used in traditional medicine. J Ethnopharmacol 2007; 110:334-342.
¹²
Bastos MLA, Lima MRF, Conserva LM, Andrade VS, Rocha EMM, Lemos RPL. Studies on the antimicrobial activity and brine shrimp toxicity of Zeyheria tuberculosa (Vell.) Bur. (Bignoniaceae) extracts and their main constituents. Ann Clin Microbiol Antimicrob 2009; 8:16.
¹³
Leite JJG, Brito éHS, Cordeiro RA, Brilhante RSN, Sidrim JJC, Bertini LM, et al. Chemical composition, toxicity and larvicidal and antifungal activities of Persea americana (avocado) seed extracts. Rev Soc Bras Med Trop 2009; 42:110-113.
¹⁴
Pinheiro CCS (inventor), Instituto Nacional de Pesquisas da Amazônia (assignee). Processo de obtenção de zerumbona isolada dos óleos essenciais das raízes de Zingiber zerumbet L. Smith (Zingiberaceae). Brazilian patent BR PI0505343-9 A2; 2005.
¹⁵
Rahuman AA, Gopalakrishnan G, Venkatesan P, Geetha K. Isolation and identification of mosquito larvicidal compound from Abutilon indicum (Linn) Sweet. Parasitol Res 2008; 102:981-988.

Publication Dates

Publication in this collection
May-Jun 2013

History

Received
17 Aug 2011
Accepted
7 Dec 2011

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Abdul AB, Abdelwahab SI, Al-Zubairi AS, Elhassan MM, Murali SM. Anticancer and antimicrobial activities of zerumbone from the rhizomes of Zingiber zerumbet. Int J Pharmacol 2008; 4:301-304.

[2] ²
Yob NJ, Jofrry SM, Affandi MMRMM, Teh LK, Salleh MZ, Zakaria ZA. Zingiber zerumbet (L.) Smith: A Review of Its Ethnomedicinal, Chemical, and Pharmacological Uses. Evid Based Complement Alternat Med 2011; 2011:1-12.

[3] ³
Kader MG, Habib MR, Nikkon F, Yeasmin T, Rashid MA, Rahman MM, et al. Zederone from the rhizomes of Zingiber zerumbet and its anti-staphylococcal activity. Bol Latinoam Caribe Plant Med Aromat 2010; 9:63-68.

[4] ⁴
Tadei WP, Dutary-Thatcher B, Santos JMM, Scarpassa VM, Rodrigues IB, Rafael MS. Ecologic observations on anopheline vectors of malaria in the Brazilian Amazon. Am J Trop Med Hyg 1998; 59:325-335.

[5] ⁵
Vyas N, Dua K, Prakash S. Efficacy of Lagenidium giganteum metabolites on mosquito larvae with reference to nontarget organisms. Parasitol Res 2007; 100:385-390.

[6] ⁶
Becker N. Bacterial control of vector-mosquitoes and black flies. In: Charles JF, Delécluse A, LeRoux CN, editors. Entomopathogenic bacteria: from laboratory to field application. Dordrecht: Kluwer Academic Publishers; 2000. p. 383-398.

[7] ⁷
Tewtrakul S, Itchayapruk J, Chaitongruk P. Mosquito larvicidal activity of Zingiber zerumbet Smith rhizomes. Songklanakarin J Sci Technol 1998; 20:183-187.

[8] ⁸
Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, et al. Chemical composition and larvicidal activity of edible plant-derived essential oils against the pyrethroid-susceptible and –resistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol 2010; 35:106-115.

[9] ⁹
Scarpassa VM, Tadei WP. Biologia de anofelinos amazônicos. XIII. Estudo do ciclo biológico de A. nuneztovari. Acta Amaz 1990; 20:95-118.

[10] ¹⁰
Meyer BN, Ferrigni NR, Putnam JE. Brine shrimp: A convenient general bioassay for active plant constituents. Planta Med 1982; 45:31-34.

[11] ¹¹
Déciga-Campos M, Rivero-Cruz I, Arriaga-Alba M, Castañeda-Corral G, Angeles-López GE, Navarrete A, et al. Acute toxicity and mutagenic activity of Mexican plants used in traditional medicine. J Ethnopharmacol 2007; 110:334-342.

[12] ¹²
Bastos MLA, Lima MRF, Conserva LM, Andrade VS, Rocha EMM, Lemos RPL. Studies on the antimicrobial activity and brine shrimp toxicity of Zeyheria tuberculosa (Vell.) Bur. (Bignoniaceae) extracts and their main constituents. Ann Clin Microbiol Antimicrob 2009; 8:16.

[13] ¹³
Leite JJG, Brito éHS, Cordeiro RA, Brilhante RSN, Sidrim JJC, Bertini LM, et al. Chemical composition, toxicity and larvicidal and antifungal activities of Persea americana (avocado) seed extracts. Rev Soc Bras Med Trop 2009; 42:110-113.

[14] ¹⁴
Pinheiro CCS (inventor), Instituto Nacional de Pesquisas da Amazônia (assignee). Processo de obtenção de zerumbona isolada dos óleos essenciais das raízes de Zingiber zerumbet L. Smith (Zingiberaceae). Brazilian patent BR PI0505343-9 A2; 2005.

[15] ¹⁵
Rahuman AA, Gopalakrishnan G, Venkatesan P, Geetha K. Isolation and identification of mosquito larvicidal compound from Abutilon indicum (Linn) Sweet. Parasitol Res 2008; 102:981-988.

Specimen	Brine Shrimp (%)
Specimen	Extracts	Time (h)	1,000µg/mL	500µg/mL	250µg/mL	100µg/mL	50µg/mL	25µg/mL
Artemia salina	methanol	24	98.0	94.4	80.0	53.3	11.2	2.2
	methanol	48	100.0	100.0	98.8	70.0	43.3	20.2
	dichloromethane	24	100.0	96.6	94.4	86.7	46.7	38.9
	dichloromethane	48	100.0	98.8	95.5	88.9	65.6	54.4

	Larvicidal activity (%)
		Time (h)	1,000µg/mL	500µg/mL	400µg/mL	300µg/mL	200µg/mL	100µg/mL
Aedes aegypti	methanol	48	not calculated	95.0	78.3	50.0	18.3	2.5
	methanol	72	not calculated	99.1	94.2	67.5	37.5	5.0
	dichloromethane	48	not calculated	100.0	100.0	98.3	95.8	58.3
	dichloromethane	72	not calculated	100.0	100.0	99.2	97.5	75.0
Anopheles nuneztovari	methanol	48	not calculated	100.0	97.5	91.6	88.3	65.8
	methanol	72	not calculated	100.0	97.5	93.3	90.8	68.3
	dichloromethane	48	not calculated	100.0	95.8	94.2	92.5	68.3
	dichloromethane	72	not calculated	100.0	99.1	98.3	97.5	78.3

Specimen	Extracts	Time (h)	LC₅₀ µg/mL (CI₉₅)	LC₉₀ µg/mL (CI₉₅)	χ²2. Yob NJ, Jofrry SM, Affandi MMRMM, Teh LK, Salleh MZ, Zakaria ZA. Zingiber zerumbet (L.) Smith: A Review of Its Ethnomedicinal, Chemical, and Pharmacological Uses. Evid Based Complement Alternat Med 2011; 2011:1-12.	Regression equation
Artemia salina	methanol	24	127.4 (112.9–142.4)	351.4 (304.2–419.6)	2.45	2.90x -1.12
	methanol	48	64.0 (33.8–90.8)	195.6 (135.1–419.6)	7.89	2.64x -0.23
	dichloromethane	24	40.4 (12.2–65.8)	177.7 (117.1–382.8)	6.46	1.99x +1.80
	dichloromethane	48	30.9 (20.0–41.1)	132.8 (109.7–168.1)	0.86	2.02x +1.98
Aedes aegypti	methanol	48	293.2 (276.4–308.9)	471.6 (439.0–518.1)	2.87	6.20x -10.31
	methanol	72	232.3 (161.1–272.0)	382.6 (326.8–550.9)	7.36	5.91x -8.99
	dichloromethane	48	89.8 (77.0–100.4)	170.5 (154.3–193.7)	1.77	4.60x -3.99
	dichloromethane	72	68.2 (50.4–81.5)	141.4 (125.6–162.9)	0.58	4.05x -2.43
Anopheles nuneztovari	methanol	48	73.9 (32.9–105.3)	227.9 (177.0–325.6)	3.99	2.61x +0.11
	methanol	72	68.1 (32.4–96.3)	210.5 (166.5–283.9)	3.14	2.61x +0.21
	dichloromethane	48	62.8 (17.2–98.1)	206.4 (150.1–316.6)	5.10	2.47x +0.55
	dichloromethane	72	54.6 (34.5–70.9)	142.8 (122.1–166.7)	1.93	3.07x -0.33

Brasil