Effect of thyme, lemongrass and rosemary essential oils on <i>Aspergillus flavus</i> in cauliflower seeds

Nakada-Freitas, Pâmela G; Santos, César Augusto; Magalhães, Thalita Helena; Bustamonte, Stefani S; Santos, Danielle Carla dos; Cardoso, Antonio Ismael Inácio; Amador, Talita S; Lanna, Natália de BL; Bardiviesso, Estefânia M; Catão, Hugo Cesar RM

doi:10.1590/s0102-0536-20220109

ABSTRACT

Due to the action of essential oils of thyme, lemongrass and rosemary against microorganisms and few studies on them in seed treatment, this study is proposed with vegetable seed. Therefore, the aim was to evaluate the effect of treatments with essential oils of thyme, lemongrass and rosemary on cauliflower seeds, inoculated with Aspergillus flavus. Three essential oils were used, at concentrations 0.0; 0.4; 0.8; 1.6 and 2.0%, arranged in a 3x5 factorial scheme, in a completely randomized design, with four replications. The essential oils of thyme (1.8%) and lemongrass (1.9%) had a fungistatic effect against A. flavus in cauliflower seeds. Thyme essential oil at 2.0% and lemongrass at 1.6% didn’t affect the physiological quality of seeds, being promising in the treatment of organic seeds. On the other hand, rosemary essential oil, despite not affecting germination and little affecting seed vigor, wasn’t efficient in controlling the pathogen.

Keywords:
Brassica oleracea var. botrytis; Thymus vulgaris; Cymbopogon citratus; Rosmarinus officinalis

RESUMO

Devido à ação dos óleos essenciais de tomilho, capim-limão e alecrim contra microrganismos e poucos estudos dos mesmos no tratamento de sementes, propõe-se este estudo com semente de hortaliça. Portanto, o objetivo deste trabalho foi avaliar o efeito do tratamento com óleos essenciais de tomilho, capim-limão e alecrim em sementes de couve-flor inoculadas com Aspergillus flavus. Foram utilizados os três óleos essenciais, nas concentrações 0,0; 0,4; 0,8; 1,6 e 2,0%, arranjados em esquema fatorial 3x5, no delineamento inteiramente casualizado, com quatro repetições. Os óleos essenciais de tomilho (1,8%) e capim-limão (1,9%) tiveram efeito fungistático contra A. flavus em sementes de couve-flor. Os óleos essenciais de tomilho a 2,0% e o de capim-limão a 1,6% não afetaram a qualidade fisiológica das sementes, sendo promissores no tratamento de sementes orgânicas. Por outro lado, o óleo essencial de alecrim, apesar de não afetar a germinação e afetar pouco o vigor das sementes, não foi eficiente no controle do patógeno.

Palavras-chave:
Brassica oleracea var. botrytis; Thymus vulgaris; Cymbopogon citratus; Rosmarinus officinalis

Seeds are a relevant agricultural input, since from them begins the food production. But seeds can disseminate disease agents, such as fungus and bacteria. Thus, the use of seeds with sanitary quality is necessary to obtain a uniform stand and reach its maximum physiological potential, and less disease inoculum in the new fields. It is not always possible to obtain seed lots 100% guaranteed free of pathogens (Cardoso et al., 2016CARDOSO, AII; KRONKA, AZ; LANNA, NBL; SILVA, PNL; COLOMBARI, LF; SANTOS, PL; PIEROZZI, CG. 2016. Treatment with thiabendazole in germination, vigor, and incidence of fungi in zucchini seeds. Australian Journal of Crop Science10: 1589-1593.). To protect seeds, it is necessary to treat the same with fungicides. In the conventional production system, there are already registered products (Agrofit, 2020AGROFIT - Sistemas de Agrotóxicos Fitossanitários. 2020. Available at<Available athttp://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons >. AccessedJanuary 3, 2021.
http://agrofit.agricultura.gov.br/agrofi... ), however, for the organic production system, there is still no product registration.

The presence of fungi affects the vigor of seeds, when they benefit from the reserve tissues or even from the embryo itself, which, according to Krzyzanowski & França Neto (2001KRZYZANOWSKI, FC; FRANÇA NETO, JB. 2001. Vigor de sementes. Informativo Abrates. Embrapa, 11: 81-84.), results in the slow growth of seedlings and production of abnormal seedlings. The fungi group with the highest contamination rate in stored seeds are of the Aspergillus species (Vecchia & Castilhos-Fortes, 2007VECCHIA, AD; CASTILHOS-FORTES, R. 2007. Fungical contamination in commercial granola. Food Science and Technology27: 324-327).

The use of agrochemicals is not allowed in an organic production system, both in the production phase in the field and in seed treatment. In view of the increase of diseases in current agriculture, and the scarcity of organic products to mitigate the potential for environmental impact, it is necessary to develop alternative products for these problems. Therefore, the evaluation of the effect of essential oils has been promising due to its high antimicrobial activity (Romero et al., 2012ROMERO, AL; ROMERO, RB; SILVA, EL; DINIZ, SPSS; OLIVEIRA, RR; VIDA, JB. 2012. Chemical composition and activity of Origanum vulgare essential oil against phytopathogenic fungi. UNOPAR Científica Ciências Biológicas e da Saúde14: 231-235.).

According to Santos et al. (2010SANTOS, ACA; ROSSATO, M; SERAFINI, LA; BUENO, M; CRIPPA, LB; SARTORI, VC; DELLACASSA, E; MOYNA, P. 2010. Efeito fungicida dos óleos essenciais de Schinus molle L. e Schinus terebinthifolius Raddi, Anacardiaceae, do Rio Grande do Sul. Revista Brasileira de Farmacognosia20: 154-159.), studies have already proven the efficacy of essential oils acting as fungicides, inhibiting mycelial growth and the germination of conidia. Among them, the thyme essential oil (Thymus vulgaris) has already shown to be effective against stem and ear rot caused by Stenocarpella maydi (Teixeira et al., 2013TEIXEIRA, GA; ALVES, E; AMARAL, DC; MACHADO, JC; PERINA, FJ. 2013. Essential oils on the control of stem and ear rot in maize. Ciência Rural43: 1945-1951.), Colletotrichum gloeosporioides (Figueiredo et al., 2021FIGUEIREDO, AR; SILVA, LR; MORAIS, LAS. 2021. Sensitivity of Colletotrichum gloeosporioides in passion fruit to essential oils. Revista Desafios 8: 19-30.), and Aspergillus sp. (Kohiyama et al., 2015KOHIYAMA, CY; YAMAMOTO, M; RIBEIRO, M; APARECIDA, S; MOSSINI, G; BANDO, E; BOMFIM, NS; NERILO, SB; ROCHA, GHO; GRESPAN, R; MIKCHA, JMG; MACHINSKI, M. 2015. Antifungal properties and inhibitory effects upon aflatoxin production of Thymus vulgaris L. by Aspergillus flavus Link. Food Chemistry 173: 1006-1010.).

In addition, there is the essential oil of lemongrass (Cymbopogon citratus) which, according to Shah et al. (2011SHAH, G; SHRI, R; PANCHAL, V; SHARMA, N; SINGH, B; MANN, AS. 2011. Scientific basis for the therapeutic use of Cymbopogon citratus, Stapf (Lemon grass). Journal of Advanced Pharmaceutical Technology and Research 1: 3-8.), has antifungal action and in some studies it was shown to be efficient in the control of A. flavus, A. niger, A. ochraceus (Sonker et al., 2014SONKER, N; PANDEY, AK; SINGH, P; TRIPATHI, NN. 2014. Assessment of Cymbopogon citratus (dc.) Stapf essential oil as herbal preservatives based on antifungal, antiaflatoxin, and antiochratoxin activities and in vivo efficacy during storage. Journal of Food Science 79: 628-634.) and A. brasiliensis (Oliveira et al., 2020OLIVEIRA, FS; TEODORO, CES; BERBERT, PA; MARTINAZZO, AP. 2020. Evaluation of the antifungal potential of Cymbopogon citratus essential oil in the control of the fungus Aspergillus brasiliensis. Research, Society and Development 9: 1-17.). Oliveira & Sá (2014)OLIVEIRA, FS; TEODORO, CES; BERBERT, PA; MARTINAZZO, AP. 2020. Evaluation of the antifungal potential of Cymbopogon citratus essential oil in the control of the fungus Aspergillus brasiliensis. Research, Society and Development 9: 1-17. detected an improvement in the physiological quality of rice, beans and soybean seeds, due to improving the sanitary quality. And finally, there is the rosemary essential oil (Rosmarinus officinalis) effective against A. flavus, A. niger (Sousa et al., 2013SOUSA, LL; ANDRADE, SCA; ATHAYDE, AJAA; OLIVEIRA, CEV; SALES, CV; MADRUGA, MS; SOUZA, EL. 2013. Efficacy of Origanum vulgare L. and Rosmarinus officinalis L. essential oils in combination to control postharvest pathogenic Aspergilli and autochthonous mycoflora in Vitis labrusca L. (table grapes). International Journal of Food Microbiology165: 312 -318.) and A. flavus (Prakash et al., 2015PRAKASH, B; KEDIA, A; MISHRA, PK; DWIVEDY, AK; DUBEY, NK. 2015. Assessment of chemically characterised Rosmarinus officinalis L. essential oil and its major compounds as plant-based preservative in food system based on their efficacy against food-borne moulds and aflatoxin secretion and as antioxidante. International Journal of Food Science and Technology 50: 1792-1798.; Lee et al., 2020LEE, LT; GARCIA, SA; MARTINAZZO, AP; TEODORO, CES. 2020. Fungitoxity and chemical composition of rosemary essential oil (Rosmarinus officinalis) on Aspergillus flavus. Research, Society and Development9: e202985628.).

Most studies about the use of medicinal plants are against microorganisms in the food industry, but still scarce in the agronomic sector. Therefore, more detailed investigations should be made with emphasis on in vivo tests, in order to validate the in vitro results. Essential oils of thyme, lemongrass and rosemary act against microorganisms. Because of the lack of studies about the control of Aspergillus flavus on vegetable seeds, and their effect on seed quality, the present study is of considerable importance for the organic production system.

The aim of this study was to evaluate the effect of essential oils of thyme, lemongrass and rosemary on cauliflower seeds inoculated with Aspergillus flavus.

MATERIAL AND METHODS

The experiments were set out at the Seed Analysis Laboratory of the São Paulo State University (UNESP), College of Agricultural and Techonogical Sciences, Dracena.

Cauliflower seeds (Feltrin^®) without fungicide treatment were inoculated with the fungus Aspergillus flavus, isolated from bean seeds. The inoculum was multiplied in PDA (potato-dextrose-agar) medium together with the water restrictor mannitol at a concentration of 33 g L^-1, to obtain -0.8 MPa. This technique has been used to prevent seed germination in sanitary tests (Machado et al., 2001MACHADO, JC; OLIVEIRA, JA; VIEIRA, MGGC; ALVES, MC. 2001. Artificial inoculation of fungi in soybean seeds using manitol solution. Brazilian Journal of Seed Science23: 95-101.). Then, the seeds remained on this medium in a single layer, for a period of one hour (Martins et al., 2016MARTINS, IR; SOUZA, EP; SANTOS, TP; ANJOS, LVS; NAKADA-FREITAS, PG; CARDOSO, AII. 2016. Inoculação de Aspergillus sp. em sementes de coentro. XXVIII Congress of Scientific Initiation of Unesp, Dracena/ Brazil.) and, after this time, the seeds remained under paper towels for a period of 48 hours.

Three essential oils were used (thyme, lemongrass and rosemary, from Company Laszlo^®), at concentrations 0.0; 0.4; 0.8; 1.6 and 2.0%, arranged in a 3x5 factorial scheme, in a completely randomized design, with four replications. The composition of the main active principles of each essential oil are: rosemary: 1,8-cineole (41.2%), α-pinene (14.3%) and camphor (11.4%); thyme: thymol (46.6%), p-cymene (38.9%) and γ-terpinene (0.3%); lemongrass: geranial (44.4%) and neral (33.5%).

The water used to prepare the solutions was deionized and autoclaved. For the treatment of seeds with essential oils, an orbital shaker table (MA-model 376) was used for five minutes.

The evaluated characteristics were a) germination (11x11x3 cm plastic boxes were used with germination paper, moistened 2.5 times their weight and 50 seeds were sown in each repetition); b) percentage of normal seedlings [evaluated ten days after sowing (DAS) (Brasil, 2009aBRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009a. Regras para análise de sementes. Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/regras_analise_de_sementes.pdf.
https://www.abrates.org.br/files/regras_... )]; c) first germination count [performed in the germination test, computing the percentage of normal seedlings on the fifth DAS (Brasil, 2009aBRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009a. Regras para análise de sementes. Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/regras_analise_de_sementes.pdf.
https://www.abrates.org.br/files/regras_... )]; d) shoot, primary root and e) total seedling length (ten normal seedlings from the germination test were sampled and the average of each plot was obtained) f) seedling dry weight (the normal seedlings of the germination test were dried in an oven with forced air circulation, under 40⁰C temperature, until reaching constant weight); g) emergency and emergency speed index [the emergency test was performed and the percentage was counted on the tenth DAS (Brasil, 2009aBRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009a. Regras para análise de sementes. Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/regras_analise_de_sementes.pdf.
https://www.abrates.org.br/files/regras_... ). Fifty seeds were sown per plot in polyethylene trays of 200 cells with substrate Carolina Soil^® for vegetable seedlings production which remained in the greenhouse. The count of emerged seedlings was initiated when the first seedling emerged, with daily counting until stabilization to obtain the emergency speed index, calculated using the formula of Maguire (1962MAGUIRE, JD. 1962. Speed of germination-aid in selection and evaluation for seedling emergence and vigor. Crop Science2: 176-177.)]; h) sanitary test [the blotter test was used according to the Seed Sanitary Analysis Manual (Brasil, 2009bBRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009b. Manual de Análise Sanitária de Sementes. Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/manual-de-analise-sanitaria-de-sementes.pdf.
https://www.abrates.org.br/files/manual-... ). In each plot 25 seeds were placed in petri dishes and kept in an incubation chamber for 24 hours at 20ºC. Then they were subjected to freezing for 24 hours at -20°C in order to suppress seed germination. Afterwards, they returned to the incubator at 20ºC for more 5 days, under alternating light and dark for 12 hours. After this period, fungi were evaluated, using a stereoscopic microscope, accounting for the presence or absence in each seed unit, and results were expressed in percentage].

Data were subjected to analysis of variance, and regression analysis was applied to the concentration factor, while for the essential oils factor the Tukey test was applied, both at 5% probability (Ferreira, 2011FERREIRA, DF. 2011. Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia35: 1039-1042.).

RESULTS AND DISCUSSION

A. flavus is one of the fungi which most affects seeds due to the consumption of their reserves, which are used in the germination process and directly affect seed vigor. Rosemary oil did not inhibit the development of A. flavus in cauliflower seeds. The essential oils of thyme and lemongrass had total control of A. flavus in its highest concentration (Figure 1).

Figure 1
Percentage of cauliflower seeds with Aspergillus flavus in treated seeds with essential oils of thyme, lemongrass and rosemary in different concentrations. Dracena, UNESP, 2021.

It is worth highlighting the components and concentrations of each of them, even to compare with results in the literature, since each lot has its variation, it also depends on the place of cultivation, the time of harvest, among other factors that end up interfering. For example, the essential oil of thyme contains thymol (46.6%) and p-cymene (38.9%), which must have promoted a fungistatic action in controlling the fungus. Borugã et al. (2014BORUGÃ, O; JIANU, C; MIŞCĂ, C; GOLET, I; GRUIA, AT; HORHAT, FG. 2014. Thymus vulgaris essential oil: Chemical composition and antimicrobial activity. Journal of Medicine and Life7: 56-60.) analyzed the components of the thyme essential oil and detected three major components, thymol (47.6%), p-cymene (8.4%) and γ-terpinene (30.9%) which have probably the greatest antimicrobial potentials, differing from the oil of the present study. Comparing oils (thyme), from the present study and from the study of Borugã et al. (2014)BORUGÃ, O; JIANU, C; MIŞCĂ, C; GOLET, I; GRUIA, AT; HORHAT, FG. 2014. Thymus vulgaris essential oil: Chemical composition and antimicrobial activity. Journal of Medicine and Life7: 56-60., there is a similar amount of thymol and a high discrepancy between the other two components, however, having the same antimicrobial action.

The thyme essential oils from each mentioned study result in a difference in concentration as they are extracted from plants from different locations, as already mentioned and also can be observed in the work of Jakiemiu et al. (2010JAKIEMIU, EAR; SCHEER, AP; OLIVEIRA, JS; CÔCCO, LC; YAMAMOTO, CI; DESCHAMPS, C. 2010. Study of composition and yield of Thymus vulgaris L. oil essential. Semina: Ciências Agrárias 31: 683-688.) who identified 33 compounds in thyme essential oil, the majority being thymol (50.4 to 55%), p-cymene (17 to 21%) and γ-terpinene (5 to 7%). There was a high variation of the three compounds compared to the one used in the present study. However, thymol is presented in greater quantity in all cited works being believed that this is the main antimicrobial component. Other researches had positive results with the use of thyme essential oil against fungi. Kohiyama et al. (2015KOHIYAMA, CY; YAMAMOTO, M; RIBEIRO, M; APARECIDA, S; MOSSINI, G; BANDO, E; BOMFIM, NS; NERILO, SB; ROCHA, GHO; GRESPAN, R; MIKCHA, JMG; MACHINSKI, M. 2015. Antifungal properties and inhibitory effects upon aflatoxin production of Thymus vulgaris L. by Aspergillus flavus Link. Food Chemistry 173: 1006-1010.) verified fungicidal effect against A. flavus at a concentration of 250 μg mL^-1 which caused cell cytoplasm leakage. Tian et al. (2019TIAN, F; LEE, SY; CHUN, HS. 2019. Comparison of the antifungal and antiaflatoxigenic potential of liquid and vapor phase of Thymus vulgaris essential oil against Aspergillus flavus. Journal of Food Protection82: 2044 -2048.) studied the use of thyme essential oil in the vapor and liquid phase to control A. flavus, and found positive effects at the concentration of 20 and 400 μg mL^-1, reducing aflatoxin production by 97.0 and 56.4%, respectively, concluding that the essential oil in the vapor phase can be a good strategy to control fungal contamination (Silva et al., 2012SILVA, FC; CHALFOUN, SM; SIQUEIRA, VM; BOTELHO, DMS; LIMA, N; BATISTA, LR. 2012. Evaluation of antifungal activity of essential oils against potentially mycotoxigenic Aspergillus flavus and Aspergillus parasiticus. Revista Brasileira de Farmacognosia 22: 1002-1010.). Silva et al. (2012)SILVA, FC; CHALFOUN, SM; SIQUEIRA, VM; BOTELHO, DMS; LIMA, N; BATISTA, LR. 2012. Evaluation of antifungal activity of essential oils against potentially mycotoxigenic Aspergillus flavus and Aspergillus parasiticus. Revista Brasileira de Farmacognosia 22: 1002-1010. reported also that the major antifungal component of thyme essential oil is thymol and that at a concentration of 50% (oil/dimethyl sulfoxide; v/v) it controlled A. flavus. Koch et al. (2010KOCH, E; SCHMITT, A; STEPHAN, D; KROMPHARDT, C; JAHN, M; KRAUTHAUSEN, HJ; FORSBERG, G; WERNER, S; AMEIN, T; WRIGHT, SAI; TINIVELLA, F; GULLINO, ML; ROBERTS, SJ; WOLF, J; GROOT, SPC. 2010. Evaluation of non-chemical seed treatment methods for the control of Alternaria dauci and A. radicina on carrot seeds. European Journal of Plant Pathology 127: 99-112.) observed the control of the Alternaria dauci and A. radicina in carrot seeds at a concentration of 1%.

Non treated seeds presented 100% infection from A. flavus (concentration 0%), showing the efficiency of inoculation. The essential thyme oil at 0.4% significantly reduced the contamination of cauliflower seeds contaminated with A. flavus, not differing from other essential oils, while in concentrations from 0.6% to 2.0% thyme and lemongrass essential oils significantly reduced the contamination, differing from rosemary essential oil (Table 1).

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Table 1
Aspergillus flavus in cauliflower seeds treated with essential oils of rosemary, lemongrass and thyme in different concentrations. Dracena, UNESP, 2021.

Shah et al. (2011SHAH, G; SHRI, R; PANCHAL, V; SHARMA, N; SINGH, B; MANN, AS. 2011. Scientific basis for the therapeutic use of Cymbopogon citratus, Stapf (Lemon grass). Journal of Advanced Pharmaceutical Technology and Research 1: 3-8.) reported that lemongrass essential oil has antifungal action and components such as geranial and neral, among others that act to control fungi. Studies show the efficiency of lemongrass essential oil as occurred in the study by Sonker et al. (2014SONKER, N; PANDEY, AK; SINGH, P; TRIPATHI, NN. 2014. Assessment of Cymbopogon citratus (dc.) Stapf essential oil as herbal preservatives based on antifungal, antiaflatoxin, and antiochratoxin activities and in vivo efficacy during storage. Journal of Food Science 79: 628-634.) who in their research verified the efficiency at a concentration of 0.33 μL mL^-1 and inhibiting 100% mycelial growth of A. flavus.Martinazzo et al. (2019MARTINAZZO, AP; OLIVEIRA, FS; TEODORO, CES. 2019. Antifungal activity of Cymbopogon citratus essential oil against Aspergillus flavus. Ciência e Natura41: 01-08.) also verified efficiency in vitro test to control 100% of A. flavus, using lemongrass essential oil at 1.0 μL mL^-1 concentration.

Subramanian et al. (2015SUBRAMANIAN, P; TAKWA, CWICW; EMELIA, AZN. 2015. Chemical composition and antibacterial activity of essential oil of Cymbopogon citratus and Cymbopogon nardus against Enterococcus faecalis. International Journal of Biosciences 6: 9-17.) concluded an antimicrobial effect and identified the chemical composition of the essential oil of lemongrass, as follows: geranial (32.4%), beta-citral (23.8%) and geraniol (12.0%), and the essential oil used in this research was composed of 44.4% geranial. Millezi et al. (2012MILLEZI, AF; CAIXETA, DS; ROSSONI, DF; CARDOSO, MG; PICCOLI, RH. 2012. In vitro antimicrobial properties of plant essential oils Thymus vulgaris, Cymbopogon citratus and Laurus nobilis against five important foodborne pathogens. Ciência e Tecnologia de Alimentos32: 167-172.) also found an antibacterial effect and again the concentration of geranial varied, resulting in 47.0%. This demonstrates that depending on the type of oil used, as they are from different locations, they may or may not be efficient in controlling phytopathogens.

Rosemary essential oil was not efficient in controlling A. flavus in cauliflower seeds, which continued to be highly contaminated (Table 1). Contrary results of the present study were found in the research of Iordache et al. (2006IORDACHE, O; COZEA, A; VĂRZARU, E; STOICA, E; PLATON, C; RODINO, S; DUMITRESCU, I. 2006. Antimicrobial activity of textiles treated with Rosemary and orange essential oils against a selection of pathogenic fungi. Scientific Bulletin, Series F. Biotechnologies 20: 362-369.), studying rosemary essential oil; they related reduction of 22.2% in A. niger analized in vitro. Lee et al. (2020LEE, LT; GARCIA, SA; MARTINAZZO, AP; TEODORO, CES. 2020. Fungitoxity and chemical composition of rosemary essential oil (Rosmarinus officinalis) on Aspergillus flavus. Research, Society and Development9: e202985628.) concluded efficiency in the control of A. flavus using rosemary essential oil at 25 μL mL^-1 concentration. Baghloul et al. (2017BAGHLOUL, F; MANSORI, R; DJAHOUDI, A. 2017. In vitro antifungal effect of Rosmarinus officinalis essential oil on Aspergillus niger. National Journal of Physiology, Pharmacy and Pharmacology 7: 285-289.), reported that rosemary essential oil with 1,8-cineole major compound (63.6%), has a fungistatic activity on foods contaminated by A. niger at a minimum inhibitory concentration of 0.5%. Bomfim et al. (2015BOMFIM, NS; NAKASSUGI, LP; OLIVEIRA, JFP; KOHIYAMA, CY; MOSSINI, SAG; GRESPAN, R; NERILO, SB; MALLMANN, CA; ABREU JUNIOR, BA; MACHINSKI FILHO, M. 2015. Antifungal activity and inhibition of fumonisin production by Rosmarinus officinalis L. essential oil in Fusarium verticillioides (Sacc.). Food Chemistry 166: 330-336.) detected three compounds that supposedly act in the control of microorganisms: 1,8-cineole (52.2%), camphor (15.2%) and α-pinene (12.4%). In the same way that it happened for thyme oil, it happened for rosemary, where there is a difference in the concentration of components, and 1,8-cineole is the component with the highest content in the oil of the present study, presenting 41.2%, however, it was not enough to control A. flavus. The essential oils of thyme and lemongrass have a fungistatic effect against A. flavus in cauliflower seeds, and especially as regards the essential oil of thyme. Rosemary essential oil, on the other hand, was not efficient in controlling this pathogen.

Germination and vigor of cauliflower seeds

Essential oils of thyme and rosemary, did not affect germination of cauliflower seeds and did not show any significant difference between them in any of the concentrations (Table 2). However, when the seeds were treated with lemongrass essential oil, germination was lower at 0.8 and 2.0%. In the research by Souza et al. (2007SOUZA, AE; ARAÚJO, E; NASCIMENTO, LC. 2007. Antifungal activity of garlic and lemon grass extracts on the development of Fusarium proliferatum isolated from maize grain. Brazilian Phytopathology 32: 465-471.) there was an increase in corn seed germination when treated with 0.5% lemongrass essential oil. Oliveira & Sá (2014OLIVEIRA, AS; SÁ, ME. 2014. Alternativas para redução de resíduos químicos e exposição ocupacional no laboratório de análise de sementes. Archives of Health Investigation. 3: 12-16.) also observed that this essential oil used in seed treatment at a concentration of 3 mL L^-1 improved germination and vigor of rice, bean and soybean seeds.

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Table 2
Germination of cauliflower seeds inoculated with Aspergillus flavus and treated with essential oil of rosemary, lemongrass and thyme in different concentrations. Dracena, UNESP, 2021.

For vigor characteristics, the first germination count and emergency speed index (ESI) had a significant effect only for essential oils (Table 3). For the first germination count, there was no significant difference between the rosemary and thyme oils, being superior to lemongrass essential oil. For the ESI, thyme essential oil was superior to the other oils which did not differ between itself.

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Table 3
First germination count and emergency speed index (ESI) of cauliflower seeds inoculated with Aspergillus flavus and treated with essential oil of rosemary, lemongrass and thyme in different concentrations. Dracena, UNESP, 2021.

For seedling dry weight (mean: 1.86 mg seedling^-1), emergence (mean: 83%), shoot length (mean: 2.8 cm), primary root (mean: 4.0 cm) and seedling length (mean: 6.8 cm) there was no significant difference among treatments. As for most physiological quality traits there was no significant effect for essential oils when treating the seeds; it is possible to assume a promising treatment via seeds for the organic production system, especially those that showed an effect in controlling A. flavus.

The essential oils of thyme (1.8%) and lemongrass (1.9%) had a fungistatic effect against A. flavus in cauliflower seeds. Thyme essential oil at 2.0% and lemongrass at 1.6% didn’t affect the physiological quality of seeds, being promising in the treatment of organic seeds. On the other hand, rosemary essential oil, despite not affecting germination and little affecting seed vigor, wasn’t efficient in controlling the pathogen.

ACKNOWLEDGMENTS

To FAPESP (São Paulo State Research Support Foundation) for granting the scientific initiation scholarship, process 2018/14890-1 and to Feltrin^® Seeds for granting the seeds for research.

REFERENCES

AGROFIT - Sistemas de Agrotóxicos Fitossanitários 2020. Available at<Available athttp://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons >. AccessedJanuary 3, 2021.
» http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons
BAGHLOUL, F; MANSORI, R; DJAHOUDI, A. 2017. In vitro antifungal effect of Rosmarinus officinalis essential oil on Aspergillus niger National Journal of Physiology, Pharmacy and Pharmacology 7: 285-289.
BOMFIM, NS; NAKASSUGI, LP; OLIVEIRA, JFP; KOHIYAMA, CY; MOSSINI, SAG; GRESPAN, R; NERILO, SB; MALLMANN, CA; ABREU JUNIOR, BA; MACHINSKI FILHO, M. 2015. Antifungal activity and inhibition of fumonisin production by Rosmarinus officinalis L. essential oil in Fusarium verticillioides (Sacc.). Food Chemistry 166: 330-336.
BORUGÃ, O; JIANU, C; MIŞCĂ, C; GOLET, I; GRUIA, AT; HORHAT, FG. 2014. Thymus vulgaris essential oil: Chemical composition and antimicrobial activity. Journal of Medicine and Life7: 56-60.
BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009a. Regras para análise de sementes Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/regras_analise_de_sementes.pdf
» https://www.abrates.org.br/files/regras_analise_de_sementes.pdf
BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009b. Manual de Análise Sanitária de Sementes Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/manual-de-analise-sanitaria-de-sementes.pdf
» https://www.abrates.org.br/files/manual-de-analise-sanitaria-de-sementes.pdf
CARDOSO, AII; KRONKA, AZ; LANNA, NBL; SILVA, PNL; COLOMBARI, LF; SANTOS, PL; PIEROZZI, CG. 2016. Treatment with thiabendazole in germination, vigor, and incidence of fungi in zucchini seeds. Australian Journal of Crop Science10: 1589-1593.
FERREIRA, DF. 2011. Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia35: 1039-1042.
FIGUEIREDO, AR; SILVA, LR; MORAIS, LAS. 2021. Sensitivity of Colletotrichum gloeosporioides in passion fruit to essential oils. Revista Desafios 8: 19-30.
IORDACHE, O; COZEA, A; VĂRZARU, E; STOICA, E; PLATON, C; RODINO, S; DUMITRESCU, I. 2006. Antimicrobial activity of textiles treated with Rosemary and orange essential oils against a selection of pathogenic fungi. Scientific Bulletin, Series F. Biotechnologies 20: 362-369.
JAKIEMIU, EAR; SCHEER, AP; OLIVEIRA, JS; CÔCCO, LC; YAMAMOTO, CI; DESCHAMPS, C. 2010. Study of composition and yield of Thymus vulgaris L. oil essential. Semina: Ciências Agrárias 31: 683-688.
KOCH, E; SCHMITT, A; STEPHAN, D; KROMPHARDT, C; JAHN, M; KRAUTHAUSEN, HJ; FORSBERG, G; WERNER, S; AMEIN, T; WRIGHT, SAI; TINIVELLA, F; GULLINO, ML; ROBERTS, SJ; WOLF, J; GROOT, SPC. 2010. Evaluation of non-chemical seed treatment methods for the control of Alternaria dauci and A. radicina on carrot seeds. European Journal of Plant Pathology 127: 99-112.
KOHIYAMA, CY; YAMAMOTO, M; RIBEIRO, M; APARECIDA, S; MOSSINI, G; BANDO, E; BOMFIM, NS; NERILO, SB; ROCHA, GHO; GRESPAN, R; MIKCHA, JMG; MACHINSKI, M. 2015. Antifungal properties and inhibitory effects upon aflatoxin production of Thymus vulgaris L. by Aspergillus flavus Link. Food Chemistry 173: 1006-1010.
KRZYZANOWSKI, FC; FRANÇA NETO, JB. 2001. Vigor de sementes Informativo Abrates. Embrapa, 11: 81-84.
LEE, LT; GARCIA, SA; MARTINAZZO, AP; TEODORO, CES. 2020. Fungitoxity and chemical composition of rosemary essential oil (Rosmarinus officinalis) on Aspergillus flavus Research, Society and Development9: e202985628.
MACHADO, JC; OLIVEIRA, JA; VIEIRA, MGGC; ALVES, MC. 2001. Artificial inoculation of fungi in soybean seeds using manitol solution. Brazilian Journal of Seed Science23: 95-101.
MAGUIRE, JD. 1962. Speed of germination-aid in selection and evaluation for seedling emergence and vigor. Crop Science2: 176-177.
MARTINAZZO, AP; OLIVEIRA, FS; TEODORO, CES. 2019. Antifungal activity of Cymbopogon citratus essential oil against Aspergillus flavus Ciência e Natura41: 01-08.
MARTINS, IR; SOUZA, EP; SANTOS, TP; ANJOS, LVS; NAKADA-FREITAS, PG; CARDOSO, AII. 2016. Inoculação de Aspergillus sp. em sementes de coentro. XXVIII Congress of Scientific Initiation of Unesp, Dracena/ Brazil
MILLEZI, AF; CAIXETA, DS; ROSSONI, DF; CARDOSO, MG; PICCOLI, RH. 2012. In vitro antimicrobial properties of plant essential oils Thymus vulgaris, Cymbopogon citratus and Laurus nobilis against five important foodborne pathogens. Ciência e Tecnologia de Alimentos32: 167-172.
OLIVEIRA, AS; SÁ, ME. 2014. Alternativas para redução de resíduos químicos e exposição ocupacional no laboratório de análise de sementes. Archives of Health Investigation 3: 12-16.
OLIVEIRA, FS; TEODORO, CES; BERBERT, PA; MARTINAZZO, AP. 2020. Evaluation of the antifungal potential of Cymbopogon citratus essential oil in the control of the fungus Aspergillus brasiliensis Research, Society and Development 9: 1-17.
PRAKASH, B; KEDIA, A; MISHRA, PK; DWIVEDY, AK; DUBEY, NK. 2015. Assessment of chemically characterised Rosmarinus officinalis L. essential oil and its major compounds as plant-based preservative in food system based on their efficacy against food-borne moulds and aflatoxin secretion and as antioxidante. International Journal of Food Science and Technology 50: 1792-1798.
ROMERO, AL; ROMERO, RB; SILVA, EL; DINIZ, SPSS; OLIVEIRA, RR; VIDA, JB. 2012. Chemical composition and activity of Origanum vulgare essential oil against phytopathogenic fungi. UNOPAR Científica Ciências Biológicas e da Saúde14: 231-235.
SANTOS, ACA; ROSSATO, M; SERAFINI, LA; BUENO, M; CRIPPA, LB; SARTORI, VC; DELLACASSA, E; MOYNA, P. 2010. Efeito fungicida dos óleos essenciais de Schinus molle L. e Schinus terebinthifolius Raddi, Anacardiaceae, do Rio Grande do Sul. Revista Brasileira de Farmacognosia20: 154-159.
SHAH, G; SHRI, R; PANCHAL, V; SHARMA, N; SINGH, B; MANN, AS. 2011. Scientific basis for the therapeutic use of Cymbopogon citratus, Stapf (Lemon grass). Journal of Advanced Pharmaceutical Technology and Research 1: 3-8.
SILVA, FC; CHALFOUN, SM; SIQUEIRA, VM; BOTELHO, DMS; LIMA, N; BATISTA, LR. 2012. Evaluation of antifungal activity of essential oils against potentially mycotoxigenic Aspergillus flavus and Aspergillus parasiticus Revista Brasileira de Farmacognosia 22: 1002-1010.
SONKER, N; PANDEY, AK; SINGH, P; TRIPATHI, NN. 2014. Assessment of Cymbopogon citratus (dc.) Stapf essential oil as herbal preservatives based on antifungal, antiaflatoxin, and antiochratoxin activities and in vivo efficacy during storage. Journal of Food Science 79: 628-634.
SOUSA, LL; ANDRADE, SCA; ATHAYDE, AJAA; OLIVEIRA, CEV; SALES, CV; MADRUGA, MS; SOUZA, EL. 2013. Efficacy of Origanum vulgare L. and Rosmarinus officinalis L. essential oils in combination to control postharvest pathogenic Aspergilli and autochthonous mycoflora in Vitis labrusca L. (table grapes). International Journal of Food Microbiology165: 312 -318.
SOUZA, AE; ARAÚJO, E; NASCIMENTO, LC. 2007. Antifungal activity of garlic and lemon grass extracts on the development of Fusarium proliferatum isolated from maize grain. Brazilian Phytopathology 32: 465-471.
SUBRAMANIAN, P; TAKWA, CWICW; EMELIA, AZN. 2015. Chemical composition and antibacterial activity of essential oil of Cymbopogon citratus and Cymbopogon nardus against Enterococcus faecalis International Journal of Biosciences 6: 9-17.
TEIXEIRA, GA; ALVES, E; AMARAL, DC; MACHADO, JC; PERINA, FJ. 2013. Essential oils on the control of stem and ear rot in maize. Ciência Rural43: 1945-1951.
TIAN, F; LEE, SY; CHUN, HS. 2019. Comparison of the antifungal and antiaflatoxigenic potential of liquid and vapor phase of Thymus vulgaris essential oil against Aspergillus flavus Journal of Food Protection82: 2044 -2048.
VECCHIA, AD; CASTILHOS-FORTES, R. 2007. Fungical contamination in commercial granola. Food Science and Technology27: 324-327

Publication Dates

Publication in this collection
22 Apr 2022
Date of issue
Jan-Mar 2022

History

Received
07 May 2021
Accepted
12 Jan 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AGROFIT - Sistemas de Agrotóxicos Fitossanitários 2020. Available at<Available athttp://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons >. AccessedJanuary 3, 2021.
» http://agrofit.agricultura.gov.br/agrofit_cons/principal_agrofit_cons

[2] BAGHLOUL, F; MANSORI, R; DJAHOUDI, A. 2017. In vitro antifungal effect of Rosmarinus officinalis essential oil on Aspergillus niger National Journal of Physiology, Pharmacy and Pharmacology 7: 285-289.

[3] BOMFIM, NS; NAKASSUGI, LP; OLIVEIRA, JFP; KOHIYAMA, CY; MOSSINI, SAG; GRESPAN, R; NERILO, SB; MALLMANN, CA; ABREU JUNIOR, BA; MACHINSKI FILHO, M. 2015. Antifungal activity and inhibition of fumonisin production by Rosmarinus officinalis L. essential oil in Fusarium verticillioides (Sacc.). Food Chemistry 166: 330-336.

[4] BORUGÃ, O; JIANU, C; MIŞCĂ, C; GOLET, I; GRUIA, AT; HORHAT, FG. 2014. Thymus vulgaris essential oil: Chemical composition and antimicrobial activity. Journal of Medicine and Life7: 56-60.

[5] BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009a. Regras para análise de sementes Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/regras_analise_de_sementes.pdf
» https://www.abrates.org.br/files/regras_analise_de_sementes.pdf

[6] BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. 2009b. Manual de Análise Sanitária de Sementes Brasília: Mapa/ACS. Available at: https://www.abrates.org.br/files/manual-de-analise-sanitaria-de-sementes.pdf
» https://www.abrates.org.br/files/manual-de-analise-sanitaria-de-sementes.pdf

[7] CARDOSO, AII; KRONKA, AZ; LANNA, NBL; SILVA, PNL; COLOMBARI, LF; SANTOS, PL; PIEROZZI, CG. 2016. Treatment with thiabendazole in germination, vigor, and incidence of fungi in zucchini seeds. Australian Journal of Crop Science10: 1589-1593.

[8] FERREIRA, DF. 2011. Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia35: 1039-1042.

[9] FIGUEIREDO, AR; SILVA, LR; MORAIS, LAS. 2021. Sensitivity of Colletotrichum gloeosporioides in passion fruit to essential oils. Revista Desafios 8: 19-30.

[10] IORDACHE, O; COZEA, A; VĂRZARU, E; STOICA, E; PLATON, C; RODINO, S; DUMITRESCU, I. 2006. Antimicrobial activity of textiles treated with Rosemary and orange essential oils against a selection of pathogenic fungi. Scientific Bulletin, Series F. Biotechnologies 20: 362-369.

[11] JAKIEMIU, EAR; SCHEER, AP; OLIVEIRA, JS; CÔCCO, LC; YAMAMOTO, CI; DESCHAMPS, C. 2010. Study of composition and yield of Thymus vulgaris L. oil essential. Semina: Ciências Agrárias 31: 683-688.

[12] KOCH, E; SCHMITT, A; STEPHAN, D; KROMPHARDT, C; JAHN, M; KRAUTHAUSEN, HJ; FORSBERG, G; WERNER, S; AMEIN, T; WRIGHT, SAI; TINIVELLA, F; GULLINO, ML; ROBERTS, SJ; WOLF, J; GROOT, SPC. 2010. Evaluation of non-chemical seed treatment methods for the control of Alternaria dauci and A. radicina on carrot seeds. European Journal of Plant Pathology 127: 99-112.

[13] KOHIYAMA, CY; YAMAMOTO, M; RIBEIRO, M; APARECIDA, S; MOSSINI, G; BANDO, E; BOMFIM, NS; NERILO, SB; ROCHA, GHO; GRESPAN, R; MIKCHA, JMG; MACHINSKI, M. 2015. Antifungal properties and inhibitory effects upon aflatoxin production of Thymus vulgaris L. by Aspergillus flavus Link. Food Chemistry 173: 1006-1010.

[14] KRZYZANOWSKI, FC; FRANÇA NETO, JB. 2001. Vigor de sementes Informativo Abrates. Embrapa, 11: 81-84.

[15] LEE, LT; GARCIA, SA; MARTINAZZO, AP; TEODORO, CES. 2020. Fungitoxity and chemical composition of rosemary essential oil (Rosmarinus officinalis) on Aspergillus flavus Research, Society and Development9: e202985628.

[16] MACHADO, JC; OLIVEIRA, JA; VIEIRA, MGGC; ALVES, MC. 2001. Artificial inoculation of fungi in soybean seeds using manitol solution. Brazilian Journal of Seed Science23: 95-101.

[17] MAGUIRE, JD. 1962. Speed of germination-aid in selection and evaluation for seedling emergence and vigor. Crop Science2: 176-177.

[18] MARTINAZZO, AP; OLIVEIRA, FS; TEODORO, CES. 2019. Antifungal activity of Cymbopogon citratus essential oil against Aspergillus flavus Ciência e Natura41: 01-08.

[19] MARTINS, IR; SOUZA, EP; SANTOS, TP; ANJOS, LVS; NAKADA-FREITAS, PG; CARDOSO, AII. 2016. Inoculação de Aspergillus sp. em sementes de coentro. XXVIII Congress of Scientific Initiation of Unesp, Dracena/ Brazil

[20] MILLEZI, AF; CAIXETA, DS; ROSSONI, DF; CARDOSO, MG; PICCOLI, RH. 2012. In vitro antimicrobial properties of plant essential oils Thymus vulgaris, Cymbopogon citratus and Laurus nobilis against five important foodborne pathogens. Ciência e Tecnologia de Alimentos32: 167-172.

[21] OLIVEIRA, AS; SÁ, ME. 2014. Alternativas para redução de resíduos químicos e exposição ocupacional no laboratório de análise de sementes. Archives of Health Investigation 3: 12-16.

[22] OLIVEIRA, FS; TEODORO, CES; BERBERT, PA; MARTINAZZO, AP. 2020. Evaluation of the antifungal potential of Cymbopogon citratus essential oil in the control of the fungus Aspergillus brasiliensis Research, Society and Development 9: 1-17.

[23] PRAKASH, B; KEDIA, A; MISHRA, PK; DWIVEDY, AK; DUBEY, NK. 2015. Assessment of chemically characterised Rosmarinus officinalis L. essential oil and its major compounds as plant-based preservative in food system based on their efficacy against food-borne moulds and aflatoxin secretion and as antioxidante. International Journal of Food Science and Technology 50: 1792-1798.

[24] ROMERO, AL; ROMERO, RB; SILVA, EL; DINIZ, SPSS; OLIVEIRA, RR; VIDA, JB. 2012. Chemical composition and activity of Origanum vulgare essential oil against phytopathogenic fungi. UNOPAR Científica Ciências Biológicas e da Saúde14: 231-235.

[25] SANTOS, ACA; ROSSATO, M; SERAFINI, LA; BUENO, M; CRIPPA, LB; SARTORI, VC; DELLACASSA, E; MOYNA, P. 2010. Efeito fungicida dos óleos essenciais de Schinus molle L. e Schinus terebinthifolius Raddi, Anacardiaceae, do Rio Grande do Sul. Revista Brasileira de Farmacognosia20: 154-159.

[26] SHAH, G; SHRI, R; PANCHAL, V; SHARMA, N; SINGH, B; MANN, AS. 2011. Scientific basis for the therapeutic use of Cymbopogon citratus, Stapf (Lemon grass). Journal of Advanced Pharmaceutical Technology and Research 1: 3-8.

[27] SILVA, FC; CHALFOUN, SM; SIQUEIRA, VM; BOTELHO, DMS; LIMA, N; BATISTA, LR. 2012. Evaluation of antifungal activity of essential oils against potentially mycotoxigenic Aspergillus flavus and Aspergillus parasiticus Revista Brasileira de Farmacognosia 22: 1002-1010.

[28] SONKER, N; PANDEY, AK; SINGH, P; TRIPATHI, NN. 2014. Assessment of Cymbopogon citratus (dc.) Stapf essential oil as herbal preservatives based on antifungal, antiaflatoxin, and antiochratoxin activities and in vivo efficacy during storage. Journal of Food Science 79: 628-634.

[29] SOUSA, LL; ANDRADE, SCA; ATHAYDE, AJAA; OLIVEIRA, CEV; SALES, CV; MADRUGA, MS; SOUZA, EL. 2013. Efficacy of Origanum vulgare L. and Rosmarinus officinalis L. essential oils in combination to control postharvest pathogenic Aspergilli and autochthonous mycoflora in Vitis labrusca L. (table grapes). International Journal of Food Microbiology165: 312 -318.

[30] SOUZA, AE; ARAÚJO, E; NASCIMENTO, LC. 2007. Antifungal activity of garlic and lemon grass extracts on the development of Fusarium proliferatum isolated from maize grain. Brazilian Phytopathology 32: 465-471.

[31] SUBRAMANIAN, P; TAKWA, CWICW; EMELIA, AZN. 2015. Chemical composition and antibacterial activity of essential oil of Cymbopogon citratus and Cymbopogon nardus against Enterococcus faecalis International Journal of Biosciences 6: 9-17.

[32] TEIXEIRA, GA; ALVES, E; AMARAL, DC; MACHADO, JC; PERINA, FJ. 2013. Essential oils on the control of stem and ear rot in maize. Ciência Rural43: 1945-1951.

[33] TIAN, F; LEE, SY; CHUN, HS. 2019. Comparison of the antifungal and antiaflatoxigenic potential of liquid and vapor phase of Thymus vulgaris essential oil against Aspergillus flavus Journal of Food Protection82: 2044 -2048.

[34] VECCHIA, AD; CASTILHOS-FORTES, R. 2007. Fungical contamination in commercial granola. Food Science and Technology27: 324-327

Essential oil	Concentration (%)
Essential oil	0.0	0.4	0.8	1.2	1.6	2.0
Rosemary	100 a¹	100 c	100 b	100 b	94 b	99 b
Lemongrass	100 a	77 b	26 a	20 a	17 a	13 a
Thyme	100 a	39 a	20 a	16 a	14 a	4 a
CV (%)	10,3

Essential oil	Concentration (%)
Essential oil	0.0	0.4	0.8	1.2	1.6	2.0
Rosemary	86 a¹	83 a	93 ab	96 a	91 a	88 a
Lemongrass	86 a	88 a	81 b	93 a	84 a	60 b
Thyme	86 a	87 a	97 a	94 a	87 a	93 a
CV (%)	8,4

Essential oil	First count (%)	ESI
Rosemary	85 a¹	4.7 b
Lemongrass	67 b	4.8 b
Thyme	83 a	5.2 a
CV (%)	19,1	7,2

Brasil

Brasil

Effect of thyme, lemongrass and rosemary essential oils on Aspergillus flavus in cauliflower seeds

Efeito de óleos essenciais de tomilho, capim-limão e alecrim sobre Aspergillus flavus em sementes de couve-flor

ABSTRACT

RESUMO

MATERIAL AND METHODS

RESULTS AND DISCUSSION

Germination and vigor of cauliflower seeds

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History