Abstracts

INTRODUCTION

Due to intensive use in agriculture, herbicides are often detected in studies about the quality of surface water and groundwater (Carter, 2000CARTER, A.D. Herbicide movement in soils: principles, pathways and processes. Weed Res., v. 40, n. 1, p. 113-122, 2000.; Tanabe et al., 2001TANABE, A. et al. Seasonal and special studies on pesticides residues in surface eaters of the Shinano river in Japan. J. Agric. Food Chem., v. 49, n. 7, p. 3847-3852, 2001.). Many of these records are found in areas of sugarcane cultivation, as this is one of the cultures that uses more herbicides in weeds tillage by acreage unit (Southwick et al., 2002SOUTHWICK, L. M. et al. Potential influence of sugarcane cultivation on estuarine water quality of Louisiana's gulf coast. J. Agric. Food Chem., v. 50, n. 15, p. 4393-4399, 2002.).

Leaching is critical for surface incorporation of most herbicides, reaching seeds or plants germinating, but when excessive, can carry them into deeper layers of the soil, limiting its action, and may even promote groundwater contamination (Monquero et al., 2014MONQUERO, P. A. et al. Manejo de Merremia aegyptia com misturas de herbicidas utilizando diferentes lâminas de água e na presença ou ausência de palha de cana-de-açúcar. R. Bras. Herbic., v. 13, n. 2, p. 88-96, 2014. ).

Among the most widely used herbicides in the culture of sugarcane is sulfentrazone 2',4' dichloro-5-(4-difluoromethyl-4,5-dihydro 3 methyl-5-oxo-1H1,2,4-triazol-1-yl) methanesulfonanilide. This herbicide is an inhibitor of protoporphyrinogen oxidase (PROTOX). According to Rodrigues & Almeida (2011)RODRIGUES, B. N.; ALMEIDA, F.S. Guia de herbicidas. 6. ed. Londrina: 2011. 697 p., it is used in preemergence for the control of dicotyledonous weeds in many monocotyledonous species such as sugarcane. Its half-life in the soil (t_1/2) is estimated as being between 110 and 280 days, and its solubility increases with increasing pH (pH 6.0 = 10 mg L^-1; pH 7.5 = 1,600 mg L^-1). It is considered a weak acid herbicide (pKa = 6.56) and therefore, ionizable, lying in different proportions of its molecular shapes (pH < pKa) and anionic (pH > pKa), depending on the medium pH (FMC Corp., 1995FMC Crop. Technical bulletin of sulfentrazone. Philadelphia: 1995. 6 p.).

Several studies have shown that the dynamics of sulfentrazone depends largely on the physical and chemical characteristics of the soil, especially the organic matter content, pH and mineralogy (Passos et al., 2013PASSOS, A. B. R. J. et al. Leaching of sulfentrazone in soils of reforestation in Brazil. Environmental Earth Sciences, v. 74, n. 2, p. 1211-1215, 2015. Disponível em: < http://link.springer.com/article/10.1007%2Fs12665-015-4110-7>. Acesso em: 20 set. 2015.
http://link.springer.com/article/10.1007... ; Freitas et al., 2014FREITAS, M. A. M. et al. Sorção do sulfentrazone em diferentes tipos de solo determinada por bioensaios. Planta Daninha, v. 32, n. 2, p. 385-392, 2014.).

In Brazil, the land of the Northeast Region they have practically not been studied with regard to herbicides behavior. The soils of the semiarid region have chemical and mineralogical characteristics that are different from those observed in tropical regions because in general they are less weathered, have an alkaline pH, low organic carbon content, and often have a high concentration of salts.

Under these conditions, it is assumed that the risk of sulfentrazone leaching is higher due to the lower adsorption of the herbicide in the soil colloids, which can cause poisoning of crops and soil and water contamination. Freitas et al. (2012) have observed greater ametryn mobility in soils of the semiarid region of the Brazilian state of Rio Grande do Norte, in relation to the yellowish-red latosol of Minas Gerais, influenced by low organic matter content and alkaline pH of the semiarid region soils.

Herbicides leaching in the field can be monitored by direct sampling of water, soil samples analyses and using lysimeters. However, it has become common to measure the potential for leaching using columns with disturbed soil samples by means of biological and chromatographic assays. These experiments employ humidity and precipitation controlled conditions and enable comparison of different soil classes in a single assay (Freitas et al., 2014; Passos et al., 2015).

Given the above, the aim of this study was to evaluate the leaching of sulfentrazone in five soils of the Northeast Region of Brazil, by means of bioassays and liquid chromatography.

MATERIALS AND METHODS

The assay was conducted in split plots, distributed in a completely randomized design with four replications. The plots consisted of columns filled with five soils collected at 0 20 cm depth in areas without a herbicide application history: Haplic cambisol - CX (Vale do Jaguaribe - Quixeré, CE); quartzarenic neosol - RQ (coastal region - Pedro Velho, RN), yellowish-red latosol (YRL) and yellowish-red acrisol - PVA (coastal plains - Maceió, AL), and haplic gleysol - GX (floodplain region - Maceió, AL), and the subplots, by 10 layers of depth in the columns, with 5 cm intervals (0-5, 5-10, 10-15, 15-20, 20-25, 25-30, 30-35, 35-40, 40 45 and 45-50 cm).

The soil samples were air dried, earth clods were undone and the samples were passed in 4 mm mesh sieves. From each soil sample was withdrawn a subsample for carrying out chemical and physical analyses (Tables 1 and 2), according to the methodology described by EMBRAPA (1997), and mineralogical analysis (Table 3), where the separation of the clay fraction of the soils studied was done according to EMBRAPA (1997), besides the identification of minerals, according to Chen (1977)CHEN, P.Y. Table of key lines in X-ray powder diffraction patterns of minerals in clays and associated rocks: Geological Survey Occasional Paper 21. Bloomington: Indiana Geological Survey Report, 1977. 67 p..

For soils quartzarenic neosol (RQ), yellowish-red latosol (YRL), yellowish-red acrisol (PVA), and haplic gleysol (GX) liming was performed by the base saturation method in order to adjust the pH, and they were incubated for a period of 30 days, when an analysis was done for reading the new corrected values of the respective index.

The soils were packed in PVC columns of 10 cm in diameter and 50 cm long, sectioned every 5 cm and with a removable side cover, according to the methodology used by Freitas et al. (2012), and subsequently paraffin was internally applied to prevent lateral flow. After filling with soil samples, these were saturated with water for a period of 48 hours and left in the vertical position, resting for 72 hours, in order to drain excess water.

Subsequently, sulfentrazone was applied on top of the columns at a dose of 1 kg ha^-1. Twelve hours after application, the columns still standing upright, a simulated rainfall was provided, with the application of a single 60 mm water depth for a period of three hours. After the precipitation simulation, the columns were maintained for 72 hours in a vertical position so as to allow water infiltration into the soil; subsequently, they were placed in a horizontal position, when side opening and sectioning every 5 cm with PVC foil were done.

In the center of each section of the columns, soil samples were collected, which were air dried, earth clods were undone and they were stored in a freezer at a temperature of approximately -10 ^oC for subsequent extraction and quantification of the herbicide by chromatographic analysis. After the collection of samples for extraction and determination of the herbicide by chromatography, sowing of five seeds of sorghum ( Sorghum bicolor ) per segment of the column was carried out in the sections of the columns, as an indicator plant of the sulfentrazone presence.

At 14 days after emergence (DAE) of the indicator species, there was the assessment of herbicide mobility by the indirect (biological) method, evaluating the toxicity index and the accumulation of plant dry matter. In assessing the toxicity index of indicator plants, scores were assigned from 0 (no toxicity) to 100 (plant death). In the evaluation of dry matter, all plants were cut in the soil surface and placed in an oven with forced air circulation (70 ± 2 ^oC) to constant weight.

For extraction of sulfentrazone soil samples, the technique of solid-liquid extraction was used, with partition at low temperature, as proposed by Vieira et al. (2007)VIEIRA, H. P. et al. Otimização e validação da técnica de extração líquidolíquido com partição em baixa temperatura (ELL-PBT) para piretróides em água e análise por CG. Quim. Nova, v. 30, n. 3, p. 535-540, 2007. and Goulart et al. (2008)GOULART, S. M. et al. Low-temperature clean-up method for the determination of pyrethroids in milk using gas chromatography with electron capture detection. Talanta, v. 75, n. 5, p. 1320-1323, 2008. .

The process consisted in measuring a mass of 2.00 g of dry soil, previously homogenized in screw cap glass flasks with 30.0 mL of capacity, then adding 12.0 mL of the extracting mixture consisting of 4.0 mL of water and 8.0 mL of acetonitrile. The bottles were subjected to vertical stirring for 30 minutes. Subsequently, the samples were left for ± 12 hours in a freezer at a temperature of approximately -20 ^oC. After this period, there was a common filtration of the unfrozen fraction, organic extract and herbicide, for volumetric flask of 10.0 mL. Fractions containing soil and frozen water were discarded. After reaching room temperature, the filtered solutions were transferred to a round bottom flask with 10.0 mL of capacity for evaporation of solvent in a rotary evaporator at a temperature of 50 ± 1 ^oC. After evaporation, the round bottom flask was washed with three aliquots of 0.50 mL of acetonitrile, and the final extract was filtered again in a membrane of 0.45 μm and stored in vials of 1.5 mL capacity for subsequent analysis by high-performance liquid chromatography (CLAE).

Sulfentrazone determination was performed using a liquid chromatography system of high efficiency, model Varian ProStar 325, with a UV-Vis detector and a stainless steel column (Varian Microsorb 100 -3 C18, 100 mm x 4.6 mm d.i.).

The chromatographic conditions for analysis consisted in a mobile phase of water and acetonitrile at a ratio of 50:50 (v/v), acidified with 0.01% of phosphoric acid; flow: 1.2 mL min^-1; injection volume: 20 µL; column temperature: 30 ^oC; and wavelength for reading: 214 nm.

The herbicide stock solution was prepared from the standard with 98.3% purity, at a concentration of 1,000 μg mL^-1 in acetonitrile, and the working solutions were prepared therefrom. Quantitation was performed by comparison of the areas obtained on the chromatograms, by the external calibration method.

To interpret the results, the data obtained in the bioassay and in the chromatographic analysis were submitted to analysis of variance and regression analysis. In the choice of the models, biological response, significance of the regression coefficients and coefficients of determination were taken into account.

RESULTS AND DISCUSSION

The increased mobility of sulfentrazone was found in RQ, being detected by the indicator plants up to a depth of 45 cm, indicating a high potential for herbicide leaching in this soil (Figure 1), which resulted in the reduction of herbicide concentration in the first 10 cm of the columns, evidenced by the lower toxicity index and higher dry matter accumulation in the indicator plants in relation to the depth of 15-35 cm, where symptoms were most evident.

The transport of the herbicide in the soil, with lower concentrations in the surface layers, compromises its effectiveness in controlling weeds, since almost all the weeds seeds that germinate are located near the soil surface, especially in the first 5 cm deep.

The high potential for leaching in this soil is due to the sandy texture and low organic matter content (Tables 1 and 2). According to Liu et al. (2010)LIU, Y. et al. Adsorption and desorption behavior of herbicide diuron on various Chinese cultivated soils. J. Hazard. Mater., v. 178, n. 1-3, p. 462-468, 2010., in soils with little organic matter and little clay, the percolation of herbicides can occur, making them available in the soil solution and making it amenable to transportation to the water table.

Rossi et al. (2003)ROSSI, C. V. S. et al. Mobilidade do sulfentrazone em Nitossolo Vermelho e em Neossolo Quartzarênico. Planta Daninha, v. 21, n. 1, p. 111-120, 2003., working with columns and using an unstructured quartzarenic neosol, have detected poisoning by sulfentrazone in the indicator plants at 22.5 cm and 30 cm deep, respectively, for water depths of 60 and 90 mm. Therefore, it is assumed in this work that if water depth higher than 60 mm were applied, herbicide mobility would have been even greater.

Herbicide mobility was also high on YRL, with symptoms of intoxication and reduced dry matter accumulation in the indicator plants observed to a depth of 35 cm (Figures 1 and 2C).

The intense herbicide leaching in this soil profile has to do with the composition of the clay fraction, predominantly kaolinite (Ct), and other minerals, such as gibbsite (Gb), goethite (Gt), and hematite (Hm) (Table 3). Iron oxides (hematite and goethite) and aluminum (mainly gibbsite) exhibit similar behavior to that of clay minerals 1:1, which have low CEC (cation-exchange capacity). According to Procópio et al. (2001), in tropical conditions where soils are highly weathered, there are predominantly oxides and hydroxides of iron and aluminum and silicate clays 1:1 of low reactivity (kaolinite); thus, organic matter is the primary contributor to these soils CEC. As shown in Table 1, the low organic matter content of this soil does not favor herbicide retention either.

In many cases, there is no correlation between the herbicide sorption and soil clay content (Grey et al., 1997GREY, T. L. et al. Sulfentrazone adsorption. and mobility as affected by soil and pH. Weed Sci., v. 45, p. 733-738, 1997.; Freitas et al., 2012, 2014; Melo et al., 2010MELO, C. A. D. et al. Lixiviação de sulfentrazone, isoxaflutole e oxyfluorfen no perfil de três solos. Planta Daninha, v. 28, n. 2, p. 385-392, 2010.). This is because the chemical characteristics of clays depend on the original soil material and its degree of weathering, which vary widely in tropical conditions (Lindsay, 2001LINDSAY, W.L. Chemical equilibria in soils. New Jersey: Blackburn, 2001. 449 p. ).

In YRL, CX and GX, sulfentrazone caused poisoning in the indicator plants up to 20 cm depth (Figure 1), although with more pronounced symptoms up to 15 cm, indicating a higher concentration of herbicide to this depth, which is enhanced by the reduction in dry matter accumulation, detected for their soils up to 15 cm (Figures 2A, B and E). Freitas et al. (2012) have also found higher efficiency in visual assessment of indicator plants intoxication in relation to the dry matter accumulation. Sulfentrazone lower mobility seems to be related to the higher content of organic matter for YRL and GX, and clay for CX, increasing herbicide sorption.

Freitas et al. (2012), working with ametryn in soils from different regions (including the Northeast Region of Brazil), have observed leaching of this herbicide up to 20 cm deep in a cambisol (Apodi, RN) and up to 25 cm in a latosolic dystrophic yellowish-red acrisol (Mossoró, RN), while in a yellowish-red latosol (Viçosa, MG) the movement of this herbicide was up to 5 cm deep. These authors claim that the increased mobility in the Northeast Region of Brazil soils was influenced by the physical and chemical characteristics of the soil, such as texture, clay content and organic matter, and can be enhanced in soils with high pH.

The liquid chromatography technique allows the quantification of herbicide content along the soil column, showing its displacement in different segments. Figure 3 shows the concentration of sulfentrazone in different soils in each segment of the column, which shows that the detection of sulfentrazone by means of the chromatographic method was slightly lower than the visual poisoning evaluation in the bioassay (Figures 1 and 2), presenting, however, the advantage of determining the herbicide concentration in the soil profile.

However, when the herbicide is distributed in the soil profile, slight variations can result in difficulty in adjusting models to explain the phenomenon, as shown in (Figure 3D), where it was not possible to adjust any model for the results of the chromatographic method in the quartzarenic neosol.

Chromatography requires sophisticated laboratories and highly skilled labor and consumes large amounts of solvents and other chemical products that can contaminate the environment, whereas the detection by the biological assay is a much simpler and cheaper process, which requires simpler structures, corroborating Melo et al. (2010) and Freitas et al. (2012), who claim that the bioassay joins cost efficiency to good practical results.

However, when the two methods are performed simultaneously, the results are much clearer, with the possibility to observe the biological effect of the herbicide residues and quantify the substance by means of chromatography.

Herbicide mobility in the soil profile can be beneficial to herbicides that exert their effect on seed or seedling during germination or emergence; however, in excess, it can lead to reduced effectiveness by percolation of the compound in the soil profile, besides the possibility of water table contamination.

Passos et al. (2015), working with sulfentrazone in soils collected in reforestation areas, have found that red acrisol with higher clay content, was the soil that retained in the first depths (0-15 cm) the highest concentration of the herbicide, whereas for haplic planosol, with the lowest content of clay and organic matter, the concentration of sulfentrazone found was almost homogeneous in all sections of the column. This result shows the great influence of clay and organic matter content in sulfentrazone mobility, in accordance with Grey et al. (1997) and Melo et al. (2010).

These results are in agreement with the ones by Freitas et al. (2014), who have found effects of physical and chemical characteristics of soils on sulfentrazone behavior. According to these authors, to recommend this herbicide in order to ensure technical efficiency and environmental sustainability, it is necessary to know the chemical and physical characteristics of the soils, as its sorption is greatly influenced by texture, organic matter content and pH of the soils.

It can be concluded that the greatest leaching rates were found in soils with high levels of sand, and there was sulfentrazone efficiency loss in the quartzarenic neosol because the symptoms of poisoning were highest between 15 and 35 cm deep. Sulfentrazone poisoning symptoms were found up to 45 cm in the quartzarenic neosol, 35 cm in the yellowish-red latosol, 20 cm in the yellowish-red acrisol, 20 cm in the haplic cambisol and 20 cm in the haplic gleysol.

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