Your search keyword '"Martin Kočárek"' showing total 7 results

1. Ecological risk source distribution, uncertainty analysis, and application of geographically weighted regression cokriging for prediction of potentially toxic elements in agricultural soils

Author

Prince Chapman Agyeman, Kingsley JOHN, Ndiye Michael Kebonye, Solomon Ofori, Luboš Borůvka, Radim Vašát, and Martin Kočárek

Subjects

Environmental Engineering, General Chemical Engineering, Environmental Chemistry, Safety, Risk, Reliability and Quality

Published

2022

2. Dissipation of Twelve Organic Micropollutants in Three Different Soils: Effect of Soil Characteristics and Microbial Composition

Author

Sunil Paul Mathew Menacherry, Radka Kodešová, Ganna Fedorova, Alina Sadchenko, Martin Kočárek, Aleš Klement, Miroslav Fér, Antonín Nikodem, Alica Chroňáková, and Roman Grabic

Published

2023

3. Competitive and synergic sorption of carbamazepine, citalopram, clindamycin, fexofenadine, irbesartan and sulfamethoxazole in seven soils

Author

Aleš Klement, Miroslav Fér, Antonín Nikodem, Roman Grabic, Helena Švecová, Martin Kočárek, Zuzana Schmidtová, Radka Kodešová, and Kateřina Grabicová

Subjects

Sulfamethoxazole, 0207 environmental engineering, 02 engineering and technology, Citalopram, 010501 environmental sciences, complex mixtures, 01 natural sciences, Soil, Hydrolysis, Soil Pollutants, Environmental Chemistry, Molecule, Freundlich equation, 020701 environmental engineering, 0105 earth and related environmental sciences, Water Science and Technology, Chemistry, Clindamycin, Cationic polymerization, Sorption, Soil classification, Irbesartan, Carbamazepine, Soil water, Adsorption, Terfenadine, Saturation (chemistry), Nuclear chemistry

Abstract

Sorption of pharmaceuticals, which can occur in soils, may differ when present in a soil solution as a single compound or in a solution with other pharmaceuticals. Therefore, the sorption isotherms described by the Freundlich equations were evaluated for 6 compounds, which were applied in solutions of a single pharmaceutical, two pharmaceuticals or all pharmaceuticals to seven soils. Study mainly focused on a behavior of fexofenadine and irbesartan that occurred in soils in 3 forms (cationic, zwitter-ionic or neutral, anionic). Sorption of both compounds slightly increased (in some soils) when applied together, largely increased when applied with carbamazepine (neutral), and extremely increased when applied in solutions with citalopram (strongly sorbed cation), which could be explained by a cooperative multilayer sorption on soil constituents. On the other hand, sorption of both compounds moderately decreased when applied with clindamycin (cation and neutral) or sulfamethoxazole (neutral or anion). The magnitude of an increase or decrease in the Freundlich sorption coefficient (KF) for a particular compound depended on soil conditions, a form of compound's molecule and its interaction with molecules of other compounds. Despite sorption being influenced by other compound(s) in solution, the KF coefficients evaluated for a particular compound under the different conditions were mostly correlated with the same soil properties: KF,CAR with an organic carbon content, KF,CIT and KF,CLI with a base cation saturation, KF,SUL with hydrolytic acidity, and KF,FEX and KF,IRB with sorption complex saturation.

Published

2020

4. Pharmaceuticals' sorptions relative to properties of thirteen different soils

Author

Ondřej Jakšík, Roman Grabic, Antonín Nikodem, Oksana Golovko, Miroslav Fér, Martin Kočárek, Aleš Klement, and Radka Kodešová

Subjects

Environmental Engineering, Chemistry, Inorganic chemistry, Sorption, complex mixtures, Pollution, Soil, Absorption, Physicochemical, Models, Chemical, Pharmaceutical Preparations, Pedotransfer function, Soil pH, Environmental chemistry, Soil water, Cation-exchange capacity, Soil Pollutants, Environmental Chemistry, Freundlich equation, Saturation (chemistry), Waste Management and Disposal

Abstract

Transport of human and veterinary pharmaceuticals in soils and consequent ground-water contamination are influenced by many factors, including compound sorption on soil particles. Here we evaluate the sorption isotherms for 7 pharmaceuticals on 13 soils, described by Freundlich equations, and assess the impact of soil properties on various pharmaceuticals' sorption on soils. Sorption of ionizable pharmaceuticals was, in many cases, highly affected by soil pH. The sorption coefficient of sulfamethoxazole was negatively correlated to soil pH, and thus positively related to hydrolytic acidity and exchangeable acidity. Sorption coefficients for clindamycin and clarithromycin were positively related to soil pH and thus negatively related to hydrolytic acidity and exchangeable acidity, and positively related to base cation saturation. The sorption coefficients for the remaining pharmaceuticals (trimethoprim, metoprolol, atenolol, and carbamazepine) were also positively correlated with the base cation saturation and cation exchange capacity. Positive correlations between sorption coefficients and clay content were found for clindamycin, clarithromycin, atenolol, and metoprolol. Positive correlations between sorption coefficients and organic carbon content were obtained for trimethoprim and carbamazepine. Pedotransfer rules for predicting sorption coefficients of various pharmaceuticals included hydrolytic acidity (sulfamethoxazole), organic carbon content (trimethoprimand carbamazepine), base cation saturation (atenolol and metoprolol), exchangeable acidity and clay content (clindamycin), and soil active pH and clay content (clarithromycin). Pedotransfer rules, predicting the Freundlich sorption coefficients, could be applied for prediction of pharmaceutical mobility in soils with similar soil properties. Predicted sorption coefficients together with pharmaceutical half-lives and other imputes (e.g., soil-hydraulic, geological, hydro-geological, climatic) may be used for assessing potential ground-water contamination.

Published

2015

5. Soil influences on uptake and transfer of pharmaceuticals from sewage sludge amended soils to spinach

Author

Antonín Nikodem, Aleš Klement, Miroslav Fér, Radka Kodešová, Martin Kočárek, Roman Grabic, and Oksana Golovko

Subjects

Cambisol, Environmental Engineering, Sewage, Chemistry, 0208 environmental biotechnology, Amendment, 02 engineering and technology, General Medicine, Wastewater, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, 020801 environmental engineering, Soil, Spinacia oleracea, Environmental chemistry, Bioaccumulation, Cation-exchange capacity, Soil Pollutants, Phaeozem, Sewage treatment, Waste Management and Disposal, Chernozem, Sludge, 0105 earth and related environmental sciences

Abstract

Sewage sludge from wastewater treatment plants, which may contain various contaminants including pharmaceuticals, is often used as a soil amendment. These contaminants may subsequently be taken up by plants. In the present study we examined uptake of select pharmaceuticals from sewage sludge applied to soils by spinach plants. Seven soils were amended with sewage sludge from two wastewater treatment plants (A and B). Concentrations of compounds in plant tissues (roots and leaves) of spinach planted 45 days in these soils under greenhouse conditions were evaluated after harvest. The largest bioaccumulation in the roots and leaves was observed for sertraline (bioaccumulation factors (BAF) of 3.3-37.9 and 1-13.4, respectively), tramadol (1.3-10.0 and 4.8-30.0), and carbamazepine (2.2-17.2 and 6.1-48.8) and its metabolite carbamazepine 10,11-epoxide (not-quantified to 7.3 and 9.3-96.7). Elevated bioaccumulation in spinach roots was also identified for telmisartan (3.0-20.3) and miconazole (4.3-15.1), and leaves for metoprolol acid (not-quantified to 24.3). BAF values resulting from application of sludge B were similar to or moderately higher than BAFs from sludge A. The BAF values of carbamazepine and carbamazepine 10,11-epoxide in all tissues were negatively correlated with soil cation exchange capacity (CEC). This negative correlation between BAF and CEC was also observed for tramadol (A-roots and B-leaves), citalopram (B-roots), and telmisartan (B-roots) or between BAF and clay content for metoprolol acid (A-leaves and B-roots), tramadol (B-roots and A-leaves) and venlafaxine (B-roots). However, in the case of some other compounds (i.e. sertraline, amitriptyline, mirtazapine, metoprolol), uptake and the subsequent translocation and transformation from 3 soils of a higher pH and base cation saturation (Stagnic Chernozem Siltic, Haplic Chernozem and Greyic Phaeozem) significantly differed from 4 soils with a lower pH and base cation saturation (Haplic Luvisol, Haplic Cambisol, Dystric Cambisol and Arenosol Epieutric). Such observations proved strong compound dependent influences of soil conditions on various compounds bioaccumulations in plants and necessity of studying these processes always in diverse soils.

Published

2019

6. Chlorotoluron mobility in compost amended soil

Author

Ondřej Drábek, Vit Kodes, Martin Kočárek, Martina Hýbler, Tereza Hajková, and Radka Kodešová

Subjects

Total organic carbon, Soil test, Chemistry, Compost, Amendment, Soil Science, Soil science, engineering.material, Distilled water, Environmental chemistry, Soil water, engineering, Soil horizon, Agronomy and Crop Science, Chernozem, Earth-Surface Processes

Abstract

Knowledge about the impact that various organic amendments have on the behavior of pesticides in soils is essential when assessing groundwater contamination risk. The aim of this study was to evaluate the impact of a compost amendment on chlorotoluron mobility in the A horizon of the Luvic Chernozem. Soil was mixed with compost material and placed into plastic cylinders. Eight mixtures (A, B, C, D, E, F, G and H) of various compost fractions (from 1 to 8% of mixture weight) were prepared. Chlorotoluron solution was applied on the top of the soil samples and a rainfall simulator was used to apply distilled water on the soil surfaces with controlled infiltration rates. Measured pressure heads at 3 positions, water outflow from the bottom, and final chlorotoluron concentrations within the soil samples were used to optimize soil hydraulic and herbicide transport parameters via numerical optimization using the HYDRUS-1D code. Optimized soil hydraulic parameters did not show noticeable changes (demonstrating an improvement of soil hydro-physical properties) with increasing compost fraction. Final chlorotoluron distribution in soil columns and estimated transport parameters also showed high variability. However, results indicated that while chlorotoluron mobility decreased up to a compost fraction of 6%, herbicide mobility noticeably increased in G (7%) samples and slightly increased in H (8%) samples. These finding corresponded to herbicide adsorption studied using a batch experiment. Multiple linear regressions revealed that other properties (not only organic carbon content) play a noticeable role in pesticide adsorption in soils. A negative impact of pH KCl (which was positively affected by compost addition), clay content, and CaCO 3 content (which were mostly properties of soil, but could be affected by compost composition as well) was documented.

Published

2012

7. Impact of varying soil structure on transport processes in different diagnostic horizons of three soil types

Author

J. Kozák, Marcela Rohošková, M. Pagliai, Jirka Šimůnek, Tereza Hajková, Nadia Vignozzi, Martin Kočárek, and Radka Kodešová

Subjects

Cambisol, Macropore, Soil test, Soil morphology, Soil classification, Soil science, complex mixtures, Soil, Infiltration (hydrology), Soil structure, Pedotransfer function, Pressure, Water Movements, Environmental Chemistry, Porosity, Filtration, Geology, Water Science and Technology

Abstract

When soil structure varies in different soil types and the horizons of these soil types, it has a significant impact on water flow and contaminant transport in soils. This paper focuses on the effect of soil structure variations on the transport of pesticides in the soil above the water table. Transport of a pesticide (chlorotoluron) initially applied on soil columns taken from various horizons of three different soil types (Haplic Luvisol, Greyic Phaeozem and Haplic Cambisol) was studied using two scenarios of ponding infiltration. The highest infiltration rate and pesticide mobility were observed for the Bt(1) horizon of Haplic Luvisol that exhibited a well-developed prismatic structure. The lowest infiltration rate was measured for the Bw horizon of Haplic Cambisol, which had a poorly developed soil structure and a low fraction of large capillary pores and gravitational pores. Water infiltration rates were reduced during the experiments by a soil structure breakdown, swelling of clay and/or air entrapped in soil samples. The largest soil structure breakdown and infiltration decrease was observed for the Ap horizon of Haplic Luvisol due to the low aggregate stability of the initially well-aggregated soil. Single-porosity and dual-permeability (with matrix and macropore domains) flow models in HYDRUS-1D were used to estimate soil hydraulic parameters via numerical inversion using data from the first infiltration experiment. A fraction of the macropore domain in the dual-permeability model was estimated using the micro-morphological images. Final soil hydraulic parameters determined using the single-porosity and dual-permeability models were subsequently used to optimize solute transport parameters. To improve numerical inversion results, the two-site sorption model was also applied. Although structural changes observed during the experiment affected water flow and solute transport, the dual-permeability model together with the two-site sorption model proved to be able to approximate experimental data.

Published

2009