Detection, fate and transport of the biohazardous agent Toxoplasma gondii in soil water systems: Influence of soil physicochemical properties, water chemistry and surfactant

A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) an...

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Published inEnvironmental microbiology reports Vol. 15; no. 6; pp. 597 - 613
Main Authors Kinsey, Erin N., Korte, Caroline, Gouasmia, Sohib, L'Ollivier, Coralie, Dubey, Jitender P., Dumètre, Aurélien, Darnault, Christophe J.G.
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.12.2023
Wiley
Subjects
Agricultural research
Biohazards
Classification
Cysts
Enumeration
Environmental Sciences
hydrochemistry
Leachates
Life Sciences
Loam soils
microbiology
Moisture content
Oocysts
Parasites
Physicochemical properties
Polymerase chain reaction
Potassium
Protozoa
quantitative polymerase chain reaction
rain
Rainfall
rainfall simulation
Sand transport
Sandy loam
sandy loam soils
Sandy soils
Simulated rainfall
Soil chemistry
Soil columns
Soil profiles
Soil properties
Soil water
Spatial distribution
Surfactants
Taxonomy
Toxoplasma gondii
Water chemistry
United States > US
Maryland
Illinois
South Carolina
Utah
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Abstract A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant—Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates. Laboratory set‐up for flow‐through experiments of soil columns under rainfall simulator in a biosafety cabinet; Photomicrograph of Toxoplasma gondii oocysts; Photos of soil column and soil column section; Breakthrough curves of oocysts in soils (oocysts (C/Co) vs. pore volume, where Co is the concentration of oocysts in the inoculums applied to the surface of the soil columns, and C refers to the concentration of oocysts in leachates of the soil columns); Distribution profiles of oocysts in soils (number of oocysts per gram of dry soil vs. depth of soil).
AbstractList A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant—Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates.
A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant—Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates. Laboratory set‐up for flow‐through experiments of soil columns under rainfall simulator in a biosafety cabinet; Photomicrograph of Toxoplasma gondii oocysts; Photos of soil column and soil column section; Breakthrough curves of oocysts in soils (oocysts (C/Co) vs. pore volume, where Co is the concentration of oocysts in the inoculums applied to the surface of the soil columns, and C refers to the concentration of oocysts in leachates of the soil columns); Distribution profiles of oocysts in soils (number of oocysts per gram of dry soil vs. depth of soil).
A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant—Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates.
A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant-Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates.A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical properties and soil water chemistry properties. Soil columns were homogeneously packed with loamy sand soils (Lewiston and Greenson series) and sandy loam soils (Sparta and Gilford series), and subject to hydrologic conditions characterized by the absence and presence of an anionic surfactant-Aerosol 22 in the artificial rainfall. Quantitative polymerase chain reaction (qPCR) was utilized for the detection and enumeration of oocysts in soil leachates to evaluate their breakthrough and in soil matrices to examine their spatial distribution. Differences in the rate and extent of transport of oocysts were observed as a function of physical and chemical parameters tested. The breakthrough of oocysts was observed for all the soils irrespective of the presence of surfactant. However, in the absence of surfactant, the predominant fate of oocysts in soils subject to simulated rainfall was their retention in the soil profile. The presence of surfactant induced a change in the fate of oocysts in these soils exposed to rainfall simulation as the predominant fate of oocysts was found to be in the soil leachates.
Author Dubey, Jitender P.
L'Ollivier, Coralie
Darnault, Christophe J.G.
Gouasmia, Sohib
Korte, Caroline
Kinsey, Erin N.
Dumètre, Aurélien
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  organization: Clemson University
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  doi: 10.1016/0038-0717(91)90092-X
– ident: e_1_2_10_48_1
  doi: 10.1128/AEM.00246-12
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Snippet A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical...
A series of laboratory experiments were conducted to study the fate and transport of Toxoplasma gondii oocysts in soils as a function of soil physicochemical...
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SubjectTerms Agricultural research
Biohazards
Classification
Cysts
Enumeration
Environmental Sciences
hydrochemistry
Leachates
Life Sciences
Loam soils
microbiology
Moisture content
Oocysts
Parasites
Physicochemical properties
Polymerase chain reaction
Potassium
Protozoa
quantitative polymerase chain reaction
rain
Rainfall
rainfall simulation
Sand transport
Sandy loam
sandy loam soils
Sandy soils
Simulated rainfall
Soil chemistry
Soil columns
Soil profiles
Soil properties
Soil water
Spatial distribution
Surfactants
Taxonomy
Toxoplasma gondii
Water chemistry
Title Detection, fate and transport of the biohazardous agent Toxoplasma gondii in soil water systems: Influence of soil physicochemical properties, water chemistry and surfactant
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2F1758-2229.13204
https://www.proquest.com/docview/3112453158
https://www.proquest.com/docview/2868118316
https://www.proquest.com/docview/3040371186
https://hal.science/hal-04253684
Volume 15
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