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Article

Enterobacteria Survival, Percolation, and Leaching on Soil Fertilized with Swine Manure

Universidade do Contestado, Rua Victor Sopelsa, 3000, Concórdia 89711-330, SC, Brazil
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2023, 20(7), 5283; https://doi.org/10.3390/ijerph20075283
Submission received: 24 February 2023 / Revised: 13 March 2023 / Accepted: 14 March 2023 / Published: 28 March 2023

Abstract

:
Swine manure has a high load of pathogens, which can pose a risk to human and environmental health. In Brazil, studies evaluating the survival of pathogens in soil are scarce. Therefore, this study aimed to evaluate the survival, percolation, and leaching of enterobacteria in clayey soil after fertilization with swine manure. For this purpose, soil columns were fertilized with manure spiked with enterobacteria. The microorganisms’ behavior was monitored in terms of survival, percolation, and leaching with and without rain. Soil samples were collected, and Escherichia coli and Salmonella enterica serovar Senftemberg were quantified. The results indicated that E. coli survived for a longer period (43 days) than S. senftemberg (14 days). E. coli percolated quickly through the soil, leaching 60 cm in less than 5 min during rainy events and remaining viable for up to 24 h after the rain. The results show the importance of treating manure effectively before being added to the soil. An efficient treatment could be anaerobic digestion, followed by a pond system. Considering the characteristics of swine-producing regions, the load of effluents applied to the soil may percolate, leach, or run off and consequently contaminate water bodies with pathogens.

1. Introduction

Swine manure is a mixture of urine, feces, food residues, and water used in cleaning activities and contains a high load of microorganisms [1]. The manure microbial composition can vary depending on factors such as age, the type of animal, feed, manure dilution, and the storage technique [2], with a large bacterial population of saprophytic microorganisms, pathogenic bacteria, viruses, and fungi, as well as gastrointestinal parasite eggs and oocysts [3].
Of manure pathogens, special attention has been given to the enterobacteria group, as they have been pointed out as responsible for more than 2.2 million annual deaths caused by gastrointestinal problems [4]. Among enterobacteria, E. coli has been used as a fecal indicator for decades, but it can also be a pathogen due to its different strains, such as Enteroinvasive E. coli (EIEC), Enterotoxigenic E. coli (ETEC), Enteropathogenic E. coli (EPEC), Enterohemorrhagic E. coli (EHEC), Uropathogenic E. coli (UPEC), and Enteroaggregative E. coli (EaggEC) [5]. All around the world, diarrhea caused by pathogenic E. coli is responsible for 550 million diseases and 230,000 deaths each year [6]. Furthermore, prolonged oral exposure to these fecal contaminants has been linked to environmental enteropathy, a subclinical condition defined by chronic bowel inflammation that can contribute to structural changes in the small intestine and immune dysfunction in the patient [7]. Although the majority of E. coli types are innocuous, some variations are harmful to health and thus raise the risk of waterborne pathogens, such as Salmonella spp.
Salmonella spp. are rod-shaped, Gram-negative bacteria, with over 2500 serovars, that colonize the intestinal tract of animals and humans [8]. This bacteria has been reported by the World Health Organization (WHO) to be one of the antibiotic-resistant priority pathogens, requiring urgent strategies for infection management, including the reduction in this bacteria in environmental matrices [9].
Spreading manure on soil as a fertilizer is of special concern since it has been associated with environmental and public health issues due to the presence of zoonotic microorganisms, which can contaminate water [10] and may become associated with vegetable roots and be internalized [11]. For a long time, scientists considered that soil could act as a filter with the potential for self-purification, naturally reducing the pathogen load. However, studies have reported the migration of pathogens in soil, both vertically and horizontally, over a distance as far as 830 m [12]. This migration ability increases the possibility of water contamination [12].
Because of complex interactions among microorganisms and soil constituents, such as organic matter, and porosity, microbial transport across soils can differ [13]. Consequently, certain soil types are more susceptible to microbial migration [9,10]. In a study by Mantha et al. [13], Salmonella enterica leached more successfully through sandy soils than through organic soils. Furthermore, higher bacterial survival in organic soils and a rapid decrease in Escherichia coli (E. coli) concentrations in more nutrient-poor soil conditions have been reported [14,15,16,17,18]. When compared to sandy soils, which present non-cohesive particles and low organic matter retention, clayey soils offer greater water and nutrient retention capacities, ensuring bacterial survival [19,20]. Certain studies have shown this effect. For example, a study comparing E. coli O157:H7 survival after cattle slurry was applied to clayey and sandy soils found that survival in clayey soils could last up to 16 weeks compared to 8 weeks in sandy soil [21].
To facilitate the assimilation of manure or other liquid wastes into the soil matrix, agricultural soil is frequently tilled. Due to this practice, the size distribution of macropores changes, and the bulk density of the soil is temporarily reduced [22,23]. As a result, the soil has a considerable impact on the dynamics of pathogen transfer to groundwater sources. This necessitates a thorough understanding of pathogen movement and survival as they traverse the soil profile [24].
Currently, Brazil is the fourth-largest swine producer in the world, and the generated manure has been applied to soil as a fertilizer for many decades because it contains nutrients beneficial to plants and improves the soil structure [25]. The estimated volume of manure to be considered is determined from the daily volume excreted by the animal (8.6 L) for a herd of 38,212,374 animals [26,27]. However, in these regions, studies evaluating the survival of enterobacteria in soil are scarce. Therefore, we aimed to evaluate the survival, percolation, and leaching of enterobacteria in clayey soil after fertilization with swine manure. We spiked swine manure with Salmonella enterica Senftenberg (S. senftenberg) and E. coli and applied it to clayey soil. We then evaluated the survival, percolation, and leaching of the added enterobacteria.

2. Materials and Methods

2.1. Soil and Swine Manure Characterization

The soil and swine manure were sampled in the western region of Santa Catarina, Brazil. For the characterization, each sample of soil was dried in an oven (100 °C). The soil was then disaggregated with a mortar and pestle. All processes were carried out according to NBR 6457 [28]. The soil samples were classified by particle size using NBR 7181 [29], Atterberg’s limits (liquid limit—LL; plastic limit—PL) using NBR 7180 [30] and NBR 6459 [31], and the weight-specific grain value using ME 093 [32] (Table 1).
The total solid content was quantified using a gravimetric assay [33]. Total organic carbon was quantified using a TOC analyzer (Multi C/N 2100, Analytik Jena, Jena, Germany), at a flow rate of 160 mL min−1, using oxygen as a carrier. The temperature was set at 900 °C. Briefly, the samples were filtered through 0.45 µm membrane filters (Millipore, Burlington, MA, USA), acidified with phosphoric acid (40% w w −1) (Sigma-Aldrich, EUA, St. Louis, MI, USA), and injected (250 µL) immediately into the analyzer. Calibration curves were generated by serial dilution of a stock solution of 1 g L−1 biphthalate (Synth, São Paulo, Brazil).
Biological oxygen demand (BOD5) was determined in accordance with 5210-B, Standard Methods for the Examination of Water and Wastewater [33]. Alkalinity was determined by titration using sulfuric acid (0.1 M, Merck, Darmstadt, Germany) as a titrant. Alkalinity was determined as CaCO3 L−1: [(M × A × 10,000)/V]; where M is molarity of standardized acid (M); A is the acid volume dispensed to reduce sample pH to 4.5 (mL) and V is total sample volume (mL) [33].
The ascorbic acid colorimetric method was used to measure the concentration of phosphate-P (4500-P, Standard Procedures for the Analysis of Water and Wastewater [33]). The reagent solution was prepared using 50 mL of sulfuric acid (5 N) (Sigma-Aldrich, St. Louis, MI, USA), 5 mL of antimony potassium tartrate solution (Sigma-Aldrich, St. Louis, MI, USA), 15 mL of ammonium molybdate solution (Synth, São Paulo, Brazil), and 30 mL of ascorbic acid solution (Synth, São Paulo, Brazil). Subsequently, 0.8 mL of this solution was added to 5 mL of the previously filtered samples (0.45 μm membrane filter, Millipore, USA). After 10 min, the absorbance of each sample was measured in a UV-Visible spectrophotometer (Pharo 300, Merck) at 880 nm. The standard curves were generated by serially diluting a stock phosphate-P solution (0.05–0.2 mg-P L−1) (Merck, Darmstadt, Germany).
Potentiometric analysis using a selective electrode method was used to measure ammoniacal NH3-N (4500-NH3 D, Standard Procedures for the Analysis of Water and Wastewater [33]). The reagent solution was prepared NaOH/EDTA (10 N) (Neon, Sao Paulo, Brazil) and sodium hydroxide (10 N) (Neon, Sao Paulo, Brazil). The standard curves were generated by serially diluting a stock NH3-N solution (0.1–1000 mg-NH3-N L−1) (Merck, Darmstadt, Germany). The concentrations of nitrite-N and nitrate-N were determined by the N-(1-naphthyl)-ethylenediamine dihydrochloride colorimetric method and were measured at a wavelength of 550 nm (4500-NO2-B and 4500-NO3-F, Standard Procedures for the Analysis of Water and Wastewater [33]). Calibration curves were prepared by serial dilution of nitrite-N (0.1–2.0 mg-N L−1, Merck, Darmstadt, Germany) and nitrate-N (0.1–3.0 mg-N L−1, Merck, Darmstadt, Germany). pH was determined using a pHmeter (pH–mV, Hanna Instruments, Inc., Woonsocket, RI, USA). The data are shown in Table 2.

2.2. Preparation of the Bacterial Inoculum

For the preparation of the inoculum spiked in swine manure, standard strains of E. coli and S. enterica serovar Senftemberg were spread on nutrient agar (Kasvi®) and incubated at 37 °C for 24 h. Following this, batches of bacterial colonies were gradually added to 10 mL of a 0.9% saline solution until they reached turbidity comparable to the 0.5 McFarland standard (Remel®), which contains 1.5 × 108 bacteria per mL. This suspension was combined with swine manure and immediately applied to the soil. The volume of swine manure used in this study was comparable to that applied to corn, wheat, and soybean crops (50 m3 ha−1) [34].

2.3. Microbial Survival Assay

The sampled soil was deposited in 1 L reactors that were artificially contaminated with bacterial suspensions containing E. coli and S. senftemberg at concentrations comparable to the 0.5 McFarland standard (Remel®). Samples were collected at time zero (T0), daily, and every 5 days until all bacteria died. For E. coli quantification, samples were serially diluted at base 10, then placed at different depths in Chromocult® Agar [35], and incubated at 37 °C for 24 h, and the count of typical colonies was determined according to the manufacturer’s instructions. To quantify S. senftemberg, the samples were serially diluted to base 10 in saline solution and placed on XLD Agar [36] for 24 h incubation at 37 °C, followed by standard colony counting according to the manufacturer’s instructions. The results are represented as colony-forming units (CFU).

2.4. Microbial Percolation Assay

Three soil column reactors, 70 cm high and 30 cm in diameter, fabricated in polyvinyl chloride tubes (PVC tubes) were used in the experiment. On the side, 1 cm diameter access slots were made at depths of 10, 20, 40, and 60 cm, to allow the soil sample collection during the experiment.
The soils were rearranged in the columns in the same order in which they were removed from the original place on the farm (up to 60 cm deep). The columns were left alone for a week to allow the soil to stabilize [34]. Then, soils were fertilized with swine manure artificially contaminated with known concentrations of model bacteria. To monitor the percolation of microorganisms in the soil, 1 g soil samples were collected at different depths [34]. Samples were collected regularly until all bacteria died.

2.5. Microbial Leaching after Rain

To carry out the leaching experiments, after fertilization, the soil columns were exposed to a precipitation of 53 mm (at an environmental temperature of 20 °C). This experiment was conducted on a rainy day, representing the real conditions that occurring in the field. The rain volume was measured to calculate the precipitation. A tap was installed at the bottom to allow the leaching liquid to be collected. The leaching liquid from the soil was collected using a sterile collector tube, at times 2, 4, 8, 12, 24, 36, and 48 h after the rain and the enteric bacteria quantified [34].

2.6. Inactivation Kinetics

The inactivation coefficient and the time required for a 1 Log10 reduction of model bacteria (T90 = 1/−k) were calculated according to Ottoson et al. [37], considering the linear regression curve with r2 ≥ 0.75.

2.7. Statistical Analysis

T-test was used to evaluate the changes in enteric bacteria behavioral profiles in soil over time. One-way analysis of variance (ANOVA) was used to evaluate differences between the depths, using a 95% confidence level, followed by Bonferroni’s multiple comparison test (GraphPad Prism 5.0). The critical p-value for the test was set at ≤0.05.

3. Results and Discussion

3.1. Enterobacteriaceae Decay Profile in Soil

The survival of pathogenic enterobacteria in clayey soil fertilized with swine manure spiked with E. coli and S. senftemberg is depicted in Figure 1. After 7 days, the E. coli concentration decreased by 90% (1 log10) and remained stable for 25 days; a significant decrease in E. coli concentration was observed after 43 days (p < 0.05). A different response was found for S. senftemberg (Figure 1B), where it required 9 days to reduce the concentration by 90% (1 log10). Additionally, 13 days were required for the elimination of S. senftemberg (104 CFU). It is worth noting that untreated swine manure can present an E. coli concentration of 107 MPN 100 mL−1 [38], so even after a 90% reduction, the bacteria load in manure remains high and is able to contaminate soil, where it can be active for more than 30 days. According to the World Health Organization, the recommendation for water reuse is an E. coli concentration lower than 103 MPN mL−1 for the fertigation of cultures not directly consumed [39]. Previous studies conducted by our group showed that swine manure treatment consisting of anaerobic digestion followed by a pond system is suitable to remove pathogenic bacteria, leading to concentrations below 103 CFU [40]. However, a low concentration of E. coli does not guarantee the absence of other pathogens, such as viral particles, which have environmental survival times greater than two months [41].
Pathogen survival in environmental matrices is affected by factors such as climatic conditions, temperature, pH, agrochemicals, aeration, soil type, and the presence of other microorganisms (due to predation or competition) [42,43]. Additionally, survival can be influenced by plants cultivated in the soil; Maule [44] reported that the greatest survival of bacteria occurs in soil containing rooted grass.
Similar results were observed after applying livestock manure to soil, where E. coli O157:H7 and Salmonella persisted in the soil for up to one month after its application to both sandy and clayey grassland soils [45]. Studies on the soil application of swine manure revealed that after the 20th day, the quantity of bacteria decreased very slowly, independent of the amount of sludge used, such that after 80 days, an estimated concentration of 103 CFU dry matter−1 remained in the soil [46]. The estimated average time required to obtain undetectable E. coli concentrations in sandy soil ranged from 56 to 70 days [47].
E. coli O157:H7 continued to survive after 60 days in Brown soil sand and silts, with a decrease of 0.7 to 2.5 log10 CFU g−1. During the same period, the E. coli O157:H7 concentration in Brown soil clay containing natural organic matter increased by 0.58 log10 CFU g−1 compared to the original inoculation (from 6.68 to 7.26 log10 CFU g−1) [48]. On the other hand, the concentration of E. coli O157:H7 in Brown clay without natural organic matter had been reduced to undetectable levels by day 24 [48]. The clay concentration in soil has been recognized to have a significant impact on enterobacteria survival in soil, typically improving survival. Some of the most common clay minerals found in soils include kaolinite, montmorillonite, and illite [20]. Brennan et al. [20] studied the effect of clay mineral type on bacterial enterobacteria survival in soil. As a result, after 96 days of experimentation, the reduction in E. coli O157:H7 in the soil was 106 CFU g, whereas, with the addition of kaolinite, montmorillonite, and illite, the reduction was 104, 103, and 102 CFU g, respectively.
Clay minerals constitute the most active inorganic colloid components in soils, influencing bacterial adhesion, metabolism, colonization, and biofilm formation [49,50]. Clays with the highest surface areas and specific surface electrical characteristics were more efficient than silts and sands in attaching E. coli O157:H7 [48]. The attachment of bacteria, the first step in biofilm formation, stimulates the organism to produce extracellular polymeric substances such as polysaccharides, proteins, lipids, and nucleic acids, which form a protective matrix around the bacterial surface and protect cells from adverse environmental conditions [51]. In this respect, higher adhesion led to gradually longer E. coli O157:H7 survival in clay soil [48]. Surface-attached bacteria may have a different physiological or metabolic state in terms of gene transcription for growth and metabolism, which increases the chances of microbial species establishing and persisting in difficult environments [52].

3.2. Decay Kinetics of Enterobacteriaceae in Soil

Pathogens discharged with manure particles are exposed to various processes and routes that decide their die-off or growth, as well as their final deposition or fate [53]. Nevertheless, to contaminate water resources and possibly infect humans or animals, a pathogen must be able to survive after fertilization and endure the processes it may face at the soil surface, during transit through the soil, or after entrainment in the overland flow [54,55]. According to the findings in this study, S. senftenberg had a greater inactivation rate (0.096 d−1) compared to E. coli (0.1029 d−1) (Table 3). Additionally, for E. coli, a 90% reduction takes 9.71 days. S. senftemberg requires 10.4 days to be 90% inactivated (1 log10). Similar T90 values were obtained in sandy soils after swine digestate application for S. enterica Typhimurium (11.9 d) and E. coli O157:H7 (10.75 d) [34]. The inactivation coefficient (k) can be influenced by enterobacteria-specific and clayey mineral properties, as shown by Brennan et al. [20]. In this regard, E. coli O157:H7 exhibited k values of 0.30, 0.23, 0.15, and 0.06 in clayey soil (without mineral addition), a soil kaolinite mix, a soil illite mix, and a soil montmorillonite mix, respectively, whereas Salmonella Dublin exhibited k values of 0.30, 0.18, 0.20, and 0.05 in the clayey soil (without mineral addition), soil kaolinite mix, soil illite mix, and soil montmorillonite mix, respectively [20].

3.3. Percolation of Enterobacteriaceae in Soil

As shown in Figure 2A, E. coli was found up to a depth of 60 cm 48 h after swine manure application, most likely due to fertilizer drag. There was a significant reduction (p < 0.05) in the first five days at soil depths of 10 cm and 20 cm. E. coli strains remained viable in the soil column, similar to the survival results depicted in Figure 1A. S. senftemberg (Figure 2B) did not penetrate the deepest soil layers, reaching only a depth of 20 cm. There was a significant decrease in the S. senftemberg concentration in the layers of soil (10 and 20 cm) in the first 48 h and a reduction to zero by the 16th day after swine manure application (p < 0.05).
The movement of microorganisms in soil is influenced by intrinsic microbial features such as size, shape, cell surface characteristics, and biochemical and enzymatic properties [56]. In this sense, the differences observed between the bacteria used in this study could be explained by the cell size, where Salmonella enterica is a rod-shaped bacteria ranging from 2.2 to 5.0 μm [57], while E. coli cells are smaller at 1–2 μm [47,58], with smaller cells percolating longer.
The number and size of microbial cells impact the settling velocity of manure. Microorganisms have a low density in general; hence, they are likely to remain suspended once entrained [54]. Suspended bacteria present in swine manure can travel quickly across the profiles of well-structured soils at moderate to high rates of water content through macropores and worm-holes. Any field soil that has macropores and receives enough water to fill these holes is likely to facilitate the fast transport of suspended bacteria to the depth at which these macropores are continuous [59]. A sandy soil with wider pores will allow for easier passage through the soil matrix than a clayey soil with fewer pore spaces [60]. Chemotactic migration permits motile bacteria to move more efficiently in response to environmental conditions (favorable or otherwise). They may also be capable of swimming toward soil pores and surface irregularities that would otherwise be inaccessible [60]; hence, their transport capability is increased. Others can use flagellar motion to move toward helpful substances such as nutrients, which promotes more mobility across the environmental medium [12].
Members of the Pseudomonas, Achromobacter, Bacillus, Flavobacterium, and Enterobacter genera have exhibited different transport potentials [61]. Sepehrnia et al. [17] reported that E. coli cells are expected to be more influenced by hydrodynamic forces compared to smaller-sized bacteria [17,62]. The adhesion of Salmonella to soil has been shown to be correlated with cell surface hydrophobicity [63]. Huysman and Verstraete [64] found that hydrophobic strains were 2–3 times slower to percolate through soil columns, as observed with the Salmonella in the present study.

3.4. Leaching of E. coli in Soil

Rain can promote the survival of pathogenic bacteria by keeping the soil wet, and it can also move bacteria through the soil to more or less suitable areas, as well as potentially contaminate groundwater [65]. Figure 3 shows the behavior of E. coli in clayey soil fertilized with swine manure exposed to rain. The samples obtained in this phase of the study were not from soil, but from the liquid fraction (leachate) that exceeded 60 cm of the soil column, simulating rains on swine-manure-fertilized soil. As a result, after 5 min of rain, approximately 103 CFU reached a depth of 60 cm, and after 48 h, all water had percolated and the total bacteria concentration was reduced. This result indicates that the bacteria leaching in the first 24 h and the water eliminated in the last 24 h correspond to the water retained in the soil particles.
Furthermore, the use of liquid manure is predicted to improve microbial release and transport efficiency [66]. Manure compounds in liquid-based materials are more quickly recoverable and more influenced by the impact of precipitation or the flow of water than solid-manure compounds, which are more aggregated (adhered to material surfaces) [67,68]. Thus, since bacteria have greater mobility in the liquid phase than in the solid phase, liquid manure tends to be more uniformly polluted than solid manure [69].
Other studies reported the depth-dependent survival of E. coli and enterococci in soil following manure application and simulated rainfall of 30, 60, and 90 mm. In the first few days, E. coli concentrations increased and then gradually decreased to the initial amount; however, enterococci populations decreased at the beginning and were inactivated after 4 weeks, except when 30 mm of rain was applied: in this condition, the survival was longer than the 21 days of the experiment [70]. The bacterial activity decreases by one or two orders of magnitude for every 2 m of depth [71].
All of these findings highlight the diverse behavior of microorganisms in soil, depending on the soil type, microbial strains, manure load, and environmental conditions such as rain volume. During the application of manure without rain, there is a long survival period, but not with a long spread; in rainy periods, vertical leaching occurs faster. In this context, farmers should be encouraged to use environmentally friendly agriculture and manure management practices. Given the diversity of agricultural conditions, such farm and manure management solutions should be adaptable and pragmatic in design. A comprehensive combination of tactics that considers geographical, environmental, sociocultural, and economic differences would be suitable. Farmers’ knowledge and understanding must be improved, particularly in rural regions. It is critical to emphasize the need to use effective manure treatments and avoid applying new/raw manure [72].

4. Conclusions

This work evaluates the behavior (survival and percolation) of E. coli and S. senftemberg in clayey soils fertilized with swine manure. The results indicate that E. coli survives for a longer period (43 days) than S. senftemberg (14 days); E. coli percolates quickly through the soil. During a rainy event (53 mm), E. coli percolated 60 cm in less than 5 min, and it was possible to find viable bacteria up to 24 h after the rain. The results show the importance of reducing enteric pathogens in animal manures before their field application, which is critical for lowering the risk of produce-related foodborne diseases. Considering the characteristics of swine-producing regions, the load of effluents applied to the soil may exceed the self-purification capacity of the environment, and percolation or surface runoff may occur, with the consequent contamination of water bodies by pathogens.

Author Contributions

Conceptualization, A.V. and W.M.; methodology, N.R.W.P.; formal analysis, N.R.W.P. and T.M.S.; investigation, D.C.S. and T.M.S.; writing—original draft preparation, A.V., W.M. and T.M.S.; writing—review and editing, A.V., W.M. and T.M.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors gratefully acknowledge the support provided by FAPESC CP 48/2021, UNIEDU/FUMDES, and Governo do Estado de Santa Catarina.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. E. coli (A) and S. senftenberg (B) decay profiles in soil fertilized with swine manure over time.
Figure 1. E. coli (A) and S. senftenberg (B) decay profiles in soil fertilized with swine manure over time.
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Figure 2. E. coli (A) and S. senftenberg (B) behavioral profiles in different soil depths fertilized with swine manure.
Figure 2. E. coli (A) and S. senftenberg (B) behavioral profiles in different soil depths fertilized with swine manure.
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Figure 3. E. coli leaching profile in swine manure fertilized soil exposed to 53 mm rain.
Figure 3. E. coli leaching profile in swine manure fertilized soil exposed to 53 mm rain.
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Table 1. Characterization of the natural clayey soil.
Table 1. Characterization of the natural clayey soil.
Soil particle sizeClay–Ø < 0.002 mm (%)72.0
Silt–0.002 mm < Ø < 0.06 mm (%)22.5
Thin sand–0.06 mm < Ø < 0.2 mm (%)1.8
Medium sand–0.2 mm < Ø < 0.6 mm (%)2.2
Coarse sand–0.6 mm < Ø < 2.0 mm (%)1.5
Boulder–2.0 mm < Ø < 60 mm (%)0.0
Geotechnical characteristicsLiquid limit (%)62
Plastic limit (%)37
Plastic index (%)25
Specific weight of grains (g cm−3)2.85
Textural classificationClay
H.R.B *-A.A.S.H.T.O. **A7-5
* Highway Research Board. ** American Association of State Highway and Transportation Officials.
Table 2. Physicochemical characteristics of swine manure used as a fertilizer.
Table 2. Physicochemical characteristics of swine manure used as a fertilizer.
CharacteristicValue
Total solids (g L−1)3–8
Total organic carbon (g L−1)1.5–6.5
BOD5 (g L−1)2.5–4.5
Alkalinity as CaCO3 (g L−1)5–8
Phosphate (g L−1)0.048–0.07
Total nitrogen (g L−1)1.5–2
Ammoniacal nitrogen (g L−1)0.9–1.5
pH7.9
Table 3. Inactivation coefficient (k), 90% reduction (T90) and correlation coefficient (r2) obtained from the linear model of the decay kinetics of E. coli and S. senftenberg in soil fertilized with swine manure.
Table 3. Inactivation coefficient (k), 90% reduction (T90) and correlation coefficient (r2) obtained from the linear model of the decay kinetics of E. coli and S. senftenberg in soil fertilized with swine manure.
Microorganismk (d−1)T90 (d)r2
E. coli0.10299.710.85
S. senftenberg0.09610.420.94
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Michelon, W.; Peter, N.R.W.; Schneider, T.M.; Segalla, D.C.; Viancelli, A. Enterobacteria Survival, Percolation, and Leaching on Soil Fertilized with Swine Manure. Int. J. Environ. Res. Public Health 2023, 20, 5283. https://doi.org/10.3390/ijerph20075283

AMA Style

Michelon W, Peter NRW, Schneider TM, Segalla DC, Viancelli A. Enterobacteria Survival, Percolation, and Leaching on Soil Fertilized with Swine Manure. International Journal of Environmental Research and Public Health. 2023; 20(7):5283. https://doi.org/10.3390/ijerph20075283

Chicago/Turabian Style

Michelon, William, Nivia Rosana Weber Peter, Tamili Martins Schneider, Dara Cristina Segalla, and Aline Viancelli. 2023. "Enterobacteria Survival, Percolation, and Leaching on Soil Fertilized with Swine Manure" International Journal of Environmental Research and Public Health 20, no. 7: 5283. https://doi.org/10.3390/ijerph20075283

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