Heavy Metals in Agriculture Soils from High Andean Zones and Potential Ecological Risk Assessment in Peru's Central Andes

Orellana, Edith; Custodio, María; Bastos, María Carolina; Ascencion, Julio Cesar

doi:10.12911/22998993/127094

Cited by 13 publications

(5 citation statements)

References 28 publications

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“…The results obtained reveal that soils in sectors S3 and S4 recorded PTE concentrations that exceeded the maximum permitted limits of the national and international standard ( MINEN, 2017 , FAO/WHO, 2011a , CME, 2004 , EPMC, 2014 ), which means that the soils in these sectors are undergoing degradation processes. The mean concentrations of As, Pb and Zn in this study were higher than the concentrations reported by Orellana et al (2020) in high Andean areas with rainfed agriculture in the central region of Peru. The high concentration of Pb and As in sectors S3 and S4 reveal that the bioavailable concentration of heavy metals is higher in soils irrigated with contaminated water than in soils irrigated with rainwater.…”

Section: Discussioncontrasting

confidence: 91%

Human risk associated with the ingestion of artichokes grown in soils irrigated with water contaminated by potentially toxic elements, Junin, Peru

Custodio

Peñaloza

Ochoa

et al. 2021

Saudi Journal of Biological Sciences

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The contamination of water, air and soil with potentially toxic elements (PTE) compromises the supply of contaminant free food. Vegetables grown in contaminated soils can absorb and accumulate PTE at concentrations that are toxic to human health. In this context, the human risk associated with the intake of artichokes grown in soils irrigated with PTE contaminated water was assessed. 120 samples of surface soil and artichoke heads were collected and the concentrations of Cu, Fe, Pb, Zn and As were determined. The results showed that the concentrations of Cu, Fe and Zn in soil did not exceed the standards of the Ministry of Environment of Peru, but they did exceed those of Pb (125.45 mg kg −1 ) and As (28.70 mg kg −1 ). The decreasing order of mean PTE concentration in artichoke heads was Fe > Zn > Cu > Pb > As, exceeding the permissible levels of FAO/WHO CODEX Alimentarius. However, the concentrations of As comply with the maximum limits of inorganic contaminants in vegetables (0.3 mg kg −1 ) established in the MERCOSUR regulations. The non-carcinogenic and carcinogenic risk of Pb and As indicated that the ingestion of artichoke heads does not represent a health risk.

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Section: Discussioncontrasting

confidence: 91%

Human risk associated with the ingestion of artichokes grown in soils irrigated with water contaminated by potentially toxic elements, Junin, Peru

Custodio

Peñaloza

Ochoa

et al. 2021

Saudi Journal of Biological Sciences

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“…Relatively high Zn and Pb contents lead to correspondingly higher geoaccumulation index values. The ecological risk index mainly considers the toxicity of the different heavy metals [9] . Additionally, the toxic response factors of Cd and Hg are much higher than those of other heavy metals, which leads to larger E i values for Cd and Hg.…”

Section: Potential Ecological Risk Index Resultsmentioning

confidence: 99%

“…There are many severe problems due to soil contamination in China, particularly related to heavy metals [8]. Because of the toxicity, bioaccumulation and persistence of heavy metals, they pose a significant threat to the natural environment [9] . Understanding the concentration and spatial distribution of soil heavy metals and assessing their ecological risks are critical for the accurate and effective implementation of risk management and control of soil heavy metal pollution [10] .…”

Section: Introductionmentioning

confidence: 99%

“…Understanding the concentration and spatial distribution of soil heavy metals and assessing their ecological risks are critical for the accurate and effective implementation of risk management and control of soil heavy metal pollution [10] . In terms of soil heavy metal distribution characteristics and ecological risk assessments, most current research has focused on mainland ecosystems, with little attention paid to islands [9,[11][12][13] . In this study, Sanjiaozhou Island, an important and typical tourist island in Daya Bay, southern China, was selected to investigate the heavy metal pollution in the surface soils and to identify the influence of human activities.…”

Section: Introductionmentioning

confidence: 99%

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Risk Assessment of Heavy Metal Distribution in Soil of a Typical Tourist Island in South China

2024

AJEE

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The concentrations of seven heavy metals (Hg, Cd, Pb, Cu, As, Cr and Zn) were measured in 20 topsoil samples collected from Sanjiaozhou Island to (1) reveal the distribution of heavy metals in soils after long-term human activities on an uninhabited island, and ( 2) analyze the ecological risks associated with soil heavy metals. According to the measured heavy metal concentrations, Zn (88.07 mg/kg) had the highest concentration, which was followed by Pb, Cr, Cu, As, Hg and Cd. Additionally, the average concentrations of Pb (73.86 mg/kg) and Hg (0.17 mg/kg) exceeded the background values 1.23 and 1.31 times, respectively. The analyzed contamination degrees, based on the contamination factor index (P i ) and geoaccumulation index (I geo ) values, were mostly low, but were high for Hg and Pb. The mean value of the potential ecological index (RI) of heavy metals in soils was 80.95, indicating a relatively low potential ecological risk. In terms of the individual metal ecological index (E i ) value, Hg was the highest followed by Cd, Pb, Cu, As, Cr and Zn. Hg resulted in a higher ecological risk, as its average E i was 52.31, suggesting a moderate risk to the environment. Based on the distribution of the metals, domestic sewage discharge and agricultural inputs are most likely to be the primary sources of metal pollution on the island.

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“…The potential ecological risk index method [ 27 , 45 ] was used to evaluate the potential ecological risks of soil PHEs obtained through sedimentation from coking waste gas in BTH (Equations (8) and (9)).

where

is the potential ecological risk index of a single PHE i ;

is the toxicity coefficient of PHE i , and the coefficients of As, Cd, Cr, Cu, Hg, Ni, Pb, and Zn are 10, 30, 2, 5, 40, 5, 5, and 1, respectively [ 45 , 46 , 47 ];

is the concentration of a single PHE i , mg·kg −1 ;

is a reference for a single PHE i , mg·kg −1 , which was the background value of PHEs in BTH; RI is the comprehensive potential ecological risk index of PHEs. Risk classification standards refer to published studies [ 45 , 48 ] ( Table S2, Supplementary File) .…”

Section: Methodsmentioning

confidence: 99%

Discharge Patterns of Potentially Harmful Elements (PHEs) from Coking Plants and Its Relationship with Soil PHE Contents in the Beijing–Tianjin–Hebei Region, China

Wan

Zeng

et al. 2022

Toxics

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The Beijing–Tianjin–Hebei (BTH) region in China is a rapid development area with a dense population and high-pollution, high-energy-consumption industries. Despite the general idea that the coking industry contributes greatly to the total emission of potentially harmful elements (PHEs) in BTH, quantitative analysis on the PHE pollution caused by coking is rare. This study collected the pollutant discharge data of coking enterprises and assessed the risks of coking plants in BTH using the soil accumulation model and ecological risk index. The average contribution rate of coking emissions to the total emissions of PHEs in BTH was ~7.73%. Cross table analysis indicated that there was a close relationship between PHEs discharged by coking plants and PHEs in soil. The accumulation of PHEs in soil and their associated risks were calculated, indicating that nearly 70% of the coking plants posed a significant ecological risk. Mercury, arsenic, and cadmium were the main PHEs leading to ecological risks. Scenario analysis indicated that the percentage of coking plants with high ecological risk might rise from 8.50% to 20.00% as time progresses. Therefore, the control of PHEs discharged from coking plants in BTH should be strengthened. Furthermore, regionalized strategies should be applied to different areas due to the spatial heterogeneity of risk levels.

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Heavy Metals in Agriculture Soils from High Andean Zones and Potential Ecological Risk Assessment in Peru's Central Andes

Cited by 13 publications

References 28 publications

Human risk associated with the ingestion of artichokes grown in soils irrigated with water contaminated by potentially toxic elements, Junin, Peru

Human risk associated with the ingestion of artichokes grown in soils irrigated with water contaminated by potentially toxic elements, Junin, Peru

Risk Assessment of Heavy Metal Distribution in Soil of a Typical Tourist Island in South China

Discharge Patterns of Potentially Harmful Elements (PHEs) from Coking Plants and Its Relationship with Soil PHE Contents in the Beijing–Tianjin–Hebei Region, China

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