Watering regime influences Cd concentrations in cultivated spinach

In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this concentration can sometimes be exceeded even on soils with baseline Cd concentrations. There is a growing need to quantify the factors determinin...

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Published in	Journal of environmental management Vol. 186; no. Pt 2; pp. 201 - 206
Main Author	Tack, Filip M.G.
Format	Journal Article
Language	English
Published	England Elsevier Ltd 15.01.2017
Subjects	Agricultural Irrigation - methods Agriculture - methods Cadmium Cadmium - analysis Cadmium - pharmacokinetics Computer Simulation crops Crops, Agricultural Food Contamination - analysis Food safety Horticulture Monte Carlo Method risk soil Soil - chemistry Soil Pollutants - analysis Soil Pollutants - pharmacokinetics Spinach Spinacia oleracea - chemistry Spinacia oleracea - metabolism Vegetables water supply Cadmium Food safety Vegetables Spinach Horticulture
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Abstract	In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this concentration can sometimes be exceeded even on soils with baseline Cd concentrations. There is a growing need to quantify the factors determining Cd uptake in the crop in order to anticipate the risk of exceedance when selecting a field for cultivation. Interseasonal variation in precipitation may be one of the factors influencing Cd uptake by crops. A pot experiment was set up where spinach plants were subject to different watering regimes. Treatment with more limited water supply during periods of high demand resulted in significantly higher accumulated Cd concentrations (0.25–0.31 versus 0.17–0.23 mg/kg FW). Concentrations at or above the maximum allowed limit were of concern, considering that the soil used in the experiment originated from a typical field in an agricultural region without any specific contamination. Probabilities to exceed maximum concentrations in the different watering regimes were estimated using Monte Carlo simulation. Results suggested that the watering regimes significantly determine the effective risk of exceeding the maximum concentrations. Their effects may be of high practical importance in the field. •Maximum allowable Cd levels in spinach exceeded in soil with baseline Cd contents.•Moisture regime significantly impacts Cd concentrations in spinach.•More dry conditions lead to a higher Cd concentration in spinach.•Risk for exceeding acceptable Cd levels is strongly determined by the watering regime.
AbstractList	In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this concentration can sometimes be exceeded even on soils with baseline Cd concentrations. There is a growing need to quantify the factors determining Cd uptake in the crop in order to anticipate the risk of exceedance when selecting a field for cultivation. Interseasonal variation in precipitation may be one of the factors influencing Cd uptake by crops. A pot experiment was set up where spinach plants were subject to different watering regimes. Treatment with more limited water supply during periods of high demand resulted in significantly higher accumulated Cd concentrations (0.25-0.31 versus 0.17-0.23 mg/kg FW). Concentrations at or above the maximum allowed limit were of concern, considering that the soil used in the experiment originated from a typical field in an agricultural region without any specific contamination. Probabilities to exceed maximum concentrations in the different watering regimes were estimated using Monte Carlo simulation. Results suggested that the watering regimes significantly determine the effective risk of exceeding the maximum concentrations. Their effects may be of high practical importance in the field. In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this concentration can sometimes be exceeded even on soils with baseline Cd concentrations. There is a growing need to quantify the factors determining Cd uptake in the crop in order to anticipate the risk of exceedance when selecting a field for cultivation. Interseasonal variation in precipitation may be one of the factors influencing Cd uptake by crops. A pot experiment was set up where spinach plants were subject to different watering regimes. Treatment with more limited water supply during periods of high demand resulted in significantly higher accumulated Cd concentrations (0.25–0.31 versus 0.17–0.23 mg/kg FW). Concentrations at or above the maximum allowed limit were of concern, considering that the soil used in the experiment originated from a typical field in an agricultural region without any specific contamination. Probabilities to exceed maximum concentrations in the different watering regimes were estimated using Monte Carlo simulation. Results suggested that the watering regimes significantly determine the effective risk of exceeding the maximum concentrations. Their effects may be of high practical importance in the field. In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this concentration can sometimes be exceeded even on soils with baseline Cd concentrations. There is a growing need to quantify the factors determining Cd uptake in the crop in order to anticipate the risk of exceedance when selecting a field for cultivation. Interseasonal variation in precipitation may be one of the factors influencing Cd uptake by crops. A pot experiment was set up where spinach plants were subject to different watering regimes. Treatment with more limited water supply during periods of high demand resulted in significantly higher accumulated Cd concentrations (0.25–0.31 versus 0.17–0.23 mg/kg FW). Concentrations at or above the maximum allowed limit were of concern, considering that the soil used in the experiment originated from a typical field in an agricultural region without any specific contamination. Probabilities to exceed maximum concentrations in the different watering regimes were estimated using Monte Carlo simulation. Results suggested that the watering regimes significantly determine the effective risk of exceeding the maximum concentrations. Their effects may be of high practical importance in the field. •Maximum allowable Cd levels in spinach exceeded in soil with baseline Cd contents.•Moisture regime significantly impacts Cd concentrations in spinach.•More dry conditions lead to a higher Cd concentration in spinach.•Risk for exceeding acceptable Cd levels is strongly determined by the watering regime.
Author	Tack, Filip M.G.
Author_xml	– sequence: 1 givenname: Filip M.G. surname: Tack fullname: Tack, Filip M.G. email: filip.tack@ugent.be organization: Department of Applied Analytical and Physical Chemistry, Ghent University, Coupure Links 653, B-9000 Gent, Belgium
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Keywords	Cadmium Food safety Vegetables Spinach Horticulture
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Snippet	In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this... In washed spinach, a maximum Cd concentration of 0.20 mg/kg fresh weight (FW) is allowed according to European regulations. Producers experience that this...
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SubjectTerms	Agricultural Irrigation - methods Agriculture - methods Cadmium Cadmium - analysis Cadmium - pharmacokinetics Computer Simulation crops Crops, Agricultural Food Contamination - analysis Food safety Horticulture Monte Carlo Method risk soil Soil - chemistry Soil Pollutants - analysis Soil Pollutants - pharmacokinetics Spinach Spinacia oleracea - chemistry Spinacia oleracea - metabolism Vegetables water supply
Title	Watering regime influences Cd concentrations in cultivated spinach
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