The Challenges and Solutions for Cadmium-contaminated Rice in China: A Critical Review
The wide occurrence of Cd-contaminated rice in southern China poses significant public health risk and deserves immediate action, which arises primarily from extensive metal (including Cd) contamination of paddies with the fast expansion of nonferrous metal mining and smelting activities. Accumulati...
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| Published in: | Environment international Vol. 92-93; pp. 515 - 532 |
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| Main Authors: | , , |
| Format: | Journal Article |
| Language: | English |
| Published: |
Netherlands
Elsevier Ltd
01.07.2016
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| Subjects: | |
| ISSN: | 0160-4120, 1873-6750 |
| Online Access: | Get full text |
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| Abstract | The wide occurrence of Cd-contaminated rice in southern China poses significant public health risk and deserves immediate action, which arises primarily from extensive metal (including Cd) contamination of paddies with the fast expansion of nonferrous metal mining and smelting activities. Accumulation of Cd in rice grains can be reduced by removing Cd from the contaminated paddy soils, reducing its bioavailability, and controlling its uptake by rice plants. Although a range of measures can be taken to rehabilitate Cd-contaminated lands, including soil replacement and turnover, chemical washing, and phytoremediation, they are either too expensive and/or too slow. Various amendment materials, including lime, animal manures, and biochar, can be used to immobilize Cd in soils, but such fixation approach can only temporarily reduce Cd availability to rice uptake. Cultivation of alternative crops with low Cd accumulation in edible plant parts is impractical on large scales due to extensive contamination and food security concerns in southern China. Transgenic techniques can help develop rice cultivars with low Cd accumulation in grains, but little public acceptance is expected for such products. As an alternative, selection and development of low-Cd rice varieties and hybrids through plant biotechnology and breeding, particularly, by integration of marker-assisted selection (MAS) with traditional breeding, could be a practical and acceptable option that would allow continued rice production in soils with high bioavailability of Cd. Plant biotechnology and breeding can also help develop Cd-hyperaccumulating rice varieties, which can greatly facilitate phytoremediation of contaminated paddies. To eliminate the long-term risk of Cd entering the food chain, soils contaminated by Cd should be cleaned up when cost-effective remediation measures are available.
[Display omitted]
•Cd-contaminated rice poses major food safety and public health concerns in S. China•Cd pollution of paddies resulted primarily from nonferrous metal mining and smelting•Removal of Cd from soil is challenging, while its phytoavailability can be controlled•Plant biotechnology and breeding can accelerate development of low-Cd rice cultivars•Growing low-Cd rice in contaminated paddies can greatly reduce dietary exposure of Cd |
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| AbstractList | The wide occurrence of Cd-contaminated rice in southern China poses significant public health risk and deserves immediate action, which arises primarily from extensive metal (including Cd) contamination of paddies with the fast expansion of nonferrous metal mining and smelting activities. Accumulation of Cd in rice grains can be reduced by removing Cd from the contaminated paddy soils, reducing its bioavailability, and controlling its uptake by rice plants. Although a range of measures can be taken to rehabilitate Cd-contaminated lands, including soil replacement and turnover, chemical washing, and phytoremediation, they are either too expensive and/or too slow. Various amendment materials, including lime, animal manures, and biochar, can be used to immobilize Cd in soils, but such fixation approach can only temporarily reduce Cd availability to rice uptake. Cultivation of alternative crops with low Cd accumulation in edible plant parts is impractical on large scales due to extensive contamination and food security concerns in southern China. Transgenic techniques can help develop rice cultivars with low Cd accumulation in grains, but little public acceptance is expected for such products. As an alternative, selection and development of low-Cd rice varieties and hybrids through plant biotechnology and breeding, particularly, by integration of marker-assisted selection (MAS) with traditional breeding, could be a practical and acceptable option that would allow continued rice production in soils with high bioavailability of Cd. Plant biotechnology and breeding can also help develop Cd-hyperaccumulating rice varieties, which can greatly facilitate phytoremediation of contaminated paddies. To eliminate the long-term risk of Cd entering the food chain, soils contaminated by Cd should be cleaned up when cost-effective remediation measures are available. The wide occurrence of Cd-contaminated rice in southern China poses significant public health risk and deserves immediate action, which arises primarily from extensive metal (including Cd) contamination of paddies with the fast expansion of nonferrous metal mining and smelting activities. Accumulation of Cd in rice grains can be reduced by removing Cd from the contaminated paddy soils, reducing its bioavailability, and controlling its uptake by rice plants. Although a range of measures can be taken to rehabilitate Cd-contaminated lands, including soil replacement and turnover, chemical washing, and phytoremediation, they are either too expensive and/or too slow. Various amendment materials, including lime, animal manures, and biochar, can be used to immobilize Cd in soils, but such fixation approach can only temporarily reduce Cd availability to rice uptake. Cultivation of alternative crops with low Cd accumulation in edible plant parts is impractical on large scales due to extensive contamination and food security concerns in southern China. Transgenic techniques can help develop rice cultivars with low Cd accumulation in grains, but little public acceptance is expected for such products. As an alternative, selection and development of low-Cd rice varieties and hybrids through plant biotechnology and breeding, particularly, by integration of marker-assisted selection (MAS) with traditional breeding, could be a practical and acceptable option that would allow continued rice production in soils with high bioavailability of Cd. Plant biotechnology and breeding can also help develop Cd-hyperaccumulating rice varieties, which can greatly facilitate phytoremediation of contaminated paddies. To eliminate the long-term risk of Cd entering the food chain, soils contaminated by Cd should be cleaned up when cost-effective remediation measures are available. [Display omitted] •Cd-contaminated rice poses major food safety and public health concerns in S. China•Cd pollution of paddies resulted primarily from nonferrous metal mining and smelting•Removal of Cd from soil is challenging, while its phytoavailability can be controlled•Plant biotechnology and breeding can accelerate development of low-Cd rice cultivars•Growing low-Cd rice in contaminated paddies can greatly reduce dietary exposure of Cd |
| Author | Hu, Yuanan Tao, Shu Cheng, Hefa |
| Author_xml | – sequence: 1 givenname: Yuanan surname: Hu fullname: Hu, Yuanan organization: School of Water Resources and Environment, China University of Geosciences (Beijing), Beijing 100083, China – sequence: 2 givenname: Hefa surname: Cheng fullname: Cheng, Hefa email: hefac@umich.edu organization: MOE Key Laboratory for Earth Surface Processes, College of Urban and Environmental Sciences, Peking University, Beijing 100871, China – sequence: 3 givenname: Shu surname: Tao fullname: Tao, Shu organization: MOE Key Laboratory for Earth Surface Processes, College of Urban and Environmental Sciences, Peking University, Beijing 100871, China |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/27179698$$D View this record in MEDLINE/PubMed |
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| Copyright | 2016 Elsevier Ltd Copyright © 2016 Elsevier Ltd. All rights reserved. |
| Copyright_xml | – notice: 2016 Elsevier Ltd – notice: Copyright © 2016 Elsevier Ltd. All rights reserved. |
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| Keywords | Soil remediation Dietary intake Phytoavailability Plant biotechnology and breeding Cadmium-contaminated rice Health risk |
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| Title | The Challenges and Solutions for Cadmium-contaminated Rice in China: A Critical Review |
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