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Hauptverfasser: Zhang, Jian, Liu, Cong, Ling, Juan, Zhou, Weiguo, Wang, Youshao, Cheng, Hao, Huang, Xiaofang, Yang, Qingsong, Zhang, Wenqian, Liang, Tongyin, Zhang, Ying, Dong, Junde
Format: Artículo científico
Sprache:en
Veröffentlicht: Ecotoxicology and environmental safety 2025
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Online-Zugang:https://pubmed.ncbi.nlm.nih.gov/40037084/
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author Zhang, Jian
Liu, Cong
Ling, Juan
Zhou, Weiguo
Wang, Youshao
Cheng, Hao
Huang, Xiaofang
Yang, Qingsong
Zhang, Wenqian
Liang, Tongyin
Zhang, Ying
Dong, Junde
author_facet Zhang, Jian
Liu, Cong
Ling, Juan
Zhou, Weiguo
Wang, Youshao
Cheng, Hao
Huang, Xiaofang
Yang, Qingsong
Zhang, Wenqian
Liang, Tongyin
Zhang, Ying
Dong, Junde
Zhang, Jian
Liu, Cong
Ling, Juan
Zhou, Weiguo
Wang, Youshao
Cheng, Hao
Huang, Xiaofang
Yang, Qingsong
Zhang, Wenqian
Liang, Tongyin
Zhang, Ying
Dong, Junde
collection PubMed - marine biology
contents Revealing the potential of biochar for heavy metal polluted seagrass remediation from microbial perspective. Zhang, Jian Liu, Cong Ling, Juan Zhou, Weiguo Wang, Youshao Cheng, Hao Huang, Xiaofang Yang, Qingsong Zhang, Wenqian Liang, Tongyin Zhang, Ying Dong, Junde Charcoal Water Pollutants, Chemical Metals, Heavy Environmental Restoration and Remediation Hydrocharitaceae Microbiota Biodegradation, Environmental Seagrass meadows are under threat due to climate change and human activities, including heavy metal contamination, which can accumulate in seagrass tissues and harm their health and productivity. Despite extensive research, effective remediation strategies are lacking. This study investigated biochar's potential as a remediation agent for seagrass meadows affected by heavy metal pollution. Heavy metal pollution was simulated by adding copper (Cu) and chromium (Cd) to seagrass Thalassia hemprichii, and the remediation effects of biochar were evaluated by monitoring seagrass physiology, root-associated microbial communities, and heavy metal concentrations. Seagrasses can accumulate heavy metals, which adversely affect their health and alter microbial communities. Seagrasses may resist heavy metal stress by releasing dissolved organic carbon (DOC) and recruiting beneficial bacteria. Biochar reduced heavy metal bioavailability and restored seagrass ecosystem health, as evidenced by restored microbial community dynamics. This study highlights biochar's promising role in seagrass meadow restoration impacted by heavy metal pollution.
format Artículo científico
id pubmed_40037084
institution PubMed
language en
publishDate 2025
publisher Ecotoxicology and environmental safety
record_format pubmed
spellingShingle Revealing the potential of biochar for heavy metal polluted seagrass remediation from microbial perspective.
Zhang, Jian
Liu, Cong
Ling, Juan
Zhou, Weiguo
Wang, Youshao
Cheng, Hao
Huang, Xiaofang
Yang, Qingsong
Zhang, Wenqian
Liang, Tongyin
Zhang, Ying
Dong, Junde
Charcoal
Water Pollutants, Chemical
Metals, Heavy
Environmental Restoration and Remediation
Hydrocharitaceae
Microbiota
Biodegradation, Environmental
Revealing the potential of biochar for heavy metal polluted seagrass remediation from microbial perspective. Zhang, Jian Liu, Cong Ling, Juan Zhou, Weiguo Wang, Youshao Cheng, Hao Huang, Xiaofang Yang, Qingsong Zhang, Wenqian Liang, Tongyin Zhang, Ying Dong, Junde Charcoal Water Pollutants, Chemical Metals, Heavy Environmental Restoration and Remediation Hydrocharitaceae Microbiota Biodegradation, Environmental Seagrass meadows are under threat due to climate change and human activities, including heavy metal contamination, which can accumulate in seagrass tissues and harm their health and productivity. Despite extensive research, effective remediation strategies are lacking. This study investigated biochar's potential as a remediation agent for seagrass meadows affected by heavy metal pollution. Heavy metal pollution was simulated by adding copper (Cu) and chromium (Cd) to seagrass Thalassia hemprichii, and the remediation effects of biochar were evaluated by monitoring seagrass physiology, root-associated microbial communities, and heavy metal concentrations. Seagrasses can accumulate heavy metals, which adversely affect their health and alter microbial communities. Seagrasses may resist heavy metal stress by releasing dissolved organic carbon (DOC) and recruiting beneficial bacteria. Biochar reduced heavy metal bioavailability and restored seagrass ecosystem health, as evidenced by restored microbial community dynamics. This study highlights biochar's promising role in seagrass meadow restoration impacted by heavy metal pollution.
title Revealing the potential of biochar for heavy metal polluted seagrass remediation from microbial perspective.
topic Charcoal
Water Pollutants, Chemical
Metals, Heavy
Environmental Restoration and Remediation
Hydrocharitaceae
Microbiota
Biodegradation, Environmental
url https://pubmed.ncbi.nlm.nih.gov/40037084/