吉林大学学报(医学版) ›› 2020, Vol. 46 ›› Issue (6): 1338-1344.doi: 10.13481/j.1671-587x.20200636
• 综述 • 上一篇
微生物修复环境铬污染机制的研究进展
张敏,范春,赵苒(
)
- 厦门大学分子疫苗学和分子诊断学国家重点实验室 厦门大学公共卫生学院预防医学系,福建 厦门 361102
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收稿日期:2020-03-29出版日期:2020-11-28发布日期:2021-01-27 -
通讯作者:赵苒 E-mail:zhaoran@xmu.edu.cn -
作者简介:张 敏(1994-),女,江西省宜春市人,在读医学硕士,主要从事环境与健康方面的研究。 -
基金资助:国家自然科学基金面上项目资助课题(81673129);福建省教育厅中青年教师教育科研项目资助课题(JAT160001)
Research progress in mechanism of bioremediation in environmental chromium pollution
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Received:2020-03-29Online:2020-11-28Published:2021-01-27
摘要:
铬污染的治理方法主要有物理法、化学法和微生物修复法,其中物理法和化学法处理程序复杂、成本高、效率低,且效果不稳定,易引发二次污染,这2种方法在实际应用中备受限制。微生物修复技术是通过特定生物(主要是藻类、细菌和真菌等微生物)将水或土壤中的污染物降解为低毒或无毒化合物的过程,细菌和真菌等微生物可通过生物转化、生物积累和生物吸附等多种机制去除环境中的六价铬[Cr(Ⅵ)]来修复铬污染,该过程具有成本低、效率高、过程安全和不易产生二次污染等优点,是一种环境友好型的铬去除技术,可应用于持久性有机污染物与重金属所致环境污染的治理以及重金属固化、回收等工艺中。现从微生物修复环境铬污染的技术、机制、环境影响因素和环境介质等方面进行综述,并对该技术的实际应用进行展望。
中图分类号:
- R117
引用本文
张敏,范春,赵苒. 微生物修复环境铬污染机制的研究进展[J]. 吉林大学学报(医学版), 2020, 46(6): 1338-1344.
表1
不同微生物及其修复Cr(Ⅵ)的机制"
| Strain | Mechanism | Reference |
|---|---|---|
| Algae | ||
| Spirulina platensis | Biosorption | FERNáNDEZ,et al.[ |
| Spirulina platensis | Biosorption | FERNáNDEZ, et al.[ |
| Pelvetia canaliculata | Biosorption | FERNáNDEZ,et al.[ |
| Dunaliella salina | Biosorption | VIDYALAXMI,et al.[ |
| Bacteria | ||
| Bacillus sp. CRB-B1 | Biosorption, Biotransformation | TAN, et al.[ |
| Pseudomonas aeruginosa G12 | Biotransformation | AN, et al.[ |
| sp. QH-2 | Biotransformation | WANG, et al.[ |
| Staphylococcusaureus K1 | Biosorption, Biotransformation | TARIQ, et al.[ |
| Stenotrophomonas sp. WY601 | Biotransformation | LIU, et al.[ |
| Pseudomonas sp. strain DC-B3 | Biosorption, Biotransformation | CHANG, et al.[ |
| Bacillus strain TCL | Biotransformation | BANERJEE, et al.[ |
| Aeromonas hydrophila | Biotransformation | SHI, et al.[ |
| Sporosarcina saro mensis M52 | Biotransformation | ZHAO, et al.[ |
| Fungi | ||
| P. saccharolyticum LY10. | Biosorption, Bioaccumulation | LONG, et al.[ |
| Papiliotrema laurentii strain RY1 | Biosorption | SARKAR, et al.[ |
| Trichoderma sp. | Biosorption, Bioaccumulation | KUMAR, et al.[ |
| Pisolithus sp1 | Biosorption, Bioaccumulation | SHI, et al.[ |
| Aspergillus flavus CR500 | Biosorption, Biotransformation | KUMAR,et al.[ |
表1
表2
生物吸附特征及其影响因素"
| Strain | Characteristics of adsorption | Influencing factor |
|---|---|---|
Dead bacteria | ①No need to add nutrients; ②Not affected by toxic substances; ③ May occur in high concentrations of Cr(Ⅵ); ④ Abscission tendency of loose adsorption. | Initial concentration of Cr(Ⅵ) , contact time, pH, biosorbent dosage, et al. |
Living bacteria | ①Mechanisms such as transportation, formation and precipitation of extracellular complexes; ②Remove Cr(Ⅵ) while growing; ③ High concentration of Cr(Ⅵ) affects growth of strains | Initial concentration of Cr(Ⅵ), contact time, pH, temperature, and environmental factors such as existence of metal ions and small molecules |
表2
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