RESEARCH PROGRESS ON EFFECTS OF TYPICAL HEAVY METAL IONS ON ANAMMOX DENITRIFICATION SYSTEM

WANG An-qi; CAI Xiang; XIA Si-qing

doi:10.13205/j.hjgc.202102009

Volume 39 Issue 2

Jul. 2021

Turn off MathJax

Article Contents

Article Navigation > ENVIRONMENTAL ENGINEERING > 2021 > 39(2): 53-60,81

WANG An-qi, CAI Xiang, XIA Si-qing. RESEARCH PROGRESS ON EFFECTS OF TYPICAL HEAVY METAL IONS ON ANAMMOX DENITRIFICATION SYSTEM[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(2): 53-60,81. doi: 10.13205/j.hjgc.202102009

Citation:

WANG An-qi, CAI Xiang, XIA Si-qing. RESEARCH PROGRESS ON EFFECTS OF TYPICAL HEAVY METAL IONS ON ANAMMOX DENITRIFICATION SYSTEM[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(2): 53-60,81. doi: 10.13205/j.hjgc.202102009

Citation:

PDF( 1458 KB)

RESEARCH PROGRESS ON EFFECTS OF TYPICAL HEAVY METAL IONS ON ANAMMOX DENITRIFICATION SYSTEM

doi: 10.13205/j.hjgc.202102009

WANG An-qi^1,2,
CAI Xiang^1,2,
XIA Si-qing^{1,2
,
,}

1. State Key Laboratory of Pollution Control and Resource Reuse, School of Environmental Science and Engineering, Tongji University, Shanghai 200092, China;
2. Shanghai Institute of Pollution Control and Ecological Security, Shanghai 200092, China

Received Date: 2020-08-26
Available Online: 2021-07-19

Abstract

Abstract

Anammox (anaerobic ammonium oxidation) is regarded as the most promising biological denitrification technique, due to its advantages such as no necessity for additional carbon, low sludge yield and low energy consumption. However, anammox bacteria are highly sensitive to external environmental factors, which hinders its large-scale application. Heavy metal ions in industrial sewage are important environmental factors affecting the biological denitrification efficiency of anammox system. Moreover, the effect of heavy metal ions with different types, concentrations and valence state varies significantly. In this paper, the recent research results on the long and short term impact of typical heavy metal ions(Cu²⁺、Zn²⁺、Fe²⁺ and Fe³⁺) on anammox denitrification system were comprehensively summarized, and the internal mechanism of heavy metal ions acting on anammox microbial community was also systematically analyzed, to provide reference for improving denitrification efficiency.
- heavy metal ions,
- anammox,
- resistance gene,
- extracellular polymeric substance,
- microbial community

FullText(HTML)

References(62)

References

[1]	THAKUR I S, MEDHI K. Nitrification and denitrification processes for mitigation of nitrous oxide from waste water treatment plants for biovalorization:challenges and opportunities[J].Bioresource Technology,2019, 282:502-513.
[2]	SUN H M, YANG Z C, YANG F F, et al. Enhanced simultaneous nitrification and denitrification performance in a fixed-bed system packed with PHBV/PLA blends[J].International Biodeterioration & Biodegradation,2020, 146:104810.
[3]	JIANG M, FENG L Y, ZHENG X, et al. Bio-denitrification performance enhanced by graphene-facilitated iron acquisition[J].Water Research,2020, 180:115916.
[4]	ZHANG Z Z, ZHANG Y G, CHEN Y. Recent advances in partial denitrification in biological nitrogen removal:from enrichment to application[J].Bioresource Technology,2020, 298:122444.
[5]	SHI Z J, XU L Z, HUANG B C, et al. A novel strategy for anammox consortia preservation:transformation into anoxic sulfide oxidation consortia[J].Science of the Total Environment,2020, 723:138094.
[6]	MA B, XU X X, WEI Y, et al. Recent advances in controlling denitritation for achieving denitratation/anammox in mainstream wastewater treatment plants[J].Bioresource Technology,2020, 299:122697.
[7]	GUO Y, CHEN Y J, WEBECK E, et al. Towards more efficient nitrogen removal and phosphorus recovery from digestion effluent:latest developments in the anammox-based process from the application perspective[J].Bioresource Technology,2020, 299:122560.
[8]	WANG X T, YANG H, LIU X Y, et al. Effects of biomass and environmental factors on nitrogen removal performance and community structure of an anammox immobilized filler[J].Science of the Total Environment,2020, 710:135258.
[9]	JI X M, WU Z Y, SUNG S, et al. Metagenomics and metatranscriptomics analyses reveal oxygen detoxification and mixotrophic potentials of an enriched anammox culture in a continuous stirred-tank reactor[J].Water Research,2019, 166:115039.
[10]	TOMASZEWSKI M, CEMA G, ZIEMBINSKA-BUCZYNSKA A. Significance of pH control in anammox process performance at low temperature[J].Chemosphere,2017, 185:439-444.
[11]	CHEN H, MAO Y Y, JIN R C. What's the variation in anammox reactor performance after single and joint temperature based shocks?[J].Science of the Total Environment,2020, 713:136609.
[12]	ZHANG Q Q, BAI Y H, WU J, et al. Microbial community evolution and fate of antibiotic resistance genes in anammox process under oxytetracycline and sulfamethoxazole stresses[J].Bioresource Technology,2019, 293:122096.
[13]	NAKAMURA T, HARIGAYA Y, KIMURA Y, et al. Quantitative evaluation of inhibitory effect of various substances on anaerobic ammonia oxidation (anammox)[J].Journal of Bioscience and Bioengineering,2017, 124(3):333-338.
[14]	李芸, 张彦灼, 李军, 等. ANAMMOX颗粒污泥吸附氨氮特性及其影响因素[J].中国环境科学,2016, 36(3):741-750.
[15]	ZHANG Q Q, ZHANG Z Z, GUO Q, et al. Variation in the performance and sludge characteristics of anaerobic ammonium oxidation inhibited by copper[J].Separation and Purification Technology,2015, 142:108-115.
[16]	CHEN Z, ZHANG X J, MA Y P, et al. Anammox biofilm system under the stress of Hg(Ⅱ):nitrogen removal performance, microbial community dynamic and resistance genes expression[J].Journal of Hazardous Materials,2020, 395:122665.
[17]	WU D, LI G F, SHI Z J, et al. Co-inhibition of salinity and Ni(Ⅱ) in the anammox-UASB reactor[J].Science of the Total Environment,2019, 669:70-82.
[18]	XU L Z, WU J, XIA W J, et al. Adaption and restoration of anammox biomass to Cd(Ⅱ) stress:performance, extracellular polymeric substance and microbial community[J].Bioresource Technology,2019, 290:121766.
[19]	XU J J, ZHANG Z Z, CHEN Q Q, et al. The short- and long-term effects of Mn(Ⅱ) on biogranule-based anaerobic ammonium oxidation (anammox)[J].Bioresource Technology,2017, 241:750-759.
[20]	GONZALEZ-ESTRELLA J, LI G B, NEELY S E, et al. Elemental copper nanoparticle toxicity to anaerobic ammonium oxidation and the influence of ethylene diamine-tetra acetic acid (EDTA) on copper toxicity[J].Chemosphere,2017, 184:730-737.
[21]	DAVEREY A, CHEN Y C, LIANG Y C, et al. Short-term effects of monoethanolamine and copper on the activities of Anammox bacteria[J].Sustainable Environment Research,2014, 24(5):325-331.
[22]	LOTTI T, CORDOLA M, KLEEREBEZEM R, et al. Inhibition effect of swine wastewater heavy metals and antibiotics on anammox activity[J].Water Science and Technology,2012, 66(7):1519-1526.
[23]	DAVEREY A, CHEN Y C, SUNG S, et al. Effect of zinc on anammox activity and performance of simultaneous partial nitrification, anammox and denitrification (SNAD) process[J].Bioresource Technology,2014, 165:105-110.
[24]	KALKAN A C, UZUNHASANOGLU A E, YAPSAKLI K. Speciation of nickel and zinc, its short-term inhibitory effect on anammox, and the associated microbial community composition[J].Bioresource Technology,2018, 268:558-567.
[25]	LIU Y W, NI B J. Appropriate Fe (Ⅱ) addition significantly enhances anaerobic ammonium oxidation (Anammox) activity through improving the bacterial growth rate[J].Scientific Reports,2015, 5:8204.
[26]	YAN Y, WANG Y Y, WANG W G, et al. Comparison of short-term dosing ferrous ion and nanoscale zero-valent iron for rapid recovery of anammox activity from dissolved oxygen inhibition[J].Water Research,2019, 153:284-294.
[27]	MAK C Y, LIN J G, CHEN W H, et al. The short- and long-term inhibitory effects of Fe (Ⅱ) on anaerobic ammonium oxidizing (anammox) process[J].Water Science and Technology,2019, 79(10):1860-1867.
[28]	CHEN H, YU J J, JIA X Y, et al. Enhancement of anammox performance by Cu(Ⅱ), Ni(Ⅱ) and Fe(Ⅲ) supplementation[J].Chemosphere,2014, 117:610-616.
[29]	袁新明, 王电站. 金属离子对厌氧氨氧化污泥脱氮效能影响[J].环境污染与防治,2019, 41(5):515-519 ,525.
[30]	李祥, 黄勇, 巫川, 等. Fe²⁺和Fe³⁺对厌氧氨氧化污泥活性的影响[J].环境科学,2014, 35(11):4224-4229.
[31]	ZHOU Y, ZHANG X J, CHEN Z, et al. Influence of CuO nanoparticle with different particle size on nitrogen removal and microbial community of anammox process[J].Environmental Engineering Science,2019, 36(6):724-731.
[32]	MA Y P, YUAN D L, MU B L, et al. Reactor performance, biofilm property and microbial community of anaerobic ammonia-oxidizing bacteria under long-term exposure to elevated Cu (Ⅱ)[J].International Biodeterioration & Biodegradation,2018, 129:156-162.
[33]	ZHANG Q Q, ZHANG Z Z, GUO Q, et al. Analyzing the revolution of anaerobic ammonium oxidation (anammox) performance and sludge characteristics under zinc inhibition[J].Applied Microbiology and Biotechnology,2015, 99(7):3221-3232.
[34]	ZHANG X J, CHEN Z, ZHOU Y, et al. Impacts of the heavy metals Cu (Ⅱ), Zn (Ⅱ) and Fe (Ⅱ) on an Anammox system treating synthetic wastewater in low ammonia nitrogen and low temperature:Fe (Ⅱ) makes a difference[J].Science of the Total Environment,2019, 648:798-804.
[35]	BI Z, QIAO S, ZHOU J T, et al. Fast start-up of Anammox process with appropriate ferrous iron concentration[J].Bioresource Technology,2014, 170:506-512.
[36]	李祥, 黄勇, 刘福鑫, 等. 铜、锌离子对厌氧氨氧化污泥脱氮效能的影响[J].中国环境科学,2014, 34(4):924-929.
[37]	YANG G F, NI W M, WU K, et al. The effect of Cu(Ⅱ) stress on the activity, performance and recovery on the Anaerobic Ammonium-Oxidizing (Anammox) process[J].Chemical Engineering Journal,2013, 226:39-45.
[38]	ZHANG X J, CHEN Z, MA Y P, et al. Influence of elevated Zn(Ⅱ) on Anammox system:microbial variation and zinc tolerance[J].Bioresource Technology,2018, 251:108-113.
[39]	FAN N S, ZHU X L, WU J, et al. Deciphering the microbial and genetic responses of anammox biogranules to the single and joint stress of zinc and tetracycline[J].Environment International,2019, 132:105097.
[40]	SHU D T, HE Y L, YUE H, et al. Effects of Fe(Ⅱ) on microbial communities, nitrogen transformation pathways and iron cycling in the anammox process:kinetics, quantitative molecular mechanism and metagenomic analysis[J].RSC Advances,2016, 6(72):68005-68016.
[41]	HUANG X L, GAO D W, PENG S, et al. Effects of ferrous and manganese ions on anammox process in sequencing batch biofilm reactors[J].Journal of Environmental Sciences,2014, 26(5):1034-1039.
[42]	ZHANG X J, ZHOU Y, ZHAO S Y, et al. Effect of Fe (Ⅱ) in low-nitrogen sewage on the reactor performance and microbial community of an ANAMMOX biofilter[J].Chemosphere,2018, 200:412-418.
[43]	MISHRA P, BURMAN I, SINHA A. Performance enhancement and optimization of the anammox process with the addition of iron[J].Environmental Technology,2020:1-12.
[44]	李祥, 黄勇, 巫川, 等. Fe²⁺和Fe³⁺对厌氧氨氧化污泥活性的影响[J].环境科学,2014, 35(11):4224-4229.
[45]	WANG X, SHU D T, YUE H. Taxonomical and functional microbial community dynamics in an Anammox-ASBR system under different Fe (Ⅲ) supplementation[J].Applied Microbiology and Biotechnology,2016, 100(23):10147-10163.
[46]	张倩倩. 铜(Ⅱ)和土霉素对厌氧氨氧化工艺性能的抑制及其调控对策[D]. 杭州:浙江大学,2019.
[47]	ZHANG X J, CHEN Z, ZHOU Y, et al. Comparisons of nitrogen removal and microbial communities in anammox systems upon addition of copper-based nanoparticles and copper ion[J].Industrial & Engineering Chemistry Research,2019, 58(19):7808-7816.
[48]	BESAURY L, PAWLAK B, QUILLET L. Expression of copper-resistance genes in microbial communities under copper stress and oxic/anoxic conditions[J].Environmental Science and Pollution Research,2016, 23(5):4013-4023.
[49]	XING C Y, FAN Y C, CHEN X, et al. A self-assembled nanocompartment in anammox bacteria for resisting intracelluar hydroxylamine stress[J].Science of the Total Environment,2020, 717:137030.
[50]	ZHANG Q Q, ZHAO Y H, WANG G J, et al. Expression of the nirS, hzsA, and hdh genes and antibiotic resistance genes in response to recovery of anammox process inhibited by oxytetracycline[J].Science of the Total Environment,2019, 681:56-65.
[51]	MA X, YAN Y, WANG W G, et al. Metatranscriptomic analysis of adaptive response of anammox bacteria Candidatus ‘Kuenenia stuttgartiensis’ to Zn(Ⅱ) exposure[J].Chemosphere,2020, 246:125682.
[52]	ZHANG Z Z, CHENG Y F, XU L Z, et al. Discrepant effects of metal and metal oxide nanoparticles on anammox sludge properties:a comparison between Cu and CuO nanoparticles[J].Bioresource Technology,2018, 266:507-515.
[53]	QIAO S, BI Z, ZHOU J T, et al. Long term effects of divalent ferrous ion on the activity of anammox biomass[J].Bioresource Technology,2013, 142:490-497.
[54]	MIAO L, ZHANG Q, WANG S Y, et al. Characterization of EPS compositions and microbial community in an Anammox SBBR system treating landfill leachate[J].Bioresource Technology,2018, 249:108-116.
[55]	毛泓宇, 谢丽, 陆熙, 等. 厌氧颗粒污泥自启动厌氧氨氧化反应特性研究[J].环境工程,2020, 38(1):93-98 ,104.
[56]	WU D, ZHANG Q, XIA W J, et al. Effect of divalent nickel on the anammox process in a UASB reactor[J].Chemosphere,2019, 226:934-944.
[57]	NI L F, WANG Y Y, LIN X M, et al. Enhancement of the adaptability of anammox granules to zinc shock by appropriate organic carbon treatment[J].Bioresource Technology,2018, 268:496-504.
[58]	LI G F, MA W J, CHENG Y F, et al. A spectra metrology insight into the binding characteristics of Cu²⁺ onto anammox extracellular polymeric substances[J].Chemical Engineering Journal,2020, 393:124800.
[59]	TANG S M, XU Z H, LIU Y L, et al. Performance, kinetics characteristics and enhancement mechanisms in anammox process under Fe(Ⅱ) enhanced conditions[J].Biodegradation,2020,31(4/5/6):223-234.
[60]	PRADHAN N, SWATHI S, WUERTZ S. Inhibition factors and kinetic model for anaerobic ammonia oxidation in a granular sludge bioreactor with Candidatus Brocadia[J].Chemical Engineering Journal,2020, 389:123618.
[61]	YANG Y C, LI M, LI H, et al. Specific and effective detection of anammox bacteria using PCR primers targeting the 16S rRNA gene and functional genes[J]. Science of the Total Environment,2020, 734:139387.
[62]	贾方旭, 彭永臻, 杨庆. 厌氧氨氧化菌与其他细菌之间的协同竞争关系[J].环境科学学报,2014, 34(6):1351-1361.