常见固体废弃物处理处置过程中病原菌的赋存、传播与灭活技术

doi:10.13287/j.1001-9332.202508.036

摘要/Abstract

摘要： 固体废弃物是病原菌的重要来源,其在收集、运输及处理处置过程中可能通过直接接触、气溶胶传播、渗滤液排放及固体废弃物处理衍生物传播等途径威害人体健康与生态环境。固体废弃物的处理处置方式不同,其中病原菌的种类和丰度也会存在差异。本文综述了生活垃圾、禽畜养殖废弃物和污泥等常见固体废弃物中病原菌的种类及赋存行为,分析了不同处理处置方式(如填埋、堆肥和厌氧消化等)下病原菌的动态变化与传播风险,最后梳理了紫外、微波、化学消化剂和热处理等主流灭活技术在固体废弃物病原菌灭活中的适用性及其作用机制,并指出当前研究中需要注意的关键问题及未来研究方向。本文可为病原菌风险防控和提高固体废弃物处理处置安全性提供参考。

关键词: 固体废弃物, 病原菌, 传播风险, 灭活技术

Abstract: Solid waste is an important source of pathogens. During the process of collection, transportation, and treatment, pathogens may spread through direct contact, aerosol transmission, leachate discharge, and waste-derived by-products, posing threats to human health and ecological environment. The types and abundance of pathogens vary across different waste types and treatment methods. We summarized the types and occurrence patterns of pathogens commonly found in municipal solid waste, livestock and poultry manure, and sewage sludge. We further analyzed the dynamics and transmission risks of pathogens under different treatment and disposal methods such as landfilling, composting, and anaerobic digestion. Moreover, we reviewed the applicability and mechanisms of inactivation technologies, including ultraviolet irradiation, microwave treatment, chemical disinfectants, and thermal treatment. Finally, we proposed key challenges in current research and future directions. This review would provide reference for pathogen risk control and for enhancing the safety of solid waste management.

Key words: solid waste, pathogen, dissemination risk, inactivation technology

苏漓娅, 沈东升, 丁贺宁, 龙於洋, 惠彩. 常见固体废弃物处理处置过程中病原菌的赋存、传播与灭活技术[J]. 应用生态学报, 2025, 36(8): 2571-2582.

SU Liya, SHEN Dongsheng, DING Hening, LONG Yuyang, HUI Cai. Occurrence, dissemination, and inactivation technologies of pathogens in the process of common solid waste treatment and disposal[J]. Chinese Journal of Applied Ecology, 2025, 36(8): 2571-2582.

参考文献

[1] Cai M, Guy C, Héroux M, et al. The impact of successive covid-19 lockdowns on people mobility, lockdown efficiency, and municipal solid waste. Environmental Chemistry Letters, 2021, 19: 3959-3965
[2] 国家统计局. 中国统计年鉴2024. 北京: 中国统计出版社, 2024: 8-18
[3] Chen DMC, Bodirsky BL, Krueger T, et al. The world’s growing municipal solid waste: Trends and impacts. Environmental Research Letters, 2020, 15: 074021
[4] Soltanian S, Kalogirou SA, Ranjbari M, et al. Exergetic sustainability analysis of municipal solid waste treatment systems: A systematic critical review. Renewable and Sustainable Energy Reviews, 2022, 156: 111975
[5] 纪岩峰. 医疗废物处理处置过程中的环境风险问题研究. 黑龙江环境通报, 2023, 36(9): 17-19
[6] Soobhany N, Mohee R, Garg VK. Inactivation of bacterial pathogenic load in compost against vermicompost of organic solid waste aiming to achieve sanitation goals: A review. Waste Management, 2017, 64: 51-62
[7] Li M, Song G, Liu R, et al. Inactivation and risk control of pathogenic microorganisms in municipal sludge treatment: A review. Frontiers of Environmental Science & Engineering, 2022, 16: 70
[8] Anand U, Li X, Sunita K, et al. SARS-cov-2 and other pathogens in municipal wastewater, landfill leachate, and solid waste: A review about virus surveillance, infectivity, and inactivation. Environmental Research, 2022, 203: 111839
[9] Song LY, Yang S, Gong ZR, et al. Antibiotics and antibiotic-resistant genes in municipal solid waste landfills: Current situation and perspective. Current Opinion in Environmental Science & Health, 2023, 31: 100421
[10] Lin WF, Guo HQ, Zhu LJ, et al. Temporal variation of antibiotic resistome and pathogens in food waste during short-term storage. Journal of Hazardous Materials, 2022, 436: 129261
[11] Li XN, Wang PL, Chu SQ, et al. The variation of antibiotic resistance genes and their links with microbial communities during full-scale food waste leachate biotreatment processes. Journal of Hazardous Materials, 2021, 416: 125744
[12] Tang W, Yuan X, Chen Z, et al. Microbial characteristics of domestic waste in a typical residential community of Shanghai. Journal of Environmental and Occupational Medicine, 2022, 39: 1102-1109
[13] Liu YQ, Li S, Zheng ZL, et al. Microbial diversity and potential health risks of household municipal solid waste in China: A case study in winter during outbreak of Covid-19. Science of the Total Environment, 2023, 904: 166672
[14] Shen DS, Yu Q, Xing XJ, et al. Distribution and survival of pathogens from different waste components and bioaerosol traceability analysis in household garbage room. Environmental Research, 2024, 252: 119016
[15] Aggarwal R, Mahajan P, Pandiya S, et al. Antibiotic resistance: A global crisis, problems and solutions. Critical Reviews in Microbiology, 2024, 50: 1-26
[16] Poulsen OM, Breum NO, Ebbehøj N, et al. Sorting and recycling of domestic waste: Review of occupational health problems and their possible causes. Science of the Total Environment, 1995, 168: 33-56
[17] 于子旋, 杨静静, 王语嫣, 等. 畜禽粪便堆肥的理化腐熟指标及其红外光谱. 应用生态学报, 2016, 27(6): 2015-2023
[18] 付强, 王敬茹, 宋海燕, 等. 畜禽粪污主要污染物处理技术研究进展. 山东畜牧兽医, 2024, 45(2): 79-82
[19] Zhu L, Lian Y, Lin D, et al. Insights into microbial contamination in multi-type manure-amended soils: The profile of human bacterial pathogens, virulence factor genes and antibiotic resistance genes. Journal of Hazar-dous Materials, 2022, 437: 129356
[20] Li WJ, Li HZ, An XL, et al. Effects of manure fertilization on human pathogens in endosphere of three vege-table plants. Environmental Pollution, 2022, 314: 120344
[21] Mawdsley JL, Bardgett RD, Merry RJ, et al. Pathogens in livestock waste, their potential for movement through soil and environmental pollution. Applied Soil Ecology, 1995, 2: 1-15
[22] Mccarthy G, Lawlor PG, Gutierrez M, et al. An assessment of salmonella survival in pig manure and its separated solid and liquid fractions during storage. Journal of Environmental Science and Health Part B, 2015, 50: 135-145
[23] Xu H, Chen ZY, Huang RY, et al. Antibiotic resistance gene-carrying plasmid spreads into the plant endophytic bacteria using soil bacteria as carriers. Environmental Science & Technology, 2021, 55: 10462-10470
[24] Ambreetha S, Marimuthu P, Mathee K, et al. Rhizospheric and endophytic pseudomonas aeruginosa in edible vegetable plants share molecular and metabolic traits with clinical isolates. Journal of Applied Microbiology, 2022, 132: 3226-3248
[25] Du W, Wang F, Fang SY, et al. Antimicrobial PCMX facilitates the volatile fatty acids production during sludge anaerobic fermentation: Insights of the interactive principles, microbial metabolic profiles and adaptation mechanisms. Chemical Engineering Journal, 2022, 446: 137339
[26] Wu LW, Ning DL, Zhang B, et al. Global diversity and biogeography of bacterial communities in wastewater treatment plants. Nature Microbiology, 2019, 4: 1183-1195
[27] Yang T, Jiang L, Bi XJ, et al. Submicron aerosols share potential pathogens and antibiotic resistomes with wastewater or sludge. Science of the Total Environment, 2022, 821: 153521
[28] Cuetero-Martínez Y, Flores-Ramírez A, De Los Cobos-Vasconcelos D, et al. Removal of bacterial pathogens and antibiotic resistance bacteria by anaerobic sludge digestion with thermal hydrolysis pre-treatment and alkaline stabilization post-treatment. Chemosphere, 2023, 313: 137383
[29] Gholipour S, Ghalhari MR, Nikaeen M, et al. Occurrence of viruses in sewage sludge: A systematic review. Science of the Total Environment, 2022, 824: 153886
[30] Otawa K, Lee SH, Yamazoe A, et al. Abundance, diversity, and dynamics of viruses on microorganisms in activated sludge processes. Microbial Ecology, 2007, 53: 143-152
[31] Pietronave S, Fracchia L, Rinaldi M, et al. Influence of biotic and abiotic factors on human pathogens in a fini-shed compost. Water Research, 2004, 38: 1963-1970
[32] Xu PC, Zhang CM, Mou X, et al. Bioaerosol in a typical municipal wastewater treatment plant: Concentration, size distribution, and health risk assessment. Water Science and Technology, 2020, 82: 1547-1559
[33] Yan C, Wang RN, Zhao XY. Emission characteristics of bioaerosol and quantitative microbiological risk assessment for equipping individuals with various personal protective equipment in a WWTP. Chemosphere, 2021, 265: 129117
[34] Wan S, Xia M, Tao J, et al. Metagenomics analysis reveals the microbial communities, antimicrobial resis-tance gene diversity and potential pathogen transmission risk of two different landfills in China. Diversity, 2021, 13: 230
[35] Hui C, Yu Q, Liu B, et al. Microbial contamination risk of landfilled waste with different ARGs. Waste Mana-gement, 2023, 170: 297-307
[36] Fraczek K, Ropek DR, Kozdroj J. Spatial distribution of salmonella in soil near municipal waste landfill site. Agriculture, 2022, 12: 1933
[37] Wu XX, Shen DS, Hui C, et al. Evaluation of pathogen spread risk from excavated landfill. Environmental Pollution, 2024, 349: 123993
[38] Madhwal S, Prabhu V, Sundriyal S, et al. Distribution, characterization and health risk assessment of size fractionated bioaerosols at an open landfill site in Dehradun, India. Atmospheric Pollution Research, 2020, 11: 156-169
[39] Anand U, Li X, Sunita K, et al. SARS-cov-2 and other pathogens in municipal wastewater, landfill leachate, and solid waste: A review about virus surveillance, infectivity, and inactivation. Environmental Research, 2022, 203: 111839
[40] Shen WT, Zhang HH, Li XJ, et al. Pathogens and antibiotic resistance genes during the landfill leachate treatment process: Occurrence, fate, and impact on groundwater. Science of the Total Environment, 2023, 903: 165925
[41] Gong ZR, Yang S, Zhang R, et al. Physiochemical and biological characteristics of fouling on landfill leachate treatment systems surface. Journal of Environmental Sciences, 2024, 135: 59-71
[42] Wu D, Wang LH, Su YL, et al. Associations between human bacterial pathogens and ARGs are magnified in leachates as landfill ages. Chemosphere, 2021, 264: 128446
[43] Wu D, Huang XH, Sun JZ, et al. Antibiotic resistance genes and associated microbial community conditions in aging landfill systems. Environmental Science & Technology, 2017, 51: 12859-12867
[44] Zhao RX, Feng J, Yin XL, et al. Antibiotic resistome in landfill leachate from different cities of China deciphered by metagenomic analysis. Water Research, 2018, 134: 126-139
[45] Liu LM, Hang YX, Chen HY, et al. Fate of resistome components and characteristics of microbial communities in constructed wetlands and their receiving river. Science of the Total Environment, 2022, 844: 157226
[46] 张令昕. 好氧堆肥过程中杂草种子和病原菌的灭活效果及参数研究. 硕士论文. 南京: 南京农业大学, 2021
[47] Jiang X, Morgan J, Doyle MP. Fate of Escherichia coli O157:H7 during composting of bovine manure in a laboratory-scale bioreactor. Journal of Food Protection, 2003, 66: 25-30
[48] Lepesteur M. Human and livestock pathogens and their control during composting. Critical Reviews in Environmental Science and Technology, 2022, 52: 1639-1683
[49] Pajura R. Composting municipal solid waste and animal manure in response to the current fertilizer crisis: A recent review. Science of the Total Environment, 2024, 912: 169221
[50] Grewal S, Sreevatsan S, Michel FC. Persistence of Lis-teria and Salmonella during swine manure treatment. Compost Science & Utilization, 2007, 15: 53-62
[51] Stringfellow K, Caldwell D, Lee J, et al. Pasteurization of chicken litter with steam and quicklime to reduce Salmonella typhimurium. Journal of Applied Poultry Research, 2010, 19: 380-386
[52] Erickson MC, Liao J, Ma L, et al. Inactivation of Salmonella spp. in cow manure composts formulated to different initial C:N ratios. Bioresource Technology, 2009, 100: 5898-5903
[53] Ferguson RMW, Neath CEE, Nasir ZA, et al. Size fractionation of bioaerosol emissions from green-waste composting. Environment International, 2021, 147: 106327
[54] Mao YQ, Akdeniz N, Nguyen TH. Quantification of pathogens and antibiotic resistance genes in backyard and commercial composts. Science of the Total Environment, 2021, 797: 149197
[55] He BC, Li W, Huang CH, et al. The environmental risk of antibiotic resistance genes from manure compost ferti-lizer gradually diminished during ryegrass planting. Chemical Engineering Journal, 2023, 466: 143143
[56] Jiang Y, Xie SH, Dennehy C, et al. Inactivation of pathogens in anaerobic digestion systems for converting biowastes to bioenergy: A review. Renewable and Sustainable Energy Reviews, 2020, 120: 109654
[57] Jiang Y, Dennehy C, Lawlor PG, et al. Inactivation of enteric indicator bacteria and system stability during dry co-digestion of food waste and pig manure. Science of the Total Environment, 2018, 612: 293-302
[58] Jang HM, Kan E. Enhanced removal of antibiotic resis-tance genes and human bacterial pathogens during anaerobic digestion of dairy manure via addition of manure biochar. Chemosphere, 2022, 304: 135178
[59] Liu H, Li X, Zhang ZH, et al. Semi-continuous anaerobic digestion of secondary sludge with free ammonia pretreatment: Focusing on volatile solids destruction, dewaterability, pathogen removal and its implications. Water Research, 2021, 202: 117481
[60] Zhao Q, Liu Y. Is anaerobic digestion a reliable barrier for deactivation of pathogens in biosludge? Science of the Total Environment, 2019, 668: 893-902
[61] Serra-Compte A, González S, Arnaldos M, et al. Elimination of SARS-CoV-2 along wastewater and sludge treatment processes. Water Research, 2021, 202: 117435
[62] Zahmatkesh S, Amesho KTT, Sillanpää M. A critical review on diverse technologies for advanced wastewater treatment during SARS-CoV-2 pandemic: What do we know? Journal of Hazardous Materials Advances, 2022, 7: 100121
[63] Hossain MF. Ultraviolet germicidal irradiation (UVGI) application in building design to terminate pathogens naturally. Materials Today Sustainability, 2022, 19: 100161
[64] Szeto W, Yam WC, Huang H, et al. The efficacy of vacuum-ultraviolet light disinfection of some common environmental pathogens. BMC Infectious Diseases, 2020, 20: 127
[65] Liu X, Tang R, Li HQ, et al. The physiological and ecological properties of bacterial persisters discovered from municipal sewage sludge and the potential risk. Environmental Research, 2022, 205: 112481
[66] Zhang SH, Ye CS, Lin HR, et al. UV disinfection induces a VBNC state in Escherichia coli and pseudomonas aeruginosa. Environmental Science & Techno-logy, 2015, 49: 1721-1728
[67] Wang LP, Ye CS, Guo LZ, et al. Assessment of the UV/chlorine process in the disinfection of Pseudomonas aeruginosa: Efficiency and mechanism. Environmental Science & Technology, 2021, 55: 9221-9230
[68] Zhang Y, Yan T, Xu ZW, et al. Experimental study on the microwave radiation disinfection of E. coli on sic composite filter. Environmental Research, 2023, 235: 116659
[69] Mendes-Oliveira G, Deering AJ, San Martin-Gonzalez MF, et al. Microwave pasteurization of apple juice: Modeling the inactivation of Escherichia coli O157:H7 and Salmonella typhimurium at 80-90 ℃. Food Micro-biology, 2020, 87: 103382
[70] Kang SY, Cho ER, Kang DH. Inactivation of foodborne pathogens in ground pork tenderloin using 915 MHz microwave heating depending on power level. Food Research International, 2023, 173: 113231
[71] Cho WI, Chung MS. Improving the quality of vegetable foodstuffs by microwave inactivation. Food Science and Biotechnology, 2020, 29: 85-91
[72] Song WJ, Kang DH. Influence of water activity on inactivation of Escherichia coli O157:H7, Salmonella typhimurium and Listeria monocytogenes in peanut butter by microwave heating. Food Microbiology, 2016, 60: 104-111
[73] Tong J, Liu JB, Zheng X, et al. Fate of antibiotic resistance bacteria and genes during enhanced anaerobic digestion of sewage sludge by microwave pretreatment. Bioresource Technology, 2016, 217: 37-43
[74] Zhang Z, Wang JH, Hu YH, et al. Microwaves, a potential treatment for bacteria: A review. Frontiers in Microbiology, 2022, 13: 256-268
[75] Huang WX, Li Y, Wang F, et al. Disinfectant sodium dichloroisocyanurate synergistically strengthened sludge acidogenic process and pathogens inactivation: Targeted upregulation of functional microorganisms and metabolic traits via self-adaptation. Water Research, 2023, 247: 120787
[76] Vlaskin MS. Review of air disinfection approaches and proposal for thermal inactivation of airborne viruses as a life-style and an instrument to fight pandemics. Applied Thermal Engineering, 2022, 202: 117855
[77] Mccarton L, Ohogain S. Thermal inactivation analysis of water-related pathogens in domestic hot water systems. Journal of Environmental Engineering and Science, 2017, 12: 34-41
[78] Lin M, Ren LJ, Wandera SM, et al. Enhancing pathogen inactivation in pig manure by introducing thermophilic and hyperthermophilic hygienization in a two-stage anaerobic digestion process. Waste Management, 2022, 144: 123-131
[79] Wang HY, Chen Z, Li MZ, et al. Testing a nonpathogenic surrogate microorganism for validating desiccation-adapted salmonella inactivation in physically heat-treated broiler litter. Journal of Food Protection, 2018, 81: 1418-1424