Challenges of pathogen inactivation in animal manure through anaerobic digestion: a short review

Anaerobic digestion is one of the best ways to re-use animal manure and agricultural residues, through the production of combustible biogas and digestate. However, the use of antibiotics for preventing and treating animal diseases and, consequently, their residual concentrations in manure, could introduce them into anaerobic digesters. If the digestate is applied as a soil fertilizer, antibiotic residues and/or their corresponding antibiotic resistance genes (ARGs) could reach soil ecosystems. This work investigated three common soil emerging contaminants, i.e., sulfamethoxazole (SMX), ciprofloxacin (CIP), enrofloxacin (ENR), their ARGs sul1, sul2, qnrS, qepA, aac-(6′)-Ib-cr and the mobile genetic element intI1, for one year in a full scale anaerobic plant. Six samplings were performed in line with the 45-day hydraulic retention time (HRT) of the anaerobic plant, by collecting input and output samples. The overall results show both antibiotics and ARGs decreased during the anaerobic digestion process. In particular, SMX was degraded by up to 100%, ENR up to 84% and CIP up to 92%, depending on the sampling time. In a similar way, all ARGs declined significantly (up to 80%) in the digestate samples. This work shows how anaerobic digestion can be a promising practice for lowering antibiotic residues and ARGs in soil.

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Net energy production associated with pathogen inactivation during mesophilic and thermophilic anaerobic digestion of sewage sludge

Water Research ◽

10.1016/j.watres.2011.06.014 ◽

2011 ◽

Vol 45 (16) ◽

pp. 4758-4768 ◽

Cited By ~ 32

Author(s):

Christopher Ziemba ◽

Jordan Peccia

Keyword(s):

Anaerobic Digestion ◽

Sewage Sludge ◽

Energy Production ◽

Net Energy ◽

Pathogen Inactivation ◽

Thermophilic Anaerobic Digestion

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Co-digestion of microbial biomass with animal manure in three-stage anaerobic digestion

Fuel ◽

10.1016/j.fuel.2021.121746 ◽

2021 ◽

Vol 306 ◽

pp. 121746

Author(s):

Fuad Ameen ◽

J. Ranjitha ◽

Nazmul Ahsan ◽

Vijayalakshmi Shankar

Keyword(s):

Anaerobic Digestion ◽

Microbial Biomass ◽

Animal Manure

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Acclimatization of a mixed-animal manure inoculum to the anaerobic digestion of Axonopus compressus reveals the putative importance of Mesotoga infera and Methanosaeta concilii as elucidated by DGGE and Illumina MiSeq

Bioresource Technology ◽

10.1016/j.biortech.2017.08.123 ◽

2017 ◽

Vol 245 ◽

pp. 1148-1154 ◽

Cited By ~ 15

Author(s):

Jonathan T.E. Lee ◽

Jianzhong He ◽

Yen Wah Tong

Keyword(s):

Anaerobic Digestion ◽

Illumina Miseq ◽

Animal Manure ◽

Methanosaeta Concilii

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Methane emission during on-site pre-storage of animal manure prior to anaerobic digestion at biogas plant: Effect of storage temperature and addition of food waste

Journal of Environmental Management ◽

10.1016/j.jenvman.2018.07.079 ◽

2018 ◽

Vol 225 ◽

pp. 272-279 ◽

Cited By ~ 6

Author(s):

Lu Feng ◽

Alastair James Ward ◽

Veronica Moset ◽

Henrik Bjarne Møller

Keyword(s):

Anaerobic Digestion ◽

Food Waste ◽

Methane Emission ◽

Storage Temperature ◽

Animal Manure ◽

Biogas Plant ◽

Plant Effect

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Waste to Energy: A Focus on the Impact of Substrate Type in Biogas Production

Processes ◽

10.3390/pr8101224 ◽

2020 ◽

Vol 8 (10) ◽

pp. 1224

Author(s):

Nwabunwanne Nwokolo ◽

Patrick Mukumba ◽

KeChrist Obileke ◽

Matthew Enebe

Keyword(s):

Anaerobic Digestion ◽

Municipal Solid Waste ◽

Solid Waste ◽

Industrial Waste ◽

Animal Manure ◽

Nutritional Composition ◽

Organic Wastes ◽

Waste To Energy ◽

Methane Yield ◽

Substrate Type

Anaerobic digestion is an efficient technology for a sustainable conversion of various organic wastes such as animal manure, municipal solid waste, agricultural residues and industrial waste into biogas. This technology offers a unique set of benefits, some of which include a good waste management technique, enhancement in the ecology of rural areas, improvement in health through a decrease of pathogens and optimization of the energy consumption of communities. The biogas produced through anaerobic digestion varies in composition, but it consists mainly of carbon dioxide methane together with a low quantity of trace gases. The variation in biogas composition are dependent on some factors namely the substrate type being digested, pH, operating temperature, organic loading rate, hydraulic retention time and digester design. However, the type of substrate used is of greater interest due to the direct dependency of microorganism activities on the nutritional composition of the substrate. Therefore, the aim of this review study is to provide a detailed analysis of the various types of organic wastes that have been used as a substrate for the sustainable production of biogas. Biogas formation from various substrates reported in the literature were investigated, an analysis and characterization of these substrates provided the pro and cons associated with each substrate. The findings obtained showed that the methane yield for all animal manure varied from 157 to 500 mL/gVS with goat and pig manure superseding the other animal manure whereas lignocellulose biomass varied from 160 to 212 mL/gVS. In addition, organic municipal solid waste and industrial waste showed methane yield in the ranges of 143–516 mL/gVS and 25–429 mL/gVS respectively. These variations in methane yield are primarily attributed to the nutritional composition of the various substrates.

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Pretreatment of Animal Manure Biomass to Improve Biogas Production: A Review

Energies ◽

10.3390/en13143573 ◽

2020 ◽

Vol 13 (14) ◽

pp. 3573 ◽

Cited By ~ 3

Author(s):

Meneses-Quelal Orlando ◽

Velázquez-Martí Borja

Keyword(s):

Anaerobic Digestion ◽

Methane Production ◽

Biogas Production ◽

Poultry Manure ◽

Animal Manure ◽

Methane Yield ◽

Operational Parameters ◽

Advantages And Disadvantages ◽

Physical Chemical ◽

Chemical Pretreatments

The objective of this research is to present a review of the current technologies and pretreatments used in the fermentation of cow, pig and poultry manure. Pretreatment techniques were classified into physical, chemical, physicochemical, and biological groups. Various aspects of these different pretreatment approaches are discussed in this review. The advantages and disadvantages of its applicability are highlighted since the effects of pretreatments are complex and generally depend on the characteristics of the animal manure and the operational parameters. Biological pretreatments were shown to improve methane production from animal manure by 74%, chemical pretreatments by 45%, heat pretreatments by 41% and physical pretreatments by 30%. In general, pretreatments improve anaerobic digestion of the lignocellulosic content of animal manure and, therefore, increase methane yield.

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Degradation of Plastics under Anaerobic Conditions: A Short Review

Polymers ◽

10.3390/polym12010109 ◽

2020 ◽

Vol 12 (1) ◽

pp. 109 ◽

Cited By ~ 9

Author(s):

Xochitl Quecholac-Piña ◽

María del Consuelo Hernández-Berriel ◽

María del Consuelo Mañón-Salas ◽

Rosa María Espinosa-Valdemar ◽

Alethia Vázquez-Morillas

Keyword(s):

Anaerobic Digestion ◽

Short Review ◽

Anaerobic Conditions ◽

Experimental Conditions ◽

Biodegradation Process ◽

Thermophilic Conditions ◽

Global Concern ◽

Useful Life ◽

Life Options ◽

Temperature Water

Plastic waste is an issue of global concern because of the environmental impact of its accumulation in waste management systems and ecosystems. Biodegradability was proposed as a solution to overcome this problem; however, most biodegradable plastics were designed to degrade under aerobic conditions, ideally fulfilled in a composting plant. These new plastics could arrive to anaerobic environments, purposely or frequently, because of their mismanagement at the end of their useful life. This review analyzes the behavior of biodegradable and conventional plastics under anaerobic conditions, specifically in anaerobic digestion systems and landfills. A review was performed in order to identify: (a) the environmental conditions found in anaerobic digestion processes and landfills, as well as the mechanisms for degradation in those environments; (b) the experimental methods used for the assessment of biodegradation in anaerobic conditions; and (c) the extent of the biodegradation process for different plastics. Results show a remarkable variability of the biodegradation rate depending on the type of plastic and experimental conditions, with clearly better performance in anaerobic digestion systems, where temperature, water content, and inoculum are strictly controlled. The majority of the studied plastics showed that thermophilic conditions increase degradation. It should not be assumed that plastics designed to be degraded aerobically will biodegrade under anaerobic conditions, and an exact match must be done between the specific plastics and the end of life options that they will face.

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