Simple SummaryBeside their use to treat infections, antibiotics are used excessively as growth promoting factors in livestock industry. Animals discharge in their feces and urine between 70%–90% of the antibiotic administrated unchanged or in active metabolites. Because livestock manure is re-applied to land as a fertilizer, concerns are growing over spread of antibiotics in water and soil. Development of antibiotic resistant bacteria is a major risk. This paper reviewed the potential of anaerobic digestion to degrade antibiotics in livestock manure. Anaerobic digestion can degrade manure-laden antibiotic to various extents depending on the concentration and class of antibiotic, bioreactor operating conditions, type of feedstock and inoculum sources.AbstractDegrading antibiotics discharged in the livestock manure in a well-controlled bioprocess contributes to a more sustainable and environment-friendly livestock breeding. Although most antibiotics remain stable during manure storage, anaerobic digestion can degrade and remove them to various extents depending on the concentration and class of antibiotic, bioreactor operating conditions, type of feedstock and inoculum sources. Generally, antibiotics are degraded during composting > anaerobic digestion > manure storage > soil. Manure matrix variation influences extraction, quantification, and degradation of antibiotics, but it has not been well investigated. Fractioning of manure-laden antibiotics into liquid and solid phases and its effects on their anaerobic degradation and the contribution of abiotic (physical and chemical) versus biotic degradation mechanisms need to be quantified for various manures, antibiotics types, reactor designs and temperature of operations. More research is required to determine the kinetics of antibiotics’ metabolites degradation during anaerobic digestion. Further investigations are required to assess the degradation of antibiotics during psychrophilic anaerobic digestion.
The microbial biodiversity of bioaerosols in recently occupied hospital rooms was assessed in a pulmonology unit. Environmental samples and isolates were also screened for antibiotics resistance genes. Biofilms from sink drains were also studied to evaluate whether sink drains constitute a potential source of bioaerosols in this environment and a reservoir for opportunistic bacteria and antibiotic resistance genes. Stenotrophomonas maltophilia was by far the most frequently isolated microorganisms from the biofilm, followed by Enterobacter cloacae. Airborne bacterial concentration ranged from 14 to 74 CFU m -3 and fungi ranged from 50 to 600 CFU m -3 . Biofilm bacteria were outnumbered in aerosols by microorganisms affiliated with human skin flora. Nonetheless, they were recovered from air samples in low concentrations. Erythromycin resistance genes were detected in all air samples collected from hospital rooms, and tetracycline resistance genes were detected sporadically. Antibiotic resistance genes were found in a single drain suggesting that genes present in DNA extracts from air samples were not aerosolized from sink drains, but rather from an unknown source. Results obtained in this study suggest that bacteria from sink drains were not aerosolized in significant concentration. They still remain a concern because of the risk of aerial transmission associated with their presence.
It was previously demonstrated that microbial communities of pig manure were composed of both bacteria and archaea. Recent studies have shown that bacteria are aerosolized from pig manure, but none have ever focused on the airborne archaeal burden. We sought here to develop and apply molecular ecology approaches to thoroughly characterize airborne archaea from swine confinement buildings (SCBs). Eight swine operations were visited, twice in winter and once during summer. Institute of Occupational Medicine cassettes loaded with 25-mm gelatin filters were used to capture the inhalable microbial biomass. The total genomic DNA was extracted and used as a template for PCR amplification of the archaeal 16S rRNA gene. High concentrations of archaea were found in SCB bioaerosols, being as high as 10 8 16S rRNA gene copies per cubic meter of air. Construction and sequencing of 16S rRNA gene libraries revealed that all sequences were closely related to methanogenic archaea, such as Methanosphaera stadtmanae (94.7% of the archaeal biodiversity). Archaeal community profiles were compared by 16S rRNA gene denaturing gradient gel electrophoresis. This analysis showed similar fingerprints in each SCB and confirmed the predominance of methanogenic archaea in the bioaerosols. This study sheds new light on the nature of bioaerosols in SCBs and suggests that archaea are also aerosolized from pig manure.Over the last 30 years, swine production in Canada evolved from small family farms to industrial facilities. Pig producers have increased animal density, building mechanization, and confinement in order to decrease working and feeding time and to optimize space, leading to an increased contamination of air by bioaerosols.Even though the swine confinement building (SCB) environment has been studied for several years, little is known about the real concentration and nature of airborne microorganisms. Moreover, increasing confinement level in modern barns has raised bioaerosol levels, modifying the health risk of exposed workers. Thus far, using culture-dependent methods was the only strategy developed and used to describe SCB bioaerosol content and levels (6, 7). However, it is well known that culture-independent approaches are more likely to reveal the presence of microorganisms never suspected in most environments (2). In aerobiology, there are only a few reports using culture-independent methods (4, 15). Nehme et al. (20) applied molecular approaches to quantify and describe the bacterial aerosols in SCB and reported as much as 10 8 bacteria per cubic meter of air, with significantly higher concentrations during winter, when the confinement is maximal. The data obtained were also compared to recent biodiversity studies of swine manures (13,22,25). Anaerobic gram-positive bacteria, being the greater part of the microbiological aerosols, appeared to originate from the swine manure. Those manure biodiversity studies revealed the presence of methanogenic archaea in hog wastes (22,25). Since bacteria observed in the aerosols seem to ori...
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