Anja Kristiansen scite author profile

Modern intensive husbandry practices can create poor indoor air quality, with high levels of airborne dust, endotoxins, ammonia, and microorganisms. Air in a sow breeding barn was investigated to determine the biomass composition of bioaerosols using molecular methods supplemented with microscopic and cultivation-dependent approaches. A total of 2.7 ± 0.7 × 10(7) bacterial cells m(-3) air and 1.2 ± 0.3 × 10(6) fungi spores m(-3) were detected, corresponding to the fungal biovolume constituted 98% of the total microbial biovolume (fungal and bacterial). Fifty-two percent of all 4',6-diamidino-2-phenyl indole-stained cells were detectable with fluorescence in situ hybridization (FISH) with a general bacterial probe mixture. Quantitative FISH of the bacterial consortium revealed Firmicutes as the dominant group with Streptococcus as the major genus, while Actinobacteria constituted 10% of the detectable bacteria. Additionally, the study revealed an abundant and diverse fungal community including species not previously found in similar environments. The most abundant fungal 18S rRNA gene clone sequences identified affiliated with the Aspergillus-Eurotium cluster, but among others, species of Wallemia, Mucorales, and Russulales were detected. For both fungi and anaerobic bacteria, a hitherto undescribed diversity was found in bioaerosols from a modern sow breeding barn, which potentially could create poor indoor air quality, although their effect on the health of farmworkers and stock still is not resolved.

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Bacterial community structure of a full-scale biofilter treating pig house exhaust air

Kristiansen

Pedersen

Nielsen

et al. 2011

Systematic and Applied Microbiology

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Butyric Acid- and Dimethyl Disulfide-Assimilating Microorganisms in a Biofilter Treating Air Emissions from a Livestock Facility

Kristiansen

Lindholst

Feilberg

et al. 2011

Appl Environ Microbiol

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Biofiltration has proven an efficient tool for the elimination of volatile organic compounds (VOCs) and ammonia from livestock facilities, thereby reducing nuisance odors and ammonia emissions to the local environment. The active microbial communities comprising these filter biofilms have not been well characterized. In this study, a trickle biofilter treating air from a pig facility was investigated and proved efficient in removing carboxylic acids (>70% reduction), mainly attributed to the primary filter section within which reduced organic sulfur compounds were also depleted (up to 50%). The secondary filter eliminated several aromatic compounds: phenol (81%), p-cresol (89%), 4-ethylphenol (68%), indole (48%), and skatole (69%). The active butyric acid degrading bacterial community of an air filter sample was identified by DNA stable-isotope probing (DNA-SIP) and microautoradiography, combined with fluorescence in situ hybridization (MAR-FISH). The predominant 16S rRNA gene sequences from a clone library derived from "heavy" DNA from [ 13 C 4 ]butyric acid incubations were Microbacterium, Gordonia, Dietzia, Rhodococcus, Propionibacterium, and Janibacter, all from the Actinobacteria. Actinobacteria were confirmed and quantified by MAR-FISH as being the major bacterial phylum assimilating butyric acid along with several Burkholderiales-related Betaproteobacteria. The active bacterial community assimilating dimethyl disulfide (DMDS) was characterized by DNA-SIP and MAR-FISH and found to be associated with the Actinobacteria, along with a few representatives of Flavobacteria and Sphingobacteria. Interestingly, ammonia-oxidizing Betaproteobacteria were also implicated in DMDS degradation, as were fungi. Thus, multiple isotope-based methods provided complementary data, enabling highresolution identification and quantitative assessments of odor-eliminating Actinobacteria-dominated populations of these biofilter environments.

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Detection and persistence of fecal Bacteroidales as water quality indicators in unchlorinated drinking water

Saunders

Kristiansen

Lund

et al. 2009

Systematic and Applied Microbiology

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Nitrifying Community Analysis in a Single Submerged Attached‐Growth Bioreactor for Treatment of High‐Ammonia Waste Stream

Gu¹,

Pedros²,

Kristiansen³

et al. 2007

Water Environment Research

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This study investigated the nitrifying community structure in a single‐stage submerged attached‐growth bioreactor (SAGB) that successfully achieved stable nitrogen removal over nitrite of a high‐strength ammonia wastewater. The reactor was operated with intermittent aeration and external carbon addition (methanol). With influent ammonia and total Kjeldahl nitrogen ranging from 537 to 968 mg/L and 643 to1510 mg/L, respectively, 85% nitrogen removal was obtained, and effluent was dominated by nitrite (NO2 −/NOx >0.95). Nitrifying community analysis using fluorescence in situ hybridization (FISH), with a hierarchical set of probes targeting known ammonia‐oxidizing bacteria (AOB) within beta‐proteobacteria, showed that the AOB community of the biofilter consists almost entirely of members of the Nitrosomonas europaea/eutropha and the Nitrosococcus mobilis lineages. Image analysis of FISH pictures was used to quantify the identified AOB, and it was estimated that Nitrosomonas europaea/eutropha‐like AOB accounted for 4.3% of the total volume of the biofilm, while Nitrosococcus mobilis‐like AOB made up 1.2%; these numbers summed up to a total AOB fraction of 5.5% of the total volume on the biofilm. Nitrite‐oxidizing bacteria (NOB) were not detectable in the biofilm samples with probes for either Nitrospira sp. or Nitrobacter sp., which indicated that NOB were either absent from the biofilters or present in numbers below the detection limit of FISH (<0.1% of the total biofilm). Nitrite oxidizers were likely outcompeted from the system because of the free ammonia inhibition and the possibility that the aeration period (from intermittent aeration) was not sufficiently long for the NOB to be released from the competition for oxygen with heterotrophs and AOB. The nitrogen removal via nitrite in a SAGB reactor described in this study is applicable for high‐ammonia‐strength wastewater treatment, such as centrate or industrial wastes.

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