Aggregate Size and Architecture Determine Microbial Activity Balance for One-Stage Partial Nitritation and Anammox

Vlaeminck, Siegfried E.; Terada, Akihiko; Smets, Barth F.; Clippeleir, Haydée De; Schaubroeck, Thomas; Bolca, Selin; Demeestere, Lien; Mast, Jan; Boon, Nico; Carballa, Marta; Verstraete, Willy

doi:10.1128/aem.02337-09

Cited by 319 publications

(156 citation statements)

References 32 publications

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“…Although there is a report that AOB associated with the N. mobilis lineage synthesize EPS in excessive amounts (39), it is unclear whether the EPS was excreted by N. mobilis or heterotrophic bacteria in the present study. Taking account of a report that EPS contributed to maintaining the structure of aggregates (1), the elasticity of EPS would support granule mechanical stability and contribute to granulation (44).…”

Section: No2mentioning

confidence: 99%

Microbial Population Dynamics and Community Structure during the Formation of Nitrifying Granules to Treat Ammonia-Rich Inorganic Wastewater

et al. 2010

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Microbial population dynamics were investigated during the formation of nitrifying granules in an aerobic upflow fluidized bed (AUFB) reactor fed ammonia as a sole energy source. Analyses of clone libraries of 16S rRNA gene and the ammonia monooxygenase subunit A gene (amoA) revealed that although the clones obtained from the seed sludge were widely distributed among the ammonia-oxidizing bacteria (AOB) isolates, the community structure of AOB shifted towards the Nitrosomonas mobilis lineage as granulation proceeded. Quantitative fluorescence in situ hybridization showed that changes in the bacterial population occurred concomitantly with changes in nitrification performance and the size of granules. AOB associated with the N. mobilis lineage were predominant in the early stages as nitrifying granules formed (average diameter, 126 µm). In mature granules (average diameter, 270 µm), at least three types of AOB, N. mobilis, Nitrosomonas oligotropha, and Nitrosomonas europaea, formed different niches and coexisted. Nitrite-oxidizing bacteria (NOB) affiliated with Nitrospira spp. were detected in the start-up period, but were replaced by NOB affiliated with Nitrobacter spp. after granules formed.Key words: community structure, population dynamics, nitrifying bacteriaThe removal of biological nitrogen from various types of wastewater is becoming increasingly important owing to the implementation of strict regulations concerning nitrogen discharge. The process of nitrification involves the conversion of ammonia (NH3) or ammonium ions (NH4. Two types of nitrifying bacteria, namely, lithoautotrophic ammonia-oxidizing bacteria (AOB) and lithoautotrophic nitrite-oxidizing bacteria (NOB), play important roles in this process. AOB are classified into two phylogenetic lineages based on their 16S rRNA gene sequences; Nitrosomonas sp. and Nitrosospira sp. belonging to Betaproteobacteria, and Nitrosococcus oceani and Nitrosococcus halophilus belonging to Gammaproteobacteria (19). NOB are mainly classified into two phylogenetic lineages based on the cell morphology of isolated organisms and on 16S rRNA gene sequences. The most intensively studied NOB, Nitrobacter and Nitrospira, fall within the Alphaproeobacteria and separate phyla in Bacteria, respectively (2).It is generally accepted that nitrifying bacteria have a low growth rate and tend to be washed out from reactors. Thus, it is difficult to retain large numbers of them within a reactor. Therefore, there is a need for a simple yet effective method of immobilizing nitrifying bacteria within a reactor. Nitrifying granule production is one method of immobilization used to preserve a large population of nitrifying bacteria within a reactor (12,(40)(41)(42)(43). Tsuneda et al. (41) produced nitrifying granules in inorganic wastewater using an aerobic upflow fluidized bed (AUFB) reactor. These granules exhibited a good settling ability and a high rate of ammonia removal (1.5 kg-N m −3 d −1 ). Therefore, nitrifying granule production is a promising method for the effective remov...

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Section: No2mentioning

confidence: 99%

Microbial Population Dynamics and Community Structure during the Formation of Nitrifying Granules to Treat Ammonia-Rich Inorganic Wastewater

et al. 2010

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“…Although the OLAND technology has been mainly used for treatment of highly nitrogenous waste streams so far, this technology can also treat low nitrogen concentrations (30-60 mg N L −1 ) at low hydraulic retention time (1-2 h) and high rates (400 mg N L −1 d −1 ) (De Clippeleir et al, in press). Besides high removal efficiencies, a high solids retention time and easy biomass retention are needed, rendering well-settling granular biomass as an appealing option (De Clippeleir et al, 2009;Vlaeminck et al, 2009a;Vlaeminck et al, 2010). Following OLAND, usable heat will be recovered with two sequential heat pumps, and this recovered energy represents about half of the fossil-fuel equivalent energy and of the CO 2 footprint advantages of ZeroWasteWater compared to CAS ( Table 2).…”

Section: Zerowastewater Technologies For End-of-pipe Treatmentmentioning

confidence: 99%

ZeroWasteWater: short-cycling of wastewater resources for sustainable cities of the future

Verstraete

Vlaeminck

2011

International Journal of Sustainable Development & World Ec

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197

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Actual sewage treatment relies on conventional activated sludge (CAS), which reaches sufficiently low carbon, nitrogen and phosphorus effluent levels, but is not cost-effective, hardly achieves recovery, requires electricity equivalent to a fossil fuel consumption of 85 kWh per inhabitant equivalent (IE) per year and has an operational CO 2 footprint of 80 kg CO 2 IE −1 year −1 . Projected water and phosphorus shortages and the need to lower greenhouse gas emissions force us to rethink wastewater treatment for sustainable cities of the future. ZeroWasteWater offers an approach to short-cycle water, energy and valuable materials while adequately abating pathogens, heavy metals and trace organics. A less diluted waste stream will be obtained from sewerage improvements, a more rational use of potable water and the addition of ground kitchen waste, complemented by an advanced physicochemical or/and biological concentration step at the entry of the sewage treatment plant. Anaerobic digestion will recover electricity from the concentrated stream and further treatment will render a value of 6.2 EUR IE −1 year −1 under the form of the nutrients nitrogen and phosphorus, and the carbon-sequestrating biochar. In the water stream, residual nitrogen will be removed through partial nitritation and anammox, followed by heat recovery and add-on membrane technologies yielding potable water (> 65 m 3 IE −1 year −1 ). Overall, compared to a CAS system without sludge digestion, the recovery of energy and nutrient in ZeroWasteWater avoids a fossil fuel use of 439 kWh IE −1 year −1 and an operational emission of 88 kg CO 2 IE −1 year −1. Interestingly, such approach is expected to be economically viable. The key challenges remain to incorporate water chain management in holistic urban planning and to render a cradle to cradle approach which society will find acceptable.

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“…distinguish between Nitrobacter and Nitrospira, as a supporting analysis for the NOB target choice in the following quantitative polymerase chain reaction (qPCR) analysis. Inoculum and endpoint samples were examined by FISH as described by Vlaeminck et al (2010). qPCR was used to quantify the abundance of AOA, AerAOB, NOB and AnAOB over time.…”

Section: Molecular Analyses Of the Microbial Communitiesmentioning

confidence: 99%

Increased salinity improves the thermotolerance of mesophilic nitrification

Courtens

Boon

Schryver

et al. 2014

Appl Microbiol Biotechnol

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Nitrification is a well-studied and established process to treat ammonia in wastewater. Although thermophilic nitrification could avoid cooling costs for the treatment of warm wastewaters, applications above 40°C remain a significant challenge. This study tested the effect of salinity on the thermotolerance of mesophilic nitrifying sludge (34°C). In batch tests, 5 g NaCl L −1 increased the activity of aerobic ammonia-oxidizing bacteria (AerAOB) by 20-21 % at 40 and 45°C. For nitrite-oxidizing bacteria (NOB), the activity remained unaltered at 40°C, yet decreased by 83 % at 45°C. In a subsequent long-term continuous reactor test, temperature was increased from 34 to 40, 42.5, 45, 47.5 and 50°C. The AerAOB activity showed 65 and 37 % higher immediate resilience in the salt reactor (7.5 g NaCl L −1) for the first two temperature transitions and lost activity from 45°C onwards. NOB activity, in contrast to the batch tests, was 37 and 21 % more resilient in the salt reactor for the first two transitions, while no difference was observed for the third temperature transition. The control reactor lost NOB activity at 47.5°C, while the salt reactor only lost activity at 50°C. Overall, this study demonstrates salt amendment as a tool for a more efficient temperature transition for mesophilic sludge (34°C) and eventually higher nitrification temperatures.

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Aggregate Size and Architecture Determine Microbial Activity Balance for One-Stage Partial Nitritation and Anammox

Cited by 319 publications

References 32 publications

Microbial Population Dynamics and Community Structure during the Formation of Nitrifying Granules to Treat Ammonia-Rich Inorganic Wastewater

Microbial Population Dynamics and Community Structure during the Formation of Nitrifying Granules to Treat Ammonia-Rich Inorganic Wastewater

ZeroWasteWater: short-cycling of wastewater resources for sustainable cities of the future

Increased salinity improves the thermotolerance of mesophilic nitrification

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