Comparison on nitrosation and anaerobic ammonium oxidation between activated sludge and biofilm from an autotrophic nitrogen removal SBBR

Qin, Yu; Guo, Jinsong; Fang, Fang; Qin, Yu; Guo, Jinsong; Fang, Fang

doi:10.24850/j-tyca-2017-02-13

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Tecnología y ciencias del agua

versión On-line ISSN 2007-2422

Tecnol. cienc. agua vol.8 no.2 Jiutepec mar./abr. 2017

https://doi.org/10.24850/j-tyca-2017-02-13

Artículos técnicos

Comparison on nitrosation and anaerobic ammonium oxidation between activated sludge and biofilm from an autotrophic nitrogen removal SBBR

Comparación de la nitrosación y la oxidación anaerobia de amonio entre lodo activado y biopelícula de un reactor biológico secuencial por lotes para la remoción autotrófica de nitrógeno

Yu Qin¹^*

Jinsong Guo²

Fang Fang²

^¹ Chongqing Jiaotong University, China

^² Chongqing University, China

Abstract:

Activated sludge and biofilm from a Sequencing Biofilm Batch Reactor (SBBR) were studied to analyze their different roles in autotrophic nitrogen removal process. Results showed that under aerobic conditions, the ammonia oxidation rate of activated sludge was 100% and the maximum rate was 0.23 mgN mgVSS⁻¹ d⁻¹ during a 48 h test cycle. Under the same conditions, the ammonia oxidation rate of the biofilm was 72% and the maximum rate was 0.08 mgN mgVSS⁻¹ d⁻¹. The population of AOB (ammonium oxidizing bacteria) in activated sludge was 1.88×10¹¹ cells/g, 10 times that in biofilm. The TN (total nitrogen) removal rate of activated sludge and biofilm under anaerobic conditions were 37% and 83%, respectively. The rate of anaerobic ammonium oxidation by activated sludge was 0.09 mgN mgVSS⁻¹ d⁻¹and that of biofilm was 0.22 mgN mgVSS⁻¹ d⁻¹. ANAMMOX (anaerobic ammonium oxidizing bacteria) were the dominant bacteria in terms of cell number in this system, with 2.66×10¹² cells/g in biofilm—2.6 times more than in activated sludge. TN was removed mainly by anaerobic ammonium oxidation.

Keywords: Autotrophic nitrogen removal; biofilm; activated sludge; AOB; ANAMMOX

Resumen:

Se estudió el lodo activado y la biopelícula de un reactor biológico secuencial por lotes (SBBR) para analizar sus diferentes papeles en el proceso de remoción autotrófica de nitrógeno. Los resultados muestran que bajo condiciones aerobias, la velocidad de oxidación del amoníaco del lodo activado fue del 100% y la velocidad máxima fue de 0.23 mgN mgVSS⁻¹ d⁻¹ durante un ciclo de pruebas de 48 horas. Bajo las mismas condiciones, la velocidad de oxidación del amoníaco de la biopelícula fue de 72% y la velocidad máxima fue de 0.08 mgN mgVSS⁻¹ d⁻¹. La población de BOA (bacterias oxidantes del amonio) en el lodo activado fue de 1.88×10¹¹ células/g, diez veces más que en la biopelícula. La tasa de remoción del NT (nitrógeno total) del lodo activado y de la biopelícula bajo condiciones anaerobias fue del 37 y 83%, respectivamente. La velocidad de oxidación anaerobia del amonio por el lodo activado fue de 0.09 mgN mgVSS⁻¹ d⁻¹y la de la biopelícula fue de 0.22 mgN mgVSS⁻¹ d⁻¹. Las bacterias anaerobias oxidantes de amonio (ANAMMOX) fueron las bacterias dominantes en términos del número de células en este sistema, con 2.66×10¹² células/g en la biopelícula — 2.6 veces más que en el lodo activado. El NT fue removido principalmente mediante la oxidación anaerobia del amonio.

Palabras clave: remoción autotrófica de nitrógeno; biopelícula; lodo activado; BOA; ANAMMOX

Introduction

Traditional nitrogen removal biotechnologies take a long process. But some researchers show that autotrophic denitrification can be performed by a Sequence Batch Biofilm Reactor (SBBR). Because this is done in a single reactor, rapidly, and using simple techniques, it has become a subject of great interest in the field of biological nitrogen removal (^{Ahn, 2006}; ^{Jetten et al., 2005}). The prevailing view holds that the main functional bacteria in this process are ammonia oxidizing bacteria (AOB), nitrite oxidizing bacteria (NOB) and anaerobic ammonium oxidizing bacteria (ANAMMOX) (^{Dong & Tollner, 2003}; ^{Sliekers et al., 2002}; ^{Third, Sliekers, Kuenen, & Jetten, 2001}). Ammonium is partially oxidized by AOB to nitrite, which is subsequently consumed by ANAMMOX together with the remaining ammonium. However, AOB and NOB are aerobic bacteria while ANAMMOX are obligate anaerobes, which do not tolerate dissolved oxygen (DO) (^{Strousm, Vanger, Kuenen, & Jetten, 1997}). Therefore, the key to one-step autotrophic denitrification in a single reactor is to balance the supply and demand of dissolved oxygen (^{Qin, Guo, Fang, & Yang, 2009}; ^{Hippen, Rosenwinkel, Baumgarten, & Seyfried, 1997}; ^{Galluzzo, Ducato, Bartolozzi, & Picciotto, 2001}) and how to make them coexist in one reactor.

In this study, autotrophic nitrogen removal was conducted in an SBBR (^{Guo, Qin, Fang, & Yang, 2008}). Previous research has shown that autotrophic nitrogen removal process has been set up and microbial community structure exerts significant influence on the performance of this system (^{Fang, Qin, Guo, Jia, & Yang, 2010}). Microbes are at the core of the reactor, and the denitrification effect of activated sludge and bio-film is directly determined by the composition of the microbial community. This is a comparative study of activated sludge and biofilm in an SBBR, with quantitative analysis of functional bacterial populations as well as nitrogen transfer pathways. This study is to analyze the different roles between activated sludge and biofilm in autotrophic nitrogen process.

Materials and methods

Experimental apparatus

A schematic view of the SBBR autotrophic denitrification reactor is shown in figure 1. The reactor was filled with hollow balls fillers and soft combination packing. Under the condition of 30 °C and pH of 8.0, artificial synthetic ammonia nitrogen wastewater was added in. The concentration of NH₄HCO₃ was 160 mg/l without organic carbon sources. According to the optimal operation condition about 2h: 2h aeration/non-aeration ratio and DO 2.0 (aeration) mg/l /0.4 (non-aeration) mg/l, after half year domestication, autotrophic nitrogen removal system was set up successfully. TN removal rate reached to 80% while ammonia conversion rate reached to 100%.

Figure 1 Schematic representation of the reactor and workflow. 1. Wastewater tank; 2. SBBR reactor; 3. Air pump; 4. Calorstat; 5. Aerating stick; 6. Stirrer; 7. Effluent tank.

Nitrosation and anaerobic ammonium oxidation were tested separately in both activated sludge and biofilm samples in the SBBR. Other tests were done in conical flasks (figure 2), which were sealed with rubber plugs to maintain a stable DO concentration. Artificial wastewaters with different NH₄⁺-N or NO₂^--N concentrations were added.

Figure 2 Schematic representation of the flask-shaking experiment. 1. Incubator; 2. Conical flask; 3. Aeration tube; 4. Exhaust tube; 5. Sampling tube.

Experimental apparatus

(1) Quantitative analysis of functional bacteria

DNA was extracted using a Shanghai Biocolors BioScience and Technology Company K717 environment genomic DNA extraction kit. Quantitative real-time PCR was carried out using SYBR Green Real-time PCR Master Mix Kit (Bio-Rad) in an iCycler IQ® Multiplex Real-Time PCR DNA System (Bio-Rad). A melting curve analysis was performed for each sample after PCR amplification to ensure that a single product with the expected melting curve characteristics had been obtained. The recombinant plasmid vectors were constructed by standard procedures.

Table 1 Primers and parameters used in real-time PCR.

(2) Nitrosation rate

Activated sludge and biofilm samples were taken from an SBBR which was performing effective and stable autotrophic nitrogen removal. The samples were diluted with distilled water and then inoculated into two 250 ml flasks, into which had already been added 100 ml of artificial wastewater. The initial concentration of NH₄HCO₃ was 70 mg/l, and pH was adjusted to 8.0 (± 0.2) by the addition of NaHCO₃. The nutrient solution with trace elements such as Fe, Mg was also added (EDTA 5.0 g/l, CoCl₂·6H₂O 1.6 g/l, ZnSO₄·7H₂O 2.2 g/l, MnCl₂·4H₂O 5.1 g/l, CuSO₄·5H₂O 1.6 g/l (NH₄)₆Mo₇O₂₄·4H₂O 1.1 g/l, CaCl₂·2H₂O 5.5 g/l, FeSO₄·7H₂O 5.0 g/l). The flasks were maintained at a temperature of 30 °C using a heated magnetic stirrer. DO concentration was controlled to 2.0 mg/l by aerating with a mixture of O₂ and Ar. The flasks were placed in a constant temperature shaking reactor at 30 °C and shaken at 150 revs/min.

Concentrations of NH₄⁺, NO₂^-, NO₃^- and TN were measured at intervals during each 48 h test to obtain concentration curves. The maximum reaction rate Vmax was calculated from the maximum slope of each concentration curve. At the end of each test, activated sludge or biofilm samples were taken out of the flask by brushing with a sterile brush and rinsing with distilled water, and volatile suspended solids (VSS) were measured:

(3) Anaerobic ammonium oxidation rate

The experimental procedure and analysis was similar to the study of nitrosation rate, except for the components of artificial wastewater and DO concentration. NH₄HCO₃ and NaNO₂ concentrations in the artificial liquid were both 70 mg/l. The liquid was sparged with Ar gas for 30 min to remove DO to below the detection limit (0.01 mg/l) of an LDO^TM HQ10 dissolved oxygen meter.

Results and discussion

Identification of recombinant plasmid

The recombinant plasmids sequences were analyzed using a GenBank BLAST search. As shown in table 2, conservative regions of 16S rDNA of functional bacteria were obtained. These recombinant plasmids were suitable for quantitative analysis of AOB, NOB, and ANAMMOX in real-time PCR experiments.

Table 2 A partial result of recombinant sequence alignment with genes in GenBank.

Quantitative analysis of AOB, NOB, and ANAMMOX

Quantitative real-time PCR results are shown in table 3. The populations of the three main functional bacteria (ammonia oxidizing bacteria AOB, nitrite oxidizing bacteria NOB and anaerobic ammonium oxidizing bacteria ANAMMOX) in activated sludge and biofilm samples were significantly different. That is to say that in this autotrophic nitrogen removal system, activated sludge and biofilm contained different communities of functional bacteria. This suggests that activated sludge and biofilm play different roles in the overall nitrogen removal procedure.

Table 3 Bacterial population in different samples (cells/g VSS).

AOB

In the first step in the nitrogen removal process, ammonium was oxidized to nitrite by AOB. The population of AOB in the activated sludge sample was 1.88 × 10¹¹ cells/g, almost nine times higher than the 1.90 × 10¹⁰ cells/g found in the biofilm. AOB are typically aerobic bacteria which thrive under high DO. Activated sludge was suspended in the reactor and was in intimate contact with DO. However, poor mass transfer of DO, into the biofilm meant that the interior layer of biofilm was anaerobic or at least had low DO concentration. Therefore AOB tended to be found in activated sludge or the exterior layer of biofilm.

NOB

NOB numbers were 2 to 4 orders of magnitude less than AOB and ANAMMOX in both activated sludge and biofilm samples. NOBs were not the dominant bacteria in terms of cell number in this SBBR reactor although they multiplied faster than AOB under normal conditions (5-20 °C) (^{Hellinga, Schellen, Mulder, & Heijnen, 1998}). Other studies have also shown that at higher temperatures (> 20 °C), the degradation rate of AOB can be higher than that of NOB (^{Hellinga et al., 1998}). During the start-up period of this study, the temperature was kept around 30 °C so that NOB was depleted and AOB became be the dominant group to accomplish one-step autotrophic nitrogen removal and prevent nitrite from being oxidized to nitrate.

ANAMMOX

The population of ANAMMOX was 5.5 times that of AOB and 874 times that of NOB in activated sludge samples. These differences were more pronounced in biofilm samples, at 140 times and 3491 times, respectively. ^{Jetten et al. (2001)} reported that anaerobic ammonia oxidation was achieved only when the ANAMMOX population was higher than 10¹⁰-10¹¹ cells/ml. Therefore, although ANAMMOX cells were the most abundant one among three functional bacteria in this study, they did not dominate the metabolic functionality. AOB and NOB are an aerobic bacteria, but ANAMMOX are anaerobic and are sensitive to DO. They can not survive even at 0.5-2.0% air saturation. The low rate of mass transfer of DO in biofilm and depletion by AOB and NOB in the outer layer made the interior of the biofilm an ideal condition for ANAMMOX. As a result, the population of ANAMMOX in biofilm was 2.66 × 10¹² cells/g, which was 2.6 times that in activated sludge.

Nitrosation of activated sludge and biofilm

Transformation of nitrogen in activated sludge and biofilm samples in a cycle of nitrosation are shown in figures 3a and 3b.

Figure 3a Nitrosation by activated sludge.

Figure 3b Nitrosation by biofilm.

Figure 3a shows that ammonia can be fully oxidized by activated sludge in a single 48 h cycle, with the ammonia oxidation rate reaching 100%. The maximum rate occurred between the 6 and 20 h with a maximum ammonia oxidation rate of 0.23 mgN mgVSS⁻¹ d⁻¹. 85% of the oxidized ammonia was present as NO₂^--N and 9% as NO₃^--N. There was the limited removal of TN. The activated sludge in this system showed good ammonia oxidation activity under aerobic conditions. Nitrogen transformation by biofilm during a 48 h cycle is shown in figure 3b. The ammonia oxidation rate was 72%. Compared with nitrosation by activated sludge, there was no obvious inflection point on the ammonia concentration curve with biofilm. The maximum rate of ammonia oxidation rate by biofilm was 0.08 mgN mgVSS⁻¹ d⁻¹. The nitrosation activity of activated sludge was about 2.89 times that of the biofilm. Ammonia was mainly oxidized to NO₂^--N and the maximum concentration of NO_3--N was only 4 mg/l at the end of the reaction cycle. The TN removal rate was 6.7%.

Both activated sludge and biofilm showed high nitrosation activities and there was little NO₃^--N accumulation in either system because they were acclimated to nitrosating conditions at the start of the experiment. NOB had been depleted and so most of the oxidized ammonia existed as nitrite. There were 158 times as many AOB as NOB cells in activated sludge samples while the ratio was 25 times in the biofilm sample. Accordingly, the aerobic ammonia oxidation rate of biofilm was less than that of activated sludge. This also led to a difference in nitrosation capacity between the two samples. This experiment used real-time PCR technology for bacterial quantification. Results showed that the populations of AOB were 1.88 × 10¹¹ cells/g in the activated sludge samples and 1.90 × 10¹⁰ cells/g in biofilm samples. Cell counts in the sludge sample were about ten times those in the biofilm. AOB, which were responsible for aerobic ammonia oxidization, were mainly found in activated sludge in this SBBR autotrophic nitrogen removal reactor.

Studies have shown that there might be denitrification under aerobic conditions by aerobic denitrifiers (^{Robertson & Kuenen, 1990}; ^{Chen, Xia, & Ju, 2003}; ^{Hung, Mitsuyo, & Makoto, 2005}). However, in this study, aerobic TN removal rates of activated sludge or bio-film samples were both low. After 48 h, the TN removal rates of sludge and biofilm samples were only 6.7 and 5.3% respectively. The NH₄⁺ to NO₂^- conversion rates of sludge and biofilm samples were 85 and 83%, respectively. The concentration of NO₃^- was low, with the highest concentrations seen at the end of the 48 h experiment cycle of just 6.7 and 4.0 mg/l. Little aerobic denitrification was seen in the SBBR autotrophic nitrogen removal process. ANAMMOX activity was limited by continuous aeration to maintain a DO concentration of 2.0 mg/l, but ANAMMOX which survived in the activated sludge flocs and the interior of biofilm might provide the system with some anaerobic nitrogen removal capability.

Anaerobic ammonium oxidation of activated sludge and biofilm

Figures 4a and 4b show the anaerobic ammonium oxidation activities of activated sludge and biofilm samples. Initial concentrations of NH₄⁺ and NO₂^- in the artificial wastewater were both 70 mg/l. TN concentrations in both samples declined over the 48h experimental period. TN removal rates were 37% by activated sludge and 83% by biofilm. In contrast with nitrosation activity, it was confirmed that TN was removed mainly by anaerobic ammonium oxidation in this reactor. The reaction rate of anaerobic ammonium oxidation by activated sludge was 0.09 mgN mgVSS⁻¹ d⁻¹. This was just 41% of the rate seen in biofilm, which was 0.22 mgN mgVSS⁻¹ d⁻¹.

Figure 4a Anaerobic oxidation of ammonium.

Figure 4b Anaerobic oxidation of ammonium by activated sludge by biofilm.

The concentration of NO₃^- in the activated sludge treatment varied between 15.0 and 17.4 mg/l, and in the biofilm treatment, the range was 13.8 to 18.0 mg/l, though no NO₃^--N was added to the artificial wastewater. The initial concentrations of NO₃^- in activated sludge and biofilm treatments were 15.0 and 13.8 mg/l, respectively. One possibility is that NaNO₂^- was unstable and was partially oxidized to NaNO₃, which provided the initial NO₃^-. Figures 4a and 4b show that the concentrations of NO₃^- did not vary greatly over the course of the experiments. The small fluctuations that were observed may have been caused by measurement error. ^{Van de Graaf et al. (1995)} concluded that ANAMMOX could utilize both NO₃^- and NO₂^- in the anaerobic ammonium oxidation reaction because both can function as electronic receptors to convert the remaining NH₄⁺ into N₂. When the substrate contained both NO₃^- and NO₂^-, it was the NO₂^- that acted as the main electronic receptor for ANAMMOX. In this study, the removal efficiency of TN was high and the largest consumption rates of NH₄⁺ and NO₂^-in activated sludge were 0.05 and 0.06 mgN mgVSS⁻¹ d^-1, respectively while for biofilm the values were 0.12 and 0.14 mgN mgVSS⁻¹ d⁻¹. The concentration of NO₃^-in the system was more-or-less constant, which suggests that NO₂^- was the main electronic receptor in anaerobic ammonium oxidation in this SBBR system. This was in accordance with Van de Graaf’s findings.

Conclusions

Activated sludge and biofilm played different roles in autotrophic nitrogen removal process.

Both activated sludge and biofilm samples exhibited nitrosation activity in the SBBR autotrophic denitrification system, the maximum ammonia oxidation rates of activated sludge and biofilm were 0.23 and 0.08 mgN mgVSS⁻¹ d⁻¹, respectively. The nitrosation activity of activated sludge was about 2.89 times that of the biofilm. The populations of AOB in activated sludge and biofilm were 1.88 × 10¹¹ and 1.90 × 10¹⁰ cells/g, respectively.

The maximum anaerobic ammonia oxidation rate of activated sludge was 0.09 mgN mgVSS⁻¹ d⁻¹, just 41% of the maximum rate of biofilm, which was 0.22 mgN mgVSS⁻¹d⁻¹. Anaerobic ammonia oxidation occurred mainly in the biofilm, with ANAMMOX being the dominant bacteria in this process. The populations of ANAMMOX were 1.04 × 10¹² cells/g in activated sludge and 2.66 × 10¹² cells/g.

TN removal rates of sludge and biofilm samples were just 6.7 and 5.3%, respectively, under aerobic conditions with both NO₂^- and NO₃^- present. No significant aerobic denitrification was seen in this SBBR autotrophic nitrogen removal system. TN removal in this study was performed mainly by ANAMMOX under anaerobic condition.

Acknowledgments

This work was supported by the National Natural Science Foundation Project of China (51609026).

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Received: May 24, 2016; Accepted: October 26, 2016

^* Author´s institutional address. Ph.D. Yu Qin, Chongqing Jiaotong University, Key laboratory of Hydraulic and Waterway Engineering of the Ministry of Education, Chongqing Jiaotong University, No. 66 Xuefu Road, Nanan district, Chongqing, 400074, China, Telephone: +86 (138) 8365 6798, qinyu54001@163.com. Ph.D. Jinsong Guo, Ph.D. Fang Fang, Chongqing University, Faculty of Urban Construction and Environmental Engineering, No. 174 Shazheng Road, Shapingba district, Chongqing, 400045, China, Telephone: +86 (139) 0836 1681 / (133) 2028 5392, guo0768@cqu.edu.cn; fangfangcq@cqu.edu.cn.

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