Elisabeth Müller

Aerobic biodegradation of the sulfonamide antibiotic sulfamethoxazole by activated sludge applied as co-substrate and sole carbon and nitrogen source

Potential aerobic biodegradation mechanisms of the widely used polar, low-adsorptive sulfonamide antibiotic sulfamethoxazole (SMX) were investigated in activated sludge at bench scale. The study focused on (i) SMX co-metabolism with acetate and ammonium nitrate and (ii) SMX utilization when present as the sole carbon and nitrogen source. With SMX adsorption being negligible, elimination was primarily based on biodegradation. Activated sludge was able to utilize SMX both as a carbon and/or nitrogen source. SMX biodegradation was enhanced when a readily degradable energy supply (acetate) was provided which fostered metabolic activity. Moreover, it was raised under nitrogen deficiency conditions. The mass balance for dissolved organic carbon showed an incomplete SMX mineralization with two scenarios: (i) with SMX as a co-substrate, 3-amino-5-methyl-isoxazole represented the main stable metabolite and (ii) SMX as sole carbon and nitrogen source possibly yielded hydroxyl-N-(5-methyl-1,2-oxazole-3-yl)benzene-1-sulfonamide as a further metabolite.

Detection of heavy metals in bacterial biofilms and microbial flocs with the fluorescent complexing agent Newport Green

The complexing agent Newport Green fluoresces upon binding of nickel, zinc or cobalt. It was used to detect nickel or zinc in MOPS buffer, in gel-like matrices, and in natural biofilms and microbial flocs cultivated in the laboratory. The response curves for increasing nickel concentrations indicated an equimolar binding capacity of Newport Green for nickel in MOPS buffer, whereas zinc fluorescence reached saturation in the presence of a 10-fold excess of zinc ions relative to Newport Green molecules. The maximum fluorescence intensity as determined by luminometry was 8-fold and 4-fold above background for nickel and zinc, respectively. The response of Newport Green to either nickel or zinc in the presence of the other metal is consistent with a different binding affinity of Newport Green for the two metals. Zinc binds more strongly to the complexing agent than nickel but it leads to a weaker fluorescent signal which was detectable by luminometry but not by confocal laser scanning microscopy (CLSM). Newport Green was able to complex nickel in the presence of 1% gelatin or agarose as determined by CLSM and image processing. Its application to fully hydrated bacterial biofilms or microbial flocs revealed the presence of nickel outside of cells. The results suggest that in addition to cellular sorption, metals are bound extracellularly by extracellular polymeric substances in intact and undisturbed microbial aggregates. Journal of Industrial Microbiology & Biotechnology (2000) 24, 116–123.

Population changes in a biofilm reactor for phosphorus removal as evidenced by the use of FISH

Induction of denitrification was investigated for a lab-scale phosphate removing biofilm reactor where oxygen was replaced with nitrate as the electron acceptor. Acetate was used as the carbon source. The original biofilm (acclimatised with oxygen) was taken from a well-established large-scale reactor. During the first run, a decrease in the denitrifying bio-P activity was observed after 1 month following a change in the anaerobic phase length. This was initially interpreted as a shift in the microbial population caused by the changed operation. In the second run, biomass samples were regularly collected and analysed by fluorescent in situ hybridisation (FISH) and confocal laser scanning microscopy (CLSM). Concurrently, samples were taken from the original reactor with oxygen as electron acceptor in order to investigate natural microbial fluctuations. A similar decrease in the activity as in the first run was seen after one month, although the phase lengths had not been varied. Hence, the decrease after 1 month in the first and second run should be seen as a start-up phenomenon. FISH could detect a noticeable shift in the microbial population mainly within the first 2 weeks of operation. Almost all bacteria belonging to the alpha subclass disappeared and characteristic clusters of the beta and gamma subclasses were lost. Small clusters of gram-positive bacteria with a high DNA G + C content (GPBHGC) were gradually replaced by filamentous GPBHGC. Most of the bacteria in the denitrifying, phosphate removing biofilm belonged to the beta subclass of Proteobacteria. The applied set of gene probes had been selected based on existing literature on biological phosphate removing organisms and included a recently published probe for a Rhodocyclus-like clone. However, none of the specific probes hybridised to the dominant bacterial groups in the reactors investigated. No noticeable changes were detected in the aerobic bench-scale reactor during this period, indicating that the observed changes in the lab-scale reactor were caused by the changed environment.

Influence of Particle Association and Suspended Solids on UV Inactivation of Fecal Indicator Bacteria in an Urban River

In order to assess and accurately predict the self-purification capabilities of rivers with respect to enteric pollution, a thorough understanding of mechanisms such as dispersion, particle association, and inactivation in the water column is crucial. In this study, we firstly performed particle size distribution analyses of wastewater and investigated the Escherichia coli and enterococci loadings of each size fraction. It was seen that 91 % of E. coli and 83 % of enterococci were associated with particle sizes less than or equal to 12 μm. Particles larger than 63 μm contributed less than 1 % to overall E. coli and enterococci loadings. Based on these results, batch experiments were performed to investigate the effect of particle size and total suspended solids (TSS) concentration on UV inactivation of the two fecal indicator bacteria (FIB). A direct relationship between the particle size to which FIB were associated and their UV inactivation rate was noted. E. coli and enterococci associated with particles smaller than or equal to 12 μm were inactivated on average 2 × and 1.7 × faster than those associated with the larger particle fraction of 12 to 63 μm. It was additionally seen that as the TSS concentrations increased, the UV inactivation rates decreased. A tailing effect of UV inactivation was however noted at TSS concentrations above approximately 100 mg L−1.

Scum in Activated Sludge Plants: Impact of Non‐filamentous and Filamentous Bacteria

Excessive scum production is a widespread phenomenon in present activated sludge wastewater treatment. The question how foaming is initiated and stabilized is still unanswered. Hydrophobic wastewater ingredients and surface active material such as synthetic surfactants are discussed among others as major causative agents for scum production. Focusing on biological impacts non-filamentous bacteria isolated from scum turned out to contribute to flotation by both cell surface hydrophobicity and emulsification activity, depending on the prevailing substrate and milieu conditions. The biological characterization of scum based on microscopic sludge investigation of conspicuous microorganisms resulted in a significant shift of filamentous and non-filamentous organism populations with Gram-positive bacteria prevailing in present nutrient removal plants as compared to the situation ten years ago. Their hydrophobic cell surface is supposed to support adherence and stabilization of interfaces and thus promote sludge flotation. In scum six types of filamentous bacteria turned out to be numerous: Microthrix parvicella and nocardioform actinomycetes, both of them being enriched in the scum fraction, moreover Nostocoida limicola and Eikelboom types 0041/0675, 1851, and 0092. Possible interactive mechanisms between non-filamentous and filamentous scum bacteria and their selection factors are discussed in order to contribute to a better understanding of scum formation and to provide efficient troubleshooting measures. Schaum in Belebungsanlagen: Einfluss nicht-fadiger und fadiger Bakterien Starke Schaumbildung ist gegenwartig ein weit verbreitetes Phanomen in Klaranlagen nach dem Belebungsverfahren. Die Frage nach Entstehung und Stabilisierung dieser Schaume ist nach wie vor ungeklart. Hydrophobe Abwasserbestandteile und oberflachenaktive Stoffe wie etwa Tenside werden unter anderem als wichtige Ursache der Schaumbildung diskutiert. Die Suche nach biologischen Einflussen ergab, dass aus Schaum isolierte Bakterien ohne Fadenbildung sowohl durch Oberflachenhydrophobierung als auch durch die Bildung stabiler Emulsionen zur Flotation beitragen, abhangig von den vorherrschenden Substrat- und Milieubedingungen. Die biologische Charakterisierung von Schaum, basierend auf mikroskopischen Untersuchungen auffalliger Organismen in belebtem Schlamm, ergab in Anlagen mit Stickstoff- und Phosphorentfernung eine deutliche Verschiebung hin zu Gram-positiven Bakterien – Fadenbakterien und solche, die nicht fadig wachsen – im Vergleich zu den vor etwa 10 Jahren ublichen Anlagen zur reinen Elimination von Kohlenstoffverbindungen. Die hydrophobe Oberflache dieser Organismen scheint der Adhasion an und Stabilisierung von Grenzflachen und damit der Flotation forderlich zu sein. In Schaum wurden sechs wichtige Fadenorganismen festgestellt: Microthrix parvicella und nocardioforme Actinomyceten, die beide in der Schaumfraktion angereichert werden, des Weiteren Nostocoida limicola und die zunachst noch mit Nummern benannten Fadenbakterien Eikelboom Typ 0041/0675, 1851 und 0092. Mogliche Interaktionen zwischen nicht-fadigen und fadigen Schaumbakterien sowie ihre Selektionsfaktoren werden diskutiert. Damit wird angestrebt, dem Praktiker uber ein besseres Verstandnis der Schaumbildung effektive Bekampfungsmasnahmen an die Hand zu geben.

Influence of resuspension on the fate of fecal indicator bacteria in large-scale flumes mimicking an oligotrophic river

In this study, large-scale flume systems simulating an oligotrophic river were used to explore the fate and transport of the fecal indicator bacteria (FIB) Escherichia coli and enterococci following a combined sewer overflow (CSO). Specifically, the removal pattern of FIB from the water column was examined as well as deposition onto the flume bed. Finally, the impact that a sudden increase in bed shear stress has on FIB in the water column was investigated. The large-scale flumes utilized in this study proved extremely useful for our investigations as they very closely approximated conditions within the Isar River (Munich, Germany). By using both natural substratum and fresh river water, as well as a flow velocity of nearly 1 m s(-1) at a water depth of roughly 0.5 m, shear stresses typical of the Isar River (9 N m(-2)) were achieved. As a result, scaling effects were appreciably reduced. In our flume system, UV inactivation played only a minimal role in overall FIB removal. Therefore, we were able to more precisely investigate other mechanisms which result in FIB removal from the water column. From the two standard FIB removal experiments following a CSO, the removal rate coefficient (k) of 0.2 h(-1) was identified for both E. coli and enterococci in the water column. An increase in the bed shear stress led to more than a 150% rise in total suspended solid (TSS) levels in the water column. These elevated TSS levels (≈ 50 mg l(-1)) increased the persistence of suspended FIB in the water column by 20 h (k = 0.05 h(-1)). This indicates that higher TSS loads resulting from resuspended bed sediments can significantly expand the area that is impacted by a CSO event. At lower TSS loads (<20 mg l(-1)) deposition onto the flume bed did not contribute significantly to FIB removal from the water column. Any deposition which did occur did not result in a net accumulation of culturable FIB in the benthic biofilm.

The biocidal effect of a novel synthesized gemini surfactant on environmental sulfidogenic bacteria: planktonic cells and biofilms.

A cationic gemini surfactant was synthesized and characterized. The surfactant was successfully applied as a biocide against environmental sulfidogenic bacteria in the bulk phase (planktonic) and on the surface (biofilm). The activity of the synthesized surfactant was discussed based on the redox potential and the sulfide productivity in the bulk phase. The cultivated biofilm structure analysis and corrosion rate were estimated on the metal surface. The lowest metal corrosion rate was recognized at a concentration of 1mM with a metal corrosion inhibition efficiency of 95%. The synthesized gemini surfactant prevented the biofilm formation at a concentration of 0.1mM. The synthesized gemini surfactant displayed a broad spectrum antibacterial activity against Gram-positive and Gram-negative bacteria.

Biogenic surface layers on historical window glass and the effect of excimer laser cleaning

Abstract The ablation of biofilms by excimer laser radiation was systematically examined in a series of model studies during which the biofilms originating from different historical panels were simulated on model glasses. The composition of these model glasses was modelled on that of the original historical glasses. Our studies have shown that glass composition, climatic conditions and biofilm formation are factors which interact synergetically. It could be observed that various biofilms grow differently on the same type of model glass and that the same type of biofilm shows a different development on various model glasses. The decisive factors for the effectiveness of biofilm ablation by laser irradiation is the formation of the biofilm on the one hand and its corrosive potential on account of its ability to accumulate moisture and to produce glass-damaging metabolites on the other. Glasses of low chemical stability promote the growth of dense biofilms and can be cleaned only with a high energy density, whereas glasses of high chemical stability merely allow for a slow growth of a biofilm spreading two-dimensionally on the glass surface which can be gently removed using low energy density.

Effect of acclimation and nutrient supply on 5-tolyltriazole biodegradation with activated sludge communities

The corrosion inhibitor 5-tolyltriazole (5-TTri) can have a detrimental impact on aquatic systems thus implying an acute need to reduce the effluent concentrations of 5-TTri. In this study, 5-TTri biodegradation was enhanced through acclimation and nutrient supply. Activated sludge communities (ASC) were setup in nine subsequent ASC generations. While generation two showed a lag phase of five days without biodegradation, generations four to nine utilized 5-TTri right after inoculation, with biodegradation rates from 3.3 to 5.2 mg L(-1)d(-1). Additionally, centrifuged AS supernatant was used to simulate the nutrient conditions in wastewater. This sludge supernatant (SS) significantly enhanced biodegradation, resulting in removal rates ranging from 3.2 to 5.0 mg L(-1)d(-1) without acclimation while the control groups without SS observed lower rates of ⩽ 2.2 mg L(-1)d(-1).

A systematic insight into a single-stage deammonification process operated in granular sludge reactor with high-loaded reject-water: characterization and quantification of microbiological community.

Reject‐water from sludge dewatering was treated in a single‐stage deammonification reactor. The aims were to characterize the microbiological community within deammonification granules.