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4. Biogeochemical consequences of nonvertical methane transport in sediment offshore northwestern Svalbard

Author

Treude, T., Krause, S., Steinle, L., Burwicz, E., Hamdan, L. J., Niemann, H., Feseker, T., Liebetrau, V., Krastel, S., Berndt, C., Treude, T., Krause, S., Steinle, L., Burwicz, E., Hamdan, L. J., Niemann, H., Feseker, T., Liebetrau, V., Krastel, S., and Berndt, C.

Abstract

A site at the gas hydrate stability limit was investigated offshore northwestern Svalbard to study methane transport in sediment. The site was characterized by chemosynthetic communities (sulfur bacteria mats, tubeworms) and gas venting. Sediments were sampled with in situ porewater collectors and by gravity coring followed by analyses of porewater constituents, sediment and carbonate geochemistry, and microbial activity, taxonomy, and lipid biomarkers. Sulfide and alkalinity concentrations showed concentration maxima in near‐surface sediments at the bacterial mat and deeper maxima at the gas vent site. Sediments at the periphery of the chemosynthetic field were characterized by two sulfate‐methane transition zones (SMTZs) at ~204 and 45 cm depth, where activity maxima of microbial anaerobic oxidation of methane (AOM) with sulfate were found. Amplicon sequencing and lipid biomarker indicate that AOM at the SMTZs was mediated by ANME‐1 archaea. A 1D numerical transport reaction model suggests that the deeper SMTZ‐1 formed on centennial scale by vertical advection of methane, while the shallower SMTZ‐2 could only be reproduced by nonvertical methane injections starting on decadal scale. Model results were supported by age distribution of authigenic carbonates, showing youngest carbonates within SMTZ‐2. We propose that nonvertical methane injection was induced by increasing blockage of vertical transport or formation of sediment fractures. Our study further suggests that the methanotrophic response to the nonvertical methane injection was commensurate with new methane supply. This finding provides new information about for the response time and efficiency of the benthic methane filter in environments with fluctuating methane transport.

Published
2020

5. Manganese/iron‐supported sulfate‐dependent anaerobic oxidation of methane by archaea in lake sediments

Author

Su, G., Zopfi, J., Yao, H., Steinle, L., Niemann, H., Lehmann, M.F., Su, G., Zopfi, J., Yao, H., Steinle, L., Niemann, H., and Lehmann, M.F.

Abstract

Anaerobic oxidation of methane (AOM) by methanotrophic archaea is an important sink of this greenhouse gas in marine sediments. However, evidence for AOM in freshwater habitats is rare, and little is known about the pathways, electron acceptors, and microbes involved. Here, we show that AOM occurs in anoxic sediments of a sulfate‐rich lake in southern Switzerland (Lake Cadagno). Combined AOM‐rate and 16S rRNA gene‐sequencing data suggest that Candidatus Methanoperedens archaea are responsible for the observed methane oxidation. Members of the Methanoperedenaceae family were previously reported to conduct nitrate‐ or iron/manganese‐dependent AOM. However, we demonstrate for the first time that the methanotrophic archaea do not necessarily rely upon these oxidants as terminal electron acceptors directly, but mainly perform canonical sulfate‐dependent AOM, which under sulfate‐starved conditions can be supported by metal (Mn, Fe) oxides through oxidation of reduced sulfur species to sulfate. The correspondence of high abundances of Desulfobulbaceae and Candidatus Methanoperedens at the same sediment depth confirms the interdependence of anaerobic methane‐oxidizing archaea and sulfate‐reducing bacteria. The relatively high abundance and widespread distribution of Candidatus Methanoperedens in lake sediments highlight their potentially important role in mitigating methane emissions from terrestrial freshwater environments to the atmosphere, analogous to ANME‐1, ‐2, and ‐3 in marine settings.

Published
2020

6. Biogeochemical consequences of nonvertical methane transport in sediment offshore northwestern Svalbard

Author

Treude, Tina, Krause, Stefan, Steinle, L., Burwicz, Ewa B., Hamdan, L. J., Niemann, H., Feseker, T., Liebetrau, Volker, Krastel, Sebastian, Berndt, Christian, Treude, Tina, Krause, Stefan, Steinle, L., Burwicz, Ewa B., Hamdan, L. J., Niemann, H., Feseker, T., Liebetrau, Volker, Krastel, Sebastian, and Berndt, Christian

Abstract

A site at the gas hydrate stability limit was investigated offshore northwestern Svalbard to study methane transport in sediment. The site was characterized by chemosynthetic communities (sulfur bacteria mats, tubeworms) and gas venting. Sediments were sampled with in‐situ porewater collectors and by gravity coring followed by analyses of porewater constituents, sediment and carbonate geochemistry, and microbial activity, taxonomy, and lipid biomarkers. Sulfide and alkalinity concentrations showed concentration maxima in near‐surface sediments at the bacterial mat and deeper maxima at the gas vent site. Sediments at the periphery of the chemosynthetic field were characterized by two sulfate‐methane transition zones (SMTZ) at ~204 and 45 cm depth, where activity maxima of microbial anaerobic oxidation of methane (AOM) with sulfate were found. Amplicon sequencing and lipid biomarker indicate that AOM at the SMTZs was mediated by ANME‐1 archaea. A 1D numerical transport reaction model suggests that the deeper SMTZ‐1 formed on centennial scale by vertical advection of methane, while the shallower SMTZ‐2 could only be reproduced by non‐vertical methane injections starting on decadal scale. Model results were supported by age distribution of authigenic carbonates, showing youngest carbonates within SMTZ‐2. We propose that non‐vertical methane injection was induced by increasing blockage of vertical transport or formation of sediment fractures. Our study further suggests that the methanotrophic response to the non‐vertical methane injection was commensurate with new methane supply. This finding provides new information about for the response time and efficiency of the benthic methane filter in environments with fluctuating methane transport.

Published
2020
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7. Distribution and abundance of methagenic and methatrophic microorganisms across European streams

Author

Nagler, M., Praeg, N., Niedrist, G., Attermeyer, K., Bednarik, A., Bors, C., Catalan, N., sophie Cauvy-Fraunié, Colls, M., Eyto, E., Doyle, B., Evtimova, V., Fenoglio, S., Freixa, A., Fuss, T., Gaffney, P., Gilbert, P., Gutmann Roberts, C., Herrero Ortega, S., Kenderov, L., Klaus, M., Lamonica, D., Machalett, B., Mor, J. R., Nydahl, A., Pegg, J., Piano, E., Pilotto, F., Romero, F., Romero Gonzalez Quijano, C., Rulik, M., Steinle, L., Thuile Bistarelli, L., Bodmer, P., UNIVERSITAT INNSBRUCK AUT, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), WASSERCLUSTER LUNZ LUNZ AM SEE AUT, Palacky University Olomouc, UNIVERSITY OF KOBLENZLANDAU LANDAU IN DER PFALZ DEU, CATALAN INSTITUTE FOR WATER RESEACH GIRONA ESP, RiverLy (UR Riverly), Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), THE MARINE INSTITUTE NEWPORT IRL, DUNDALK INSTITUTE OF TECHNOLOGY DUNDALK IRL, BULGARIAN ACADEMY OF SCIENCES SOFIA BGR, UNIVERSITA DEL PIEMONTE ORIENTALE ALESSANDRIA ITA, LEIBNIZ INSTITUTE OF FRESHWATER ECOLOGY AND INLAND FISHERIES BERLIN DEU, University of the Highlands and Islands (UHI), Bournemouth University [Poole] (BU), SOFIA UNIVERSITY ST KLIMENT OHRIDSKI BGR, UMEA UNIVERSITY SWE, Humboldt-Universität zu Berlin, University of Massachusetts [Amherst] (UMass Amherst), University of Massachusetts System (UMASS), Uppsala University, SOUTH AFRICAN INSTITUTE FOR AQUATIC BIODIVERSITY MAKHANDA ZAF, SENCKENBERG RESEARCH INSTITUTE AND NATURAL HISTORY MUSEUM FRANKFURT GELNHAUSEN DEU, and University of Basel (Unibas)

Subjects
EUROPE, [SDE]Environmental Sciences
Abstract

International audience; Globally, streams and rivers emit a significant amount of methane, a highly potent greenhouse gas. However, little is known about stream sediment microbial communities, driving the net methane balance in these systems, especially on their distribution and composition at large spatial scales. Within the project Euro Methane we investigated the diversity and abundance of methanogenic archaea and methane-oxidizing bacteria across 16 European streams (from northern Spain to central Sweden) via 16S rRNA sequencing and qPCR. We determined environmental drivers of both abundance and community composition and explored the link to measured potential methane production and oxidation rates of the respective sediments. We found that the community composition of methane-oxidizing bacteria significantly differed among the studied streams, while methanogenic archaea were more homogeneously distributed. Beyond the overall diversity trends, indicator species for stream types were identified. Methanogenic Methanosaeta sp. and methane-oxidizing Methyloglobulus sp. increased with geographical latitude and dominated in headwater streams (orders 1-3) with high oxygen levels and high proportions of pristine land within the catchment, while methanogenic Methanomethylovorans sp. and methane-oxidizing Methylocaldum spp. were more common in larger streams (orders 4-6) with higher discharge and agricultural influence. Potential methane production rates significantly increased with abundance of methanogenic archaea, while potential methane oxidation rates did not show significant correlations with methane oxidizing bacteria, presumably due to the more diverse physiological capabilities of this microbial group. Our study represents a holistic large-scale biogeographical overview of two microbial groups to enhance our understanding of the methane cycle within a heretofore understudied ecosystem.

Published
2019

8. Life on the edge: active microbial communities in the Kryos MgCl2-brine basin at very low water activity

Author

Steinle, L., Knittel, K., Felber, N., Casalino, C., de Lange, G., Tessarolo, C., Stadnitskaia, A., Sinninghe Damsté, J.S., Zopfi, J., Lehmann, M.F., Treude, T., Niemann, H., Steinle, L., Knittel, K., Felber, N., Casalino, C., de Lange, G., Tessarolo, C., Stadnitskaia, A., Sinninghe Damsté, J.S., Zopfi, J., Lehmann, M.F., Treude, T., and Niemann, H.

Abstract

The Kryos Basin is a deep-sea hypersaline anoxic basin (DHAB) located in the Eastern Mediterranean Sea (34.98°N 22.04°E). It is filled with brine of re-dissolved Messinian evaporites and is nearly saturated with MgCl2-equivalents, which makes this habitat extremely challenging for life. The strong density difference between the anoxic brine and the overlying oxic Mediterranean seawater impedes mixing, giving rise to a narrow chemocline. Here, we investigate the microbial community structure and activities across the seawater–brine interface using a combined biogeochemical, next-generation sequencing, and lipid biomarker approach. Within the interface, we detected fatty acids that were distinctly 13C-enriched when compared to other fatty acids. These likely originated from sulfide-oxidizing bacteria that fix carbon via the reverse tricarboxylic acid cycle. In the lower part of the interface, we also measured elevated rates of methane oxidation, probably mediated by aerobic methanotrophs under micro-oxic conditions. Sulfate reduction rates increased across the interface and were highest within the brine, providing first evidence that sulfate reducers (likely Desulfovermiculus and Desulfobacula) thrive in the Kryos Basin at a water activity of only ~0.4 Aw. Our results demonstrate that a highly specialized microbial community in the Kryos Basin has adapted to the poly-extreme conditions of a DHAB with nearly saturated MgCl2 brine, extending the known environmental range where microbial life can persist.

Published
2018

9. Water column methanotrophy controlled by a rapid oceanographic switch

Author

Steinle, L, Steinle, L, Graves, CA, Treude, T, Ferré, B, Biastoch, A, Bussmann, I, Berndt, C, Krastel, S, James, RH, Behrens, E, Böning, CW, Greinert, J, Sapart, CJ, Scheinert, M, Sommer, S, Lehmann, MF, Niemann, H, Steinle, L, Steinle, L, Graves, CA, Treude, T, Ferré, B, Biastoch, A, Bussmann, I, Berndt, C, Krastel, S, James, RH, Behrens, E, Böning, CW, Greinert, J, Sapart, CJ, Scheinert, M, Sommer, S, Lehmann, MF, and Niemann, H

Abstract

Large amounts of the greenhouse gas methane are released from the seabed to the water column, where it may be consumed by aerobic methanotrophic bacteria. The size and activity of methanotrophic communities, which determine the amount of methane consumed in the water column, are thought to be mainly controlled by nutrient and redox dynamics. Here, we report repeated measurements of methanotrophic activity and community size at methane seeps west of Svalbard, and relate them to physical water mass properties and modelled ocean currents. We show that cold bottom water, which contained a large number of aerobic methanotrophs, was displaced by warmer water with a considerably smaller methanotrophic community within days. Ocean current simulations using a global ocean/sea-ice model suggest that this water mass exchange is consistent with short-term variations in the meandering West Spitsbergen Current. We conclude that the shift from an offshore to a nearshore position of the current can rapidly and severely reduce methanotrophic activity in the water column. Strong fluctuating currents are common at many methane seep systems globally, and we suggest that they affect methane oxidation in the water column at other sites, too.

Published
2015

10. Water column methanotrophy controlled by a rapid oceanographic switch

Author

Steinle, L., Graves, C.A., Treude, T., Ferré, B., Biastoch, A., Bussmann, I., Berndt, C., Krastel, S., James, R.H., Behrens, E., Böning, C.W., Greinert, J., Sapart, C.-J., Scheinert, M., Sommer, S., Lehmann, M.F., Niemann, H., Steinle, L., Graves, C.A., Treude, T., Ferré, B., Biastoch, A., Bussmann, I., Berndt, C., Krastel, S., James, R.H., Behrens, E., Böning, C.W., Greinert, J., Sapart, C.-J., Scheinert, M., Sommer, S., Lehmann, M.F., and Niemann, H.

Abstract

From the seabed to the water column, where it may be consumed by aerobic methanotrophic bacteria. The size and activity of methanotrophic communities, which determine the amount of methane consumed in the water column,are thought to be mainly controlled by nutrient and redoxdynamics3–7. Here, we report repeated measurements of methanotrophic activity and community size at methaneseeps west of Svalbard, and relate them to physical watermass properties and modelled ocean currents. We show that cold bottom water, which contained a large number of aerobic methanotrophs, was displaced by warmer water with a considerably smaller methanotrophic community within days.Ocean current simulations using a global ocean/sea-ice model suggest that this water mass exchange is consistent withshort-term variations in the meandering West Spitsbergen Current. We conclude that the shift from an oshore to a nearshore position of the current can rapidly and severelyr educe methanotrophic activity in the water column. Strong fluctuating currents are common at many methane seep systems globally, and we suggest that they aect methaneoxidation in the water column at other sites, too.

Published
2015

11. Amplified Sediment waves in the Irish Sea (AmSedIS)

Author

Van Landeghem, K., Besio, G., Niemann, H., Mellett, C., Huws, D., Steinle, L., O'Reilly, S., Croker, P., Hodgson, D., and Williams, D.

Abstract

Exceptionally high, straight-crested and trochoidal sediment waves have recently been observed on shelf seas world-wide, and reach heights of up to 36 m in the Irish Sea. It is uncertain how the interplay between geological, biogeochemical and hydrodynamic processes influences the migration and extreme growth of these sediment waves. The AmSedIS project thus sets out to (1) investigate the role of sediment granulometry and sedimentavailability on both “extreme” and “normal” sediment wave development and (2) investigate the potential association of methane derived carbonate formation with extreme sediment wave growth. The preliminary findings are: (1) The crests of unusually high and trochoidal sediment waves still migrate over several meters per year and they consist of coarser, more poorly sorted sediments in comparison to the "normal" sediments waves; (2) Methane seepage is not considered a factor in extreme sediment wave development; (3) The excess of mobile sediment supply seems to allow for "extreme" sediment wave growth, and is linked to palaeo-tunnel valleys and the finer sediments that fill them or with converging sediment transport pathways; (4) The variation in sediment from sediment wave trough to crest to trough will form the basis for more advanced numerical modelling.

Published
2013

12. Temporal Constraints on Hydrate-Controlled Methane Seepage off Svalbard

Author

Berndt, Christian, Feseker, Tomas, Treude, Tina, Krastel, Sebastian, Liebetrau, Volker, Niemann, H., Bertics, Victoria J., Dumke, Ines, Dünnbier, Karolin, Ferre, B., Graves, C., Gross, Felix, Hissmann, Karen, Hühnerbach, Veit, Krause, Stefan, Lieser, Kathrin, Schauer, Jürgen, Steinle, L., Berndt, Christian, Feseker, Tomas, Treude, Tina, Krastel, Sebastian, Liebetrau, Volker, Niemann, H., Bertics, Victoria J., Dumke, Ines, Dünnbier, Karolin, Ferre, B., Graves, C., Gross, Felix, Hissmann, Karen, Hühnerbach, Veit, Krause, Stefan, Lieser, Kathrin, Schauer, Jürgen, and Steinle, L.

Abstract

Methane hydrate is an icelike substance that is stable at high pressure and low temperature in continental margin sediments. Since the discovery of a large number of gas flares at the landward termination of the gas hydrate stability zone off Svalbard, there has been concern that warming bottom waters have started to dissociate large amounts of gas hydrate and that the resulting methane release may possibly accelerate global warming. Here, we can corroborate that hydrates play a role in the observed seepage of gas, but we present evidence that seepage off Svalbard has been ongoing for at least three thousand years and that seasonal fluctuations of 1-2°C in the bottom-water temperature cause periodic gas hydrate formation and dissociation, which focus seepage at the observed sites.

Published
2014
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14. Functional analysis of NopM, a novel E3 ubiquitin ligase (NEL) domain effector of

Author

Xin D.-W., Liao S., Xie Z.-P., Hann D. R., Steinle L., Boller T., and Staehelin C.

Subjects
food and beverages
Abstract

Type 3 effector proteins secreted via the bacterial type 3 secretion system (T3SS) are not only virulence factors of pathogenic bacteria but also influence symbiotic interactions between nitrogen fixing nodule bacteria (rhizobia) and leguminous host plants. In this study we characterized NopM (nodulation outer protein M) of Rhizobium sp. strain NGR234 which shows sequence similarities with novel E3 ubiquitin ligase (NEL) domain effectors from the human pathogens Shigella flexneri and Salomonella enterica. NopM expressed in Escherichia coli but not the non functional mutant protein NopM C338A showed E3 ubiquitin ligase activity in vitro. In vivo NopM but not inactive NopM C338A promoted nodulation of the host plant Lablab purpureus by NGR234. When NopM was expressed in yeast it inhibited mating pheromone signaling a mitogen activated protein (MAP) kinase pathway. When expressed in the plant Nicotiana benthamiana NopM inhibited one part of the plant's defense response as shown by a reduced production of reactive oxygen species (ROS) in response to the flagellin peptide flg22 whereas it stimulated another part namely the induction of defense genes. In summary our data indicate the potential for NopM as a functional NEL domain E3 ubiquitin ligase. Our findings that NopM dampened the flg22 induced ROS burst in N. benthamiana but promoted defense gene induction are consistent with the concept that pattern triggered immunity is split in two separate signaling branches one leading to ROS production and the other to defense gene induction.

Published
2012

15. Life on the edge: active microbial communities in the Kryos MgCl 2 -brine basin at very low water activity.

Author

Steinle L, Knittel K, Felber N, Casalino C, de Lange G, Tessarolo C, Stadnitskaia A, Sinninghe Damsté JS, Zopfi J, Lehmann MF, Treude T, and Niemann H

Subjects
Biomarkers metabolism, Lipids chemistry, Mediterranean Sea, Oxygen chemistry, Phylogeny, RNA, Ribosomal, 16S chemistry, Sulfates chemistry, Sulfides chemistry, Bacteria, Magnesium Chloride chemistry, Microbiota, Salts chemistry, Seawater microbiology, Water Microbiology
Abstract

The Kryos Basin is a deep-sea hypersaline anoxic basin (DHAB) located in the Eastern Mediterranean Sea (34.98°N 22.04°E). It is filled with brine of re-dissolved Messinian evaporites and is nearly saturated with MgCl 2 -equivalents, which makes this habitat extremely challenging for life. The strong density difference between the anoxic brine and the overlying oxic Mediterranean seawater impedes mixing, giving rise to a narrow chemocline. Here, we investigate the microbial community structure and activities across the seawater-brine interface using a combined biogeochemical, next-generation sequencing, and lipid biomarker approach. Within the interface, we detected fatty acids that were distinctly 13 C-enriched when compared to other fatty acids. These likely originated from sulfide-oxidizing bacteria that fix carbon via the reverse tricarboxylic acid cycle. In the lower part of the interface, we also measured elevated rates of methane oxidation, probably mediated by aerobic methanotrophs under micro-oxic conditions. Sulfate reduction rates increased across the interface and were highest within the brine, providing first evidence that sulfate reducers (likely Desulfovermiculus and Desulfobacula) thrive in the Kryos Basin at a water activity of only ~0.4 A w . Our results demonstrate that a highly specialized microbial community in the Kryos Basin has adapted to the poly-extreme conditions of a DHAB with nearly saturated MgCl 2 brine, extending the known environmental range where microbial life can persist.

Published
2018
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16. Shallow Gas Migration along Hydrocarbon Wells-An Unconsidered, Anthropogenic Source of Biogenic Methane in the North Sea.

Author

Vielstädte L, Haeckel M, Karstens J, Linke P, Schmidt M, Steinle L, and Wallmann K

Subjects
Atmosphere, Hydrocarbons analysis, Methane analysis, North Sea, Hydrocarbons chemistry, Methane chemistry
Abstract

Shallow gas migration along hydrocarbon wells constitutes a potential methane emission pathway that currently is not recognized in any regulatory framework or greenhouse gas inventory. Recently, the first methane emission measurements at three abandoned offshore wells in the Central North Sea (CNS) were conducted showing that considerable amounts of biogenic methane originating from shallow gas accumulations in the overburden of deep reservoirs were released by the boreholes. Here, we identify numerous wells poking through shallow gas pockets in 3-D seismic data of the CNS indicating that about one-third of the wells may leak, potentially releasing a total of 3-17 kt of methane per year into the North Sea. This poses a significant contribution to the North Sea methane budget. A large fraction of this gas (∼42%) may reach the atmosphere via direct bubble transport (0-2 kt yr -1 ) and via diffusive exchange of methane dissolving in the surface mixed layer (1-5 kt yr -1 ), as indicated by numerical modeling. In the North Sea and in other hydrocarbon-prolific provinces of the world shallow gas pockets are frequently observed in the sedimentary overburden and aggregate leakages along the numerous wells drilled in those areas may be significant.

Published
2017
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17. Reflectometric interference spectroscopy.

Author

Proll G, Markovic G, Steinle L, and Gauglitz G

Subjects
Biosensing Techniques methods, Equipment Design, Equipment Failure Analysis, Immunoassay methods, Interferometry methods, Photometry methods, Refractometry methods, Reproducibility of Results, Sensitivity and Specificity, Spectrum Analysis methods, Biosensing Techniques instrumentation, Immunoassay instrumentation, Interferometry instrumentation, Photometry instrumentation, Refractometry instrumentation, Spectrum Analysis instrumentation
Abstract

Reflectometry is classified in comparison to the commercialized refractometric surface plasmon resonance (SPR). The advantages of direct optical detection depend on a sophisticated surface chemistry resulting in negligible nonspecific binding and high loading with recognition sites at the biopolymer sensitive layer of the transducer. Elaborate details on instrumental realization and surface chemistry are discussed for optimum application of reflectometric interference spectroscopy (RIfS). A standard protocol for a binding inhibition assay is given. It overcomes principal problems of any direct optical detection technique.

Published
2009
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18. Potential of label-free detection in high-content-screening applications.

Author

Proll G, Steinle L, Pröll F, Kumpf M, Moehrle B, Mehlmann M, and Gauglitz G

Subjects
Automation, Electrophoresis, Sensitivity and Specificity, Spectrum Analysis methods, Temperature, Drug Design
Abstract

The classical approach of high-content screening (HCS) is based on multiplexed, functional cell-based screening and combines several analytical technologies that have been used before separately to achieve a better level of automation (scale-up) and higher throughput. New HCS methods will help to overcome the bottlenecks, e.g. in the present development chain for lead structures for the pharmaceutical industry or during the identification and validation process of new biomarkers. In addition, there is a strong need in analytical and bioanalytical chemistry for functional high-content assays which can be provided by different hyphenated techniques. This review discusses the potential of a label-free optical biosensor based on reflectometric interference spectroscopy (RIfS) as a bridging technology for different HCS approaches. Technical requirements of RIfS are critically assessed by means of selected applications and compared to the performance characteristics of surface plasmon resonance (SPR) which is currently the leading technology in the area of label-free optical biosensors.

Published
2007
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