@article{ShumyantsevaIvanovBistolasetal.2004, author = {Shumyantseva, V. V. and Ivanov, Y. D. and Bistolas, Nikitas and Scheller, Frieder W. and Archakov, Alexander I. and Wollenberger, Ursula}, title = {Direct electron transfer of cytochrome P450 2B4 at electrodes modified with non-ionic detergent and colloidal clay nanoparticles}, year = {2004}, abstract = {A method for construction of biosensors with membranous cytochrome P450 isoenzymes was developed based on clay/ detergent/protein mixed films. Thin films of sodium montmorillonite colloid with incorporated cytochrome P450 2134 (CYP2B4) with nonionic detergent were prepared on glassy carbon electrodes. The modified electrodes were electrochemically characterized, and bio-electrocatalytic reactions were followed. CYP2B4 can be reduced fast on clay- modified glassy carbon electrodes in the presence of the nonionic detergent Tween 80. In anaerobic solutions, reversible oxidation and reduction is obtained with a formal potential between -0.292 and - 0.305 V vs Ag/AgCl 1 M KCl depending on the preparation of the biosensor. In air-saturated solution, bio-electrocatalytic reduction currents can be obtained with the CYP2B4-modified electrode on addition of typical substrates such as aminopyrine and benzphetamine. This reaction was suppressed when methyrapone, an inhibitor of P450 reactions, was present. Measurement of product formation also indicates the bioelectrocatialysis by CYP2B4}, language = {en} } @article{SezerSpricigoUteschetal.2010, author = {Sezer, Murat and Spricigo, Roberto and Utesch, Tillmann and Millo, Diego and Leimk{\"u}hler, Silke and Mroginski, Maria A. and Wollenberger, Ursula and Hildebrandt, Peter and Weidinger, Inez M.}, title = {Redox properties and catalytic activity of surface-bound human sulfite oxidase studied by a combined surface enhanced resonance Raman spectroscopic and electrochemical approach}, issn = {1463-9076}, doi = {10.1039/B927226g}, year = {2010}, abstract = {Human sulfite oxidase (hSO) was immobilised on SAM-coated silver electrodes under preservation of the native heme pocket structure of the cytochrome b5 (Cyt b5) domain and the functionality of the enzyme. The redox properties and catalytic activity of the entire enzyme were studied by surface enhanced resonance Raman (SERR) spectroscopy and cyclic voltammetry (CV) and compared to the isolated heme domain when possible. It is shown that heterogeneous electron transfer and catalytic activity of hSO sensitively depend on the local environment of the enzyme. Increasing the ionic strength of the buffer solution leads to an increase of the heterogeneous electron transfer rate from 17 s(-1) to 440 s(- 1) for hSO as determined by SERR spectroscopy. CV measurements demonstrate an increase of the apparent turnover rate for the immobilised hSO from 0.85 s(-1) in 100 mM buffer to 5.26 s(-1) in 750 mM buffer. We suggest that both effects originate from the increased mobility of the surface-bound enzyme with increasing ionic strength. In agreement with surface potential calculations we propose that at high ionic strength the enzyme is immobilised via the dimerisation domain to the SAM surface. The flexible loop region connecting the Moco and the Cyt b5 domain allows alternating contact with the Moco interaction site and the SAM surface, thereby promoting the sequential intramolecular and heterogeneous electron transfer from Moco via Cyt b5 to the electrode. At lower ionic strength, the contact time of the Cyt b5 domain with the SAM surface is longer, corresponding to a slower overall electron transfer process.}, language = {en} } @article{SchellerYarmanBachmannetal.2014, author = {Scheller, Frieder W. and Yarman, Aysu and Bachmann, Till and Hirsch, Thomas and Kubick, Stefan and Renneberg, Reinhard and Schumacher, Soeren and Wollenberger, Ursula and Teller, Carsten and Bier, Frank Fabian}, title = {Future of biosensors: a personal view}, series = {Advances in biochemical engineering, biotechnology}, volume = {140}, journal = {Advances in biochemical engineering, biotechnology}, editor = {Gu, MB and Kim, HS}, publisher = {Springer}, address = {Berlin}, isbn = {978-3-642-54143-8; 978-3-642-54142-1}, issn = {0724-6145}, doi = {10.1007/10_2013_251}, pages = {1 -- 28}, year = {2014}, abstract = {Biosensors representing the technological counterpart of living senses have found routine application in amperometric enzyme electrodes for decentralized blood glucose measurement, interaction analysis by surface plasmon resonance in drug development, and to some extent DNA chips for expression analysis and enzyme polymorphisms. These technologies have already reached a highly advanced level and need minor improvement at most. The dream of the "100-dollar' personal genome may come true in the next few years provided that the technological hurdles of nanopore technology or of polymerase-based single molecule sequencing can be overcome. Tailor-made recognition elements for biosensors including membrane-bound enzymes and receptors will be prepared by cell-free protein synthesis. As alternatives for biological recognition elements, molecularly imprinted polymers (MIPs) have been created. They have the potential to substitute antibodies in biosensors and biochips for the measurement of low-molecular-weight substances, proteins, viruses, and living cells. They are more stable than proteins and can be produced in large amounts by chemical synthesis. Integration of nanomaterials, especially of graphene, could lead to new miniaturized biosensors with high sensitivity and ultrafast response. In the future individual therapy will include genetic profiling of isoenzymes and polymorphic forms of drug-metabolizing enzymes especially of the cytochrome P450 family. For defining the pharmacokinetics including the clearance of a given genotype enzyme electrodes will be a useful tool. For decentralized online patient control or the integration into everyday "consumables' such as drinking water, foods, hygienic articles, clothing, or for control of air conditioners in buildings and cars and swimming pools, a new generation of "autonomous' biosensors will emerge.}, language = {en} } @article{SchellerWollenbergerWarsinkeetal.2001, author = {Scheller, Frieder W. and Wollenberger, Ursula and Warsinke, Axel and Lisdat, Fred}, title = {Research and development in biosensors}, year = {2001}, language = {en} } @article{SchellerWollenbergerSchubertetal.1993, author = {Scheller, Frieder W. and Wollenberger, Ursula and Schubert, Florian and Pfeiffer, Dorothea and Markower, Alexander and McNeil, C. J.}, title = {Multienzyme biosensors : coupled enzyme reactions and enzyme activation}, year = {1993}, language = {en} } @article{SchellerWollenbergerPfeifferetal.1996, author = {Scheller, Frieder W. and Wollenberger, Ursula and Pfeiffer, Dorothea and Schubert, Florian}, title = {Overview of biosensor technology : proceedings of Mosbach Symposion on Biochemical Technology}, year = {1996}, language = {en} } @article{SchellerWollenbergerLeietal.2002, author = {Scheller, Frieder W. and Wollenberger, Ursula and Lei, Chenghong and Jin, Wen and Ge, Bixia and Lehmann, Claudia and Lisdat, Fred and Fridman, Vadim}, title = {Bioelectrocatalysis by redox enzymes at modified electrodes}, year = {2002}, language = {en} } @article{SchellerWollenberger2003, author = {Scheller, Frieder W. and Wollenberger, Ursula}, title = {Enzyme Electrodes}, isbn = {3-527-30401-0}, year = {2003}, language = {en} } @article{SchellerPfeifferSchubertetal.1995, author = {Scheller, Frieder W. and Pfeiffer, Dorothea and Schubert, Florian and Wollenberger, Ursula}, title = {Enzyme - based electrodes}, year = {1995}, language = {en} } @article{SchellerMakowerGhindilisetal.1995, author = {Scheller, Frieder W. and Makower, Alexander and Ghindilis, A. L. and Bier, Frank Fabian and Ehrentreich-F{\"o}rster, Eva and Wollenberger, Ursula and Bauer, Christian G. and Micheel, Burkhard and Pfeiffer, Dorothea and Szeponik, Jan and Michael, N. and Kaden, H.}, title = {Enzyme sensors for subnanomolar concentrations}, year = {1995}, language = {en} } @article{SchellerMakowerBieretal.1995, author = {Scheller, Frieder W. and Makower, Alexander and Bier, Frank Fabian and Wollenberger, Ursula and Ghindilis, A. L. and Eremenko, A. V. and Pfeiffer, Dorothea}, title = {Enzymsensoren zur Bestimmung subnanomolarer Konzentrationen}, year = {1995}, language = {de} } @article{SchellerLisdatWollenberger2005, author = {Scheller, Frieder W. and Lisdat, Fred and Wollenberger, Ursula}, title = {Application of electrically contacted enzymes for biosensors}, isbn = {3-527- 30690-0}, year = {2005}, language = {en} } @article{SchellerKleinjungBieretal.1998, author = {Scheller, Frieder W. and Kleinjung, Frank and Bier, Frank Fabian and Markower, Alexander and Neumann, Barbara and Wollenberger, Ursula and Kurochkin, Iliya N. and Eremenko, Arkadi V. and Barmin, Anatoli V. and Klußmann, Sven and F{\"u}rste, Jens-Peter and Erdmann, Volker A. and Mansuy, D.}, title = {New recognition elements in biosensing}, year = {1998}, language = {en} } @article{SchellerJinEhrentreichFoersteretal.1999, author = {Scheller, Frieder W. and Jin, Wen and Ehrentreich-F{\"o}rster, Eva and Ge, Bixia and Lisdat, Fred and B{\"u}ttemeyer, R. and Wollenberger, Ursula}, title = {Cytochrome c based superoxide sensor for in vivo application}, year = {1999}, language = {en} } @article{SchellerBistolasLiuetal.2005, author = {Scheller, Frieder W. and Bistolas, Nikitas and Liu, Songqin and J{\"a}nchen, Michael and Katterle, Martin and Wollenberger, Ursula}, title = {Thirty years of haemoglobin electrochemistry}, year = {2005}, abstract = {Electrochemical investigations of the blood oxygen carrier protein include both mediated and direct electron transfer. The reaction of haemoglobin (Hb) with typical mediators, e.g., ferricyanide, can be quantified by measuring the produced ferrocyanide which is equivalent to the Hb concentration. Immobilization of the mediator within the electrode body allows reagentless electrochemical measuring of Hb. On the other hand, entrapment of the protein within layers of polyclectrolytes, lipids, nanoparticles of clay or gold leads to a fast heterogeneous electron exchange of the partially denatured Hb. (c) 2005 Elsevier B.V. All rights reserved}, language = {en} } @article{SchellerBauerMarkoweretal.2001, author = {Scheller, Frieder W. and Bauer, Christian G. and Markower, Alexander and Wollenberger, Ursula and Warsinke, Axel and Bier, Frank Fabian}, title = {Coupling of immunoassays with enzymatic recycling electrodes}, year = {2001}, language = {en} } @article{SchellerBauerMakoweretal.2002, author = {Scheller, Frieder W. and Bauer, Christian G. and Makower, Alexander and Wollenberger, Ursula and Warsinke, Axel and Bier, Frank Fabian}, title = {Immunoassays using enzymatic amplification electrodes}, isbn = {0-7484-0791-X}, year = {2002}, language = {en} } @article{SarauliRiedelWettsteinetal.2012, author = {Sarauli, David and Riedel, Marc and Wettstein, Christoph and Hahn, Robert and Stiba, Konstanze and Wollenberger, Ursula and Leimk{\"u}hler, Silke and Schmuki, Patrik and Lisdat, Fred}, title = {Semimetallic TiO2 nanotubes new interfaces for bioelectrochemical enzymatic catalysis}, series = {Journal of materials chemistry}, volume = {22}, journal = {Journal of materials chemistry}, number = {11}, publisher = {Royal Society of Chemistry}, address = {Cambridge}, issn = {0959-9428}, doi = {10.1039/c2jm16427b}, pages = {4615 -- 4618}, year = {2012}, abstract = {Different self-organized TiO2 nanotube structures are shown to represent new interfaces for the achievement of bioelectrochemical enzymatic catalysis involving redox proteins and enzymes without further surface modification or the presence of mediators.}, language = {en} } @article{RosePfeifferSchelleretal.2001, author = {Rose, Andreas and Pfeiffer, Dorothea and Scheller, Frieder W. and Wollenberger, Ursula}, title = {Quinoprotein glucose dehydrogenasemodified thick-film electrodes for the amperometric detection of phenolic compounds in flow injection analysis}, year = {2001}, language = {en} } @article{PinyouRuffPoelleretal.2016, author = {Pinyou, Piyanut and Ruff, Adrian and Poeller, Sascha and Alsaoub, Sabine and Leimk{\"u}hler, Silke and Wollenberger, Ursula and Schuhmann, Wolfgang}, title = {Wiring of the aldehyde oxidoreductase PaoABC to electrode surfaces via entrapment in low potential phenothiazine-modified redox polymers}, series = {Bioelectrochemistry : an international journal devoted to electrochemical aspects of biology and biological aspects of electrochemistry ; official journal of the Bioelectrochemical Society}, volume = {109}, journal = {Bioelectrochemistry : an international journal devoted to electrochemical aspects of biology and biological aspects of electrochemistry ; official journal of the Bioelectrochemical Society}, publisher = {Elsevier}, address = {Lausanne}, issn = {1567-5394}, doi = {10.1016/j.bioelechem.2015.12.005}, pages = {24 -- 30}, year = {2016}, abstract = {Phenothiazine-modified redox hydrogels were synthesized and used for the wiring of the aldehyde oxidoreductase PaoABC to electrode surfaces. The effects of the pH value and electrode surface modification on the biocatalytic activity of the layers were studied in the presence of vanillin as the substrate. The enzyme electrodes were successfully employed as bioanodes in vanillin/O-2 biofuel cells in combination with a high potential bilirubin oxidase biocathode. Open circuit voltages of around 700 mV could be obtained in a two compartment biofuel cell setup. Moreover, the use of a rather hydrophobic polymer with a high degree of crosslinking sites ensures the formation of stable polymer/enzyme films which were successfully used as bioanode in membrane-less biofuel cells. (C) 2015 Elsevier B.V. All rights reserved.}, language = {en} }