Scientific Advisory Board
Nanolytics is pleased to have established a Scientific Advisory Board whose members are three of the leading experts in Analytical Ultracentrifugation (AUC) and its various applications.
The purpose of the Board is to lend critical support in staying ahead of the state of the art of scientific and technological developments in AUC which still mainly rely on the efforts of its users.
Furthermore, Nanolytics has been participating in the Open AUC Project to efficiently focus the capabilities of the community to advance the AUC hardware and software . The Open AUC strategy facilitates collaborations, encourages sharing, and eliminates the chronic impediments that have plagued AUC innovation for the last 20 years.
Accordingly, the implementation of the Scientific Advisory Board enhances the expertise of Nanolytics to optimally exploit the scientific potential of AUC for the needs of the clients.
: Cölfen, H., Laue, T.M., Wohlleben, W., Schilling, K., Karabudak, E., Langhors,t B.W., Brookes, E., Dubbs, B., Zollars, D., Rocco, M., Demeler, B. The Open AUC Project. Eur. Biophys. J. 2010, 39, 347–359.
Professor for Physical Chemistry
Department of Chemistry
D-78457 Konstanz, Germany
Web page: cms.uni-konstanz.de/coelfen
Helmut Cölfen is listed in the Thomson Reuters list of top 100 chemists worldwide for the years 2000–2010, having achieved an outstanding publication record of more than 200 publications (h-index: 46, at 12/2010). Moreover, he is reviewer for more than 100 scientific journals.
The group of Helmut Cölfen investigates various crystalline systems and nucleation mechanisms mainly under the topic „From biominerals to novel bioinspired materials.“
A major methodical focus is on developing new optical detection systems with the final goal of a multidetector AUC capable of simultaneous determination of several complimentary physicochemical quantities or to utilize the power of this fractionating method for complex colloidal systems – also in a global analysis approach with other techniques.
Associate Professor, Department of Biochemistry
Director, Center for Analytical Ultracentrifugation of Macromolecular Assemblies (CAUMA)
Director, Center for Light Scattering
Director, Bioinformatics Core Facility (BCF)
The University of Texas Health Science Center at San Antonio
Department of Biochemistry
San Antonio, Texas 78229-3900, USA
Web page: www.demeler.uthscsa.edu
Borries Demeler is author of more than 90 publications.
The main project involves the development of the UltraScan data analysis software package (www.ultrascan.uthscsa.edu). This software is used for modeling of hydrodynamic and thermodynamic properties of biological and synthetic macromolecules, and interactions and thermodynamic characteristics of macromolecular assemblies. Areas of research involve advanced numerical analysis, optimization, high-performance network computing and cluster computing. The current focus is on the development of software for the interpretation of multiwavelength sedimentation velocity experiments, and on spectral decomposition of analytical ultracentrifugation experiments.
Thomas M. Laue
Professor of the Department of Molecular, Cellular and Biomedical Science
Director of the Center to Advance Molecular Interaction Science (CAMIS)
Director of the Biomolecular Interaction Technologies Center
Department of Biochemistry and Molecular Biology,
University of New Hampshire
Durham, NH 03824, USA
Web page: camis.sr.unh.edu/camis/personnel/laue.html
Tom Laue is author of more than 100 publications.
The research in Laue´s laboratory is directed toward the development of direct physical methods for determining properties of macromolecules, including mass, charge, size, shape, and solubility, as well as the state of aggregation and the extent of ligand binding.
Along with standard optical methods, his lab has developed novel instrumentation for sedimentation analysis, in particular an efficient interference detector (which was introduced into the Beckman Coulter XLI analytical centrifuge) and a fluorescence detection system (FDS, available as a third party add-on), and for charge analysis (capillary electrophoresis, membrane-confined analytical electrophoresis, MCE). These methods are being applied to a wide range of macromolecular interactions, including those in blood coagulation, DNA transcriptional regulation, viral DNA integration, and gel formation.