Resultats globals: 2 registres trobats en 0.02 segons.
Articles, 2 registres trobats
Articles 2 registres trobats  
1.
30 p, 759.1 KB Nanomechanics on FGF-2 and heparin reveal slip bond characteristics with pH dependency / Sevim, Semih (Bogazici University. Department of Electrical and Electronics Engineering) ; Ozer, Sevil (Bogazici University. Department of Electrical and Electronics Engineering) ; Jones, Gabriel (Universität Würzburg. Institute of Pharmacy and Food Chemistry) ; Wurzel, Joel (Universität Würzburg. Institute of Pharmacy and Food Chemistry) ; Feng, Luying (Bogazici University. Department of Electrical and Electronics Engineering) ; Fakhraee, Arielle (Aeon Scientific AG) ; Shamsudhin, Naveen (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Ergeneman, Olga (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Pellicer Vilà, Eva M. (Eva Maria) (Universitat Autònoma de Barcelona. Departament de Física) ; Sort Viñas, Jordi (Universitat Autònoma de Barcelona. Departament de Física) ; Pané i Vidal, Salvador (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Nelson, Bradley J. (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Torun, Hamdi (Bogazici University. Department of Electrical and Electronics Engineering) ; Lühmann, Tessa (Universität Würzburg. Institute of Pharmacy and Food Chemistry)
Fibroblast growth factor 2 (FGF-2), an important paracrine growth factor, binds electrostatically with low micromolar affinity to heparan sulfates present on extracellular matrix proteins. A single molecular analysis served as a basis to decipher the nanomechanical mechanism of the interaction between FGF-2 and the heparan sulfate surrogate, heparin, with a modular atomic force microscope (AFM) design combining magnetic actuators with force measurements at the low force regime (1 × 10¹ to 1 × 10⁴ pN/s). [...]
2017 - 10.1021/acsbiomaterials.6b00723
ACS biomaterials science & engineering, Vol. 3, issue 6 (2017) , p. 1000–1007  
2.
19 p, 606.3 KB Dually actuated atomic force microscope with miniaturized magnetic bead-actuators for single-molecule force measurements / Sevim, Semih (Bogazici University. Department of Electrical and Electronics Engineering) ; Ozer, Sevil (Bogazici University. Department of Electrical and Electronics Engineering) ; Feng, Luying (Bogazici University. Department of Electrical and Electronics Engineering) ; Wurzel, Joel (University of Würzburg. Institute of Pharmacy and Food Chemistry) ; Fakhraee, Arielle (Aeon Scientific AG) ; Shamsudhin, Naveen (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Jang, Bumjin (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Alcantara, Carlos (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Ergeneman, Olgaç (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Pellicer Vilà, Eva M. (Eva Maria) (Universitat Autònoma de Barcelona. Departament de Física) ; Sort Viñas, Jordi (Institució Catalana de Recerca i Estudis Avançats) ; Lühmann, Tessa (University of Würzburg. Institute of Pharmacy and Food Chemistry) ; Pané i Vidal, Salvador (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Nelson, Bradley J. (ETH Zurich. Institute of Robotics and Intelligent Systems) ; Torun, Hamdi (Bogazici University. Department of Electrical and Electronics Engineering)
We report for the first time on a novel Atomic Force Microscopy (AFM) technique with dual actuation capabilities using both piezo and magnetic bead actuation for advanced single-molecule force spectroscopy experiments. [...]
2016 - 10.1039/c6nh00134c
Nanoscale Horizons, Vol. 1, Issue 6 (November 2016) , p. 488-495  

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