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1. Adsorption of Human Plasma Albumin and Fibronectin onto Nanostructured Black Silicon Surfaces Langmuir: 10.1021/acs.langmuir.6b02601 (2016) Duy H. K. Nguyen, Vy T. H. Pham, Mohammad Al Kobaisi, Chris M. Bhadra, Anna Orlowska, Shahram Ghanaati, Berardo Mario Manzi, Vladimir A Baulin, Saulius Juodkazis, Peter Kingshott, Russell J Crawford, and Elena P. Ivanova The protein adsorption of two human plasma proteins, albumin (Alb) and fibronectin (Fn) onto synthetic nanostructured bactericidal material, black silicon [...]...
2. Bactericidal activity of black silicon Nature Comm., 4, 2838 (2013) E. P. Ivanova, J. Hasan, H. K. Webb, G. Gervinskas, S. Juodkazis, Vi K. Truong, A. H. F. Wu, R. N. Lamb, V. A. Baulin, G. S. Watson, J. A. Watson, D. E. Mainwaring, R. J. Crawford  Black silicon is a synthetic nanomaterial that contains high aspect ratio nanoprotrusions on its surface, produced through a simple reactive-ion etching technique for use in photovoltaic applications. Surfaces with high [...]...
3. Homo-polymers with balanced hydrophobicity translocate through lipid bilayers and enhance local solvent permeability Marco Werner, Jens-Uwe Sommer and Vladimir A. Baulin Soft Matter, 8, 11708-11716 (2012) Recent experimental studies indicate that polymeric structures with a well-adjusted balance of amphiphilic parts may translocate through self-assembled phospholipid bilayers and enhance the passive trans-membrane transport of smaller molecules. Using a coarse grained lattice Monte Carlo model with explicit solvent we investigate self-assembled lipid [...]...
4. Nanoparticle-Induced Permeability of Lipid Membranes Sergey Pogodin, Marco Werner, Jens-Uwe Sommer, Vladimir A. Baulin ACS Nano, DOI: 10.1021/nn3028858 (2012) Monte Carlo simulations using the bond fluctuation method with explicit solvent reveal the mechanism of enhanced permeability of lipid bilayers induced by the adsorption of nanoparticles with controlled hydrophobicity. Simulation results indicate an adsorption transition of nanoparticles on the bilayer in a [...]...
5. Collision induced spatial organization of microtubules V.A. Baulin, C.M. Marques, F. Thalmann Biophysical Chemistry, 128(2-3), 231 – 244 (2007) The dynamic behavior of microtubules in solution can be strongly modified by interactions with walls or other structures. We examine here a microtubule growth model where the increase in size of the plus-end is perturbed by collisions with other microtubules. We show that [...]...