The library will operate on a duty schedule between 22 December 2025 and 4 January 2026. During this period, it will be possible to upload publications, but all other services will be suspended.
Szalóki, M.,
Csarnovics, I.,
Bonyár, A.,
Ungor, D.,
Csapó, E.,
Sápi, A.,
Hegedűs, C.:
Plasmonic Effect of Gold-Patchy Silica Nanoparticles on Green Light-Photopolymerizable Dental Resin.
Nanomaterials. 13 (18), 1-16, (article identifier: 2554), 2023.
Csapó, E.,
Buglyó, P.,
Nagy, N. V.,
Santos, A. M.,
Corona, A.,
Farkas, E.:
Syntheses and characterization of Cu2+, Ni2+ and Zn2+ binding capability of histidinehydroxamic acid derivatives.
Polyhedron. 29 (16), 3137-3145, 2010.
Jarenmark, M.,
Csapó, E.,
Singh, J.,
Wockel, S.,
Farkas, E.,
Meyer, F.,
Haukka, M.,
Nordlander, E.:
Unsymmetrical dizinc complexes as models for the active sites of phosphohydrolases.
Dalton Trans. 39, 8183-8194, 2010.
Farkas, E.,
Csapó, E.,
Buglyó, P.,
Damante, C. A.,
Di Natale, G.:
Metal-binding ability of histidine-containing peptidehydroxamic acids: Imidazole versus hydroxamate coordination.
Inorg. Chim. Acta. 362 (3), 753-762, 2009.
Farkas, E.,
Csapó, E.,
Buglyó, P.:
Effects of imidazole containing Rc substituents on the metal binding capability of potentially metalloenzyme inhibitor hydroxamic acids.
Metal ions in biology and medicine. 10, 393-398, 2008.
Farkas, E.,
Bátka, D.,
Csapó, E.,
Buglyó, P.,
Haase, W.,
Sanna, D.:
Synthesis and characterization of Cu2+, Ni2+ and Zn2+ binding capability of some amino- and imidazole hydroxamic acids: effects of substitution of side chain amino-N for imidazole-N or hydroxamic-N-H for -N-CH3 on metal complexation.
Polyhedron. 26 (3), 543-554, 2007.
