| Making optimal use of empirical energy functions: force‐field parameterization in crystal space E Krieger, T Darden, SB Nabuurs, A Finkelstein, G Vriend Proteins: Structure, Function, and Bioinformatics 57 (4), 678-683, 2004 | 1006 | 2004 |
| Protein physics: a course of lectures (soft condensed matter, complex fluids and biomaterials) AV Finkelstein, O Ptitsyn Protein physics: a course of lectures (soft condensed matter, complex fluids …, 2016 | 670* | 2016 |
| Contact order revisited: influence of protein size on the folding rate DN Ivankov, SO Garbuzynskiy, E Alm, KW Plaxco, D Baker, AV Finkelstein Protein science 12 (9), 2057-2062, 2003 | 449 | 2003 |
| The classification and origins of protein folding patterns C Chothia, AV Finkelstein Annual review of biochemistry 59 (1), 1007-1035, 1990 | 427 | 1990 |
| The price of lost freedom: entropy of bimolecular complex formation AV Finkelstein, J Janin Protein Engineering, Design and Selection 3 (1), 1-3, 1989 | 404 | 1989 |
| A theoretical search for folding/unfolding nuclei in three-dimensional protein structures OV Galzitskaya, AV Finkelstein Proceedings of the National Academy of Sciences 96 (20), 11299-11304, 1999 | 381 | 1999 |
| Theory of cooperative transitions in protein molecules. I. Why denaturation of globular protein is a first‐order phase transition EI Shakhnovich, AV Finkelstein Biopolymers: Original Research on Biomolecules 28 (10), 1667-1680, 1989 | 374 | 1989 |
| Why do globular proteins fit the limited set of folding patterns? AV Finkelstein, OB Ptitsyn Progress in biophysics and molecular biology 50 (3), 171-190, 1987 | 343 | 1987 |
| Theory of protein secondary structure and algorithm of its prediction OB Ptitsyn, AV Finkelstein Biopolymers: Original Research on Biomolecules 22 (1), 15-25, 1983 | 334 | 1983 |
| What is the probability of a chance prediction of a protein structure with an RMSD of 6 A? SJ Reva BA, Finkelstein AV Folding & Design 3, 141-147, 1998 | 282* | 1998 |
| Prediction of protein folding rates from the amino acid sequence-predicted secondary structure DN Ivankov, AV Finkelstein Proceedings of the National Academy of Sciences 101 (24), 8942-8944, 2004 | 251 | 2004 |
| Similarities of protein topologies: evolutionary divergence, functional convergence or principles of folding? OB Ptitsyn, AV Finkelstein Quarterly Reviews of Biophysics 13 (3), 339-386, 1980 | 248 | 1980 |
| Rate of protein folding near the point of thermodynamic equilibrium between the coil and the most stable chain fold AV Finkelstein, AY Badretdinov Folding and Design 2 (2), 115-121, 1997 | 234 | 1997 |
| Why do protein architectures have Boltzmann‐like statistics? AV Finkelstein, AY Badretdinov, AM Gutin Proteins: Structure, Function, and Bioinformatics 23 (2), 142-150, 1995 | 232 | 1995 |
| Theory of cooperative transitions in protein molecules. II. Phase diagram for protein molecule in solution , 1989, 28: 1681-1694. SEI Finkelstein A.V. Biopolymers 28, 1681-1694, 1989 | 194* | 1989 |
| Chain length is the main determinant of the folding rate for proteins with three‐state folding kinetics OV Galzitskaya, SO Garbuzynskiy, DN Ivankov, AV Finkelstein Proteins: Structure, Function, and Bioinformatics 51 (2), 162-166, 2003 | 184 | 2003 |
| A Search for the Most Stable Folds of Protein Chains RBA Finkelstein AV Nature 351, 497-499, 1991 | 182 | 1991 |
| Comparison of predicted and experimentally determined secondary structure of adenyl kinase NK Schulz G.E., Barry C.D., Friedman J., Chou P.Y., Fasman G.D., Finkelstein ... Nature 250, 140-142, 1974 | 180 | 1974 |
| General architecture of the α-helical globule AG Murzin, AV Finkelstein Journal of molecular biology 204 (3), 749-769, 1988 | 163 | 1988 |
| Physics of protein folding AV Finkelstein, OV Galzitskaya Physics of Life reviews 1 (1), 23-56, 2004 | 148 | 2004 |
Oxana GalzitskayaInstitute of Protein Research, Group of Bioinformatics在 vega.protres.ru 的电子邮件经过验证
