Identifiability of chemical reaction networks G Craciun, C Pantea Journal of Mathematical Chemistry 44 (1), 244-259, 2008 | 197 | 2008 |
Persistence and permanence of mass-action and power-law dynamical systems G Craciun, F Nazarov, C Pantea SIAM Journal on Applied Mathematics 73 (1), 305-329, 2013 | 154 | 2013 |
On the persistence and global stability of mass-action systems C Pantea SIAM Journal on Mathematical Analysis 44 (3), 1636-1673, 2012 | 96 | 2012 |
Some results on injectivity and multistationarity in chemical reaction networks M Banaji, C Pantea SIAM Journal on Applied Dynamical Systems 15 (2), 807-869, 2016 | 64 | 2016 |
The inheritance of nondegenerate multistationarity in chemical reaction networks M Banaji, C Pantea SIAM Journal on Applied Mathematics 78 (2), 1105-1130, 2018 | 59 | 2018 |
Global injectivity and multiple equilibria in uni-and bi-molecular reaction networks C Pantea, H Koeppl, G Craciun Discrete Contin. Dyn. Syst. Ser. B 17 (6), 2153-2170, 2012 | 50 | 2012 |
CoNtRol: an open source framework for the analysis of chemical reaction networks P Donnell, M Banaji, A Marginean, C Pantea Bioinformatics 30 (11), 1633-1634, 2014 | 43 | 2014 |
The QSSA in chemical kinetics: as taught and as practiced C Pantea, A Gupta, JB Rawlings, G Craciun Discrete and topological models in molecular biology, 419-442, 2014 | 41 | 2014 |
A deficiency-based approach to parametrizing positive equilibria of biochemical reaction systems MD Johnston, S Müller, C Pantea Bulletin of Mathematical Biology 81, 1143-1172, 2019 | 31 | 2019 |
A generalization of Birch's theorem and vertex-balanced steady states for generalized mass-action systems G Craciun, S Muller, C Pantea, PY Yu arXiv preprint arXiv:1802.06919, 2018 | 24 | 2018 |
Combinatorial approaches to Hopf bifurcations in systems of interacting elements D Angeli, M Banaji, C Pantea Communications in Mathematical Sciences 12 (6), 1101-1133, 0 | 24* | |
Algebraic methods for inferring biochemical networks: a maximum likelihood approach G Craciun, C Pantea, GA Rempala Computational biology and chemistry 33 (5), 361-367, 2009 | 22 | 2009 |
A computational approach to persistence, permanence, and endotacticity of biochemical reaction systems MD Johnston, C Pantea, P Donnell Journal of mathematical biology 72, 467-498, 2016 | 18 | 2016 |
Graph-theoretic analysis of multistability and monotonicity for biochemical reaction networks G Craciun, C Pantea, ED Sontag Design and Analysis of Biomolecular Circuits: Engineering Approaches to …, 2011 | 18 | 2011 |
Multistationarity in biochemical networks: results, analysis, and examples C Conradi, C Pantea Algebraic and combinatorial computational biology, 279-317, 2019 | 16 | 2019 |
Statistical model for biochemical network inference G Craciun, J Kim, C Pantea, GA Rempala Communications in Statistics-Simulation and Computation 42 (1), 121-137, 2013 | 12 | 2013 |
Computational methods for analyzing bistability in biochemical reaction networks C Pantea, G Craciun Proceedings of 2010 IEEE International Symposium on Circuits and Systems …, 2010 | 12 | 2010 |
Delay stability of reaction systems G Craciun, M Mincheva, C Pantea, YY Polly Mathematical Biosciences 326, 108387, 2020 | 11 | 2020 |
Multistationarity in cyclic sequestration-transmutation networks G Craciun, B Joshi, C Pantea, I Tan Bulletin of Mathematical Biology 84 (6), 65, 2022 | 10 | 2022 |
Multistationarity in Biochemical Networks: Results, Analysis, and Examples. Algebraic and Combinatorial Computational Biology, Ch. 9, Eds. Robeva R. and Macaulay M … C Conradi, C Pantea Academic Press, 2019 | 9 | 2019 |