Modeling viscoelastic behavior of arterial walls and their interaction with pulsatile blood flow S Čanić, J Tambača, G Guidoboni, A Mikelić, CJ Hartley, D Rosenstrauch SIAM Journal on Applied Mathematics 67 (1), 164-193, 2006 | 167 | 2006 |
Fluid–structure interaction in blood flow capturing non-zero longitudinal structure displacement M Bukač, S Čanić, R Glowinski, J Tambača, A Quaini Journal of Computational Physics 235, 515-541, 2013 | 148 | 2013 |
Blood flow in compliant arteries: an effective viscoelastic reduced model, numerics, and experimental validation S Čanić, CJ Hartley, D Rosenstrauch, J Tambača, G Guidoboni, A Mikelić Annals of Biomedical Engineering 34, 575-592, 2006 | 148 | 2006 |
Self-consistent effective equations modeling blood flow in medium-to-large compliant arteries S Canic, D Lamponi, A Mikelic, J Tambaca Multiscale Modeling & Simulation 3 (3), 559-596, 2005 | 105 | 2005 |
A two-dimensional effective model describing fluid–structure interaction in blood flow: analysis, simulation and experimental validation S Čanić, A Mikelić, J Tambača Comptes Rendus Mécanique 333 (12), 867-883, 2005 | 69 | 2005 |
Fluid–structure interaction between pulsatile blood flow and a curved stented coronary artery on a beating heart: A four stent computational study M Bukač, S Čanić, J Tambača, Y Wang Computer methods in applied mechanics and engineering 350, 679-700, 2019 | 60 | 2019 |
Mathematical modeling of vascular stents J Tambača, M Kosor, S Čanić, DP MD SIAM journal on applied mathematics 70 (6), 1922-1952, 2010 | 56 | 2010 |
Linear curved rod model: general curve M Jurak, J Tambača Mathematical models and methods in applied sciences 11 (07), 1237-1252, 2001 | 51 | 2001 |
Derivation and justification of a curved rod model M Jurak, J Tambača Mathematical Models and Methods in Applied Sciences 9 (07), 991-1014, 1999 | 50 | 1999 |
Mechanical behavior of fully expanded commercially available endovascular coronary stents J Tambaca, S Canic, M Kosor, RD Fish, D Paniagua Texas Heart Institute Journal 38 (5), 491, 2011 | 47 | 2011 |
Derivation and justification of the models of rods and plates from linearized three-dimensional micropolar elasticity I Aganović, J Tambača, Z Tutek Journal of elasticity 84, 131-152, 2006 | 44 | 2006 |
Effective model of the fluid flow through elastic tube with variable radius J Tambača, S Čanić, A Mikelić Grazer Mathematische Berichte 348, 91-112, 2005 | 27 | 2005 |
Cardiovascular stents as PDE nets: 1D vs. 3D S Čanić, J Tambača Ima journal of applied mathematics 77 (6), 748-770, 2012 | 24 | 2012 |
Integrated stent models based on dimension reduction: review and future perspectives P Zunino, J Tambača, E Cutrì, S Čanić, L Formaggia, F Migliavacca Annals of biomedical engineering 44, 604-617, 2016 | 20 | 2016 |
Derivation and justification of the model of micropolar elastic shells from three-dimensional linearized micropolar elasticity I Aganović, J Tambača, Z Tutek Asymptotic Analysis 51 (3-4), 335-361, 2007 | 16 | 2007 |
A new linear Naghdi type shell model for shells with little regularity J Tambača, Z Tutek Applied Mathematical Modelling 40 (23-24), 10549-10562, 2016 | 15 | 2016 |
Blood flow through axially symmetric sections of compliant vessels: new effective closed models S Canic, J Tambaca, A Mikelic, CJ Hartley, D Mirkovic, J Chavez, ... The 26th Annual International Conference of the IEEE Engineering in Medicine …, 2004 | 15 | 2004 |
A model of irregular curved rods J Tambača Applied mathematics and scientific computing, 289-299, 2003 | 15 | 2003 |
A new linear shell model for shells with little regularity J Tambača Journal of elasticity 117 (2), 163-188, 2014 | 14 | 2014 |
Existence theorem for nonlinear micropolar elasticity J Tambača, I Velčić ESAIM: Control, Optimisation and Calculus of Variations 16 (1), 92-110, 2010 | 14 | 2010 |