Mantegazza, A., De Marinis, D., & de Tullio, M. D. (2024). Red blood cell transport in bounded shear flow: On the effects of cell viscoelastic properties. Computer Methods in Applied Mechanics and Engineering, 428, 117088 [Link].
Torre, M., Morganti, S., Nitti, A., de Tullio, M. D., Kiendl, J., Pasqualini, F. S., & Reali, A. (2024). An efficient active-stress electromechanical isogeometric shell model for muscular thin film simulations. Mechanics of Materials, 195, 105046 [Link].
Wang, J., Nitti, A., & de Tullio, M. D. (2024). Self-excited flapping motion of wall-mounted valvular leaflets in a three-dimensional channel flow. Physics of Fluids, 36, 061903 [Link].
De Marinis, D., Mantegazza, A., Coclite, A., & de Tullio, M. D. (2024). A fluid-structure interaction method for soft particle transport in curved microchannels. Computer Methods in Applied Mechanics and Engineering, 418, 116592 [Link].
Nitti, A., Torre, M., Reali, A., Kiendl, J., & de Tullio, M. D. (2023). A multiphysics model for fluid-structure-electrophysiology interaction in rowing propulsion. Applied Mathematical Modelling,124, 414-444 [Link].
Torre, M., Morganti, S., Nitti, A., de Tullio, M. D., Pasqualini, F. S., & Reali, A. (2023). Isogeometric mixed collocation of nearly-incompressible electromechanics in finite deformations for cardiac muscle simulations. Computer Methods in Applied Mechanics and Engineering, 411, 116055 [Link].
Tirri, A., Nitti, A., Sierra-Ausin, J., Giannetti, F., de Tullio, M. D. (2023). Linear stability analysis of fluid–structure interaction problems with an immersed boundary method. Journal of Fluids and Structures, 117, 103830 [Link].
Pricci, A., de Tullio, M.D., Percoco, G. (2023). Modeling of extrusion-based additive manufacturing for pelletized thermoplastics: Analytical relationships between process parameters and extrusion outcomes. CIRP Journal of Manufacturing Science and Technology, 41, 239–258 [Link].
Coclite, A., de Tullio, M. D., Pascazio, G., Politi, T. (2022). Characterization of micro-capsules deformation in branching channels. Applied Mathematics and Computation, 434, 127445.0 [Link].
Nitti, A., De Cillis, G., de Tullio, M. D. (2022). Cross-flow oscillations of a circular cylinder with mechanically coupled rotation. Journal of Fluid Mechanics, 943. [Link].
Gallo, D., Morbiducci, U., de Tullio, M. D. (2022). On the unexplored relationship between kinetic energy and helicity in prosthetic heart valves hemodynamics. International Journal of Engineering Science, 177, 103702 [Link].
Nitti, A., De Cillis, G., de Tullio, M. D. (2022). Numerical investigation of turbulent features past different mechanical aortic valves. Journal of Fluid Mechanics, 940 [Link].
Torre, M., Morganti, S., Nitti, A., de Tullio, M. D., Pasqualini, F. S., Reali, A. (2022). An efficient isogeometric collocation approach to cardiac electrophysiology. Computer Methods in Applied Mechanics and Engineering, 393, 114782 [Link].
Viola, F., Spandan, V., Meschini, V., Romero, J., Fatica, M., de Tullio, M. D., Verzicco, R. (2022). FSEI-GPU: GPU accelerated simulations of the fluid-structure-electrophysiology interaction in the left heart. Computer physics communications, 273, 108248 [Link].
Pricci, A., de Tullio, M.D., Percoco, G. (2022). Semi-analytical models for non-Newtonian fluids in tapered and cylindrical ducts, applied to the extrusion-based additive manufacturing. Materials and Design, 223, 111168 [Link].
Nitti, A., Kiendl, J., Gizzi, A., Reali, A., de Tullio, M.D. (2021). A curvilinear isogeometric framework for the electromechanical activation of thin muscular tissues. Computer Methods in Applied Mechanics and Engineering, 382,113877 [Link].
Zeraatkar, M., de Tullio, M.D., Pricci, A., Pignatelli, F., Percoco, G. (2021). Exploiting limitations of fused deposition modeling to enhance mixing in 3D printed microfluidic devices. Rapid Prototyping Journal, 27(10), 1850 [Link].
Pricci, A., de Tullio, M.D., Percoco, G. (2021). Analytical and numerical models of thermoplastics: A review aimed to pellet extrusion-based additive manufacturing. Polymers, 13(18),3160 [Link].
Zeraatkar, M., De Tullio, M.D., Percoco, G. (2021). Fused filament fabrication (FFF) for manufacturing of microfluidic micromixers: An experimental study on the effect of process variables in printed microfluidic micromixers. Micromachines, 12(8),858 [Link].
Nitti, A., Kiendl, J., Reali, A., de Tullio, M.D. (2020). An immersed-boundary/isogeometric method for fluid-structure interaction involving thin shells. Computer Methods in Applied Mechanics and Engineering, 364,112977 [Link].
Coclite, A., Ranaldo, S., Pascazio, G., de Tullio, M.D. (2020). A Lattice Boltzmann dynamic-Immersed Boundary scheme for the transport of deformable inertial capsules in low-Re flows. Computers and Mathematics with Applications, 80(12), 2860 [Link].
Coclite, A., Ranaldo, S., de Tullio, M.D., Decuzzi, P., Pascazio, G. (2019). Kinematic and dynamic forcing strategies for predicting the transport of inertial capsules via a combined lattice Boltzmann – Immersed Boundary method. Computers and Fluids, 180, 41 [Link].
Spandan, V., Lohse, D., de Tullio, M.D., Verzicco, R. (2018). A fast moving least squares approximation with adaptive Lagrangian mesh refinement for large scale immersed boundary simulations.Journal of Computational Physics, 375, 228 [Link].
Coclite, A., Pascazio, G., de Tullio, M.D., Decuzzi, P. (2018). Predicting the vascular adhesion of deformable drug carriers in narrow capillaries traversed by blood cells.Journal of Fluids and Structures, 82, 638 [Link].
Di Renzo, M., Urzay, J., De Palma, P., de Tullio, M.D., Pascazio, G. (2018). The effects of incident electric fields on counterflow diffusion flames.Combustion and Flame, 193, 177 [Link].
Meschini, V., De Tullio, M.D., Querzoli, G., Verzicco, R. (2018). Flow structure in healthy and pathological left ventricles with natural and prosthetic mitral valves.Journal of Fluid Mechanics, 834, 271 [Link].
Meschini, V., de Tullio, M.D., Verzicco, R. (2018). Effects of mitral chordae tendineae on the flow in the left heart ventricle.European Physical Journal E, 41(2),27 [Link].
Spandan, V., Meschini, V., Ostilla-Mónico, R., Lohse, D., Querzoli, G., de Tullio, M.D., Verzicco, R. (2017). A parallel interaction potential approach coupled with the immersed boundary method for fully resolved simulations of deformable interfaces and membranes. Journal of Computational Physics, 348, 567 [Link].
Di Renzo, M., De Palma, P., de Tullio, M.D., Pascazio, G. (2017). An efficient flamelet progress-variable method for modeling non-premixed flames in weak electric fields.Computers and Fluids, 157, 14 [Link].
Coclite, A., Mollica, H., Ranaldo, S., Pascazio, G., de Tullio, M.D., Decuzzi, P. (2017). Predicting different adhesive regimens of circulating particles at blood capillary walls.Microfluidics and Nanofluidics, 21(11),168 [Link].
Geraci, G., De Tullio, M.D., Iaccarino, G. (2017). Polynomial chaos assessment of design tolerances for vortex-induced vibrations of two cylinders in tandem.Artificial Intelligence for Engineering Design, Analysis and Manufacturing: AIEDAM, 31(2), 185 [Link].
de Tullio, M.D., Pascazio, G. (2016). A moving-least-squares immersed boundary method for simulating the fluid–structure interaction of elastic bodies with arbitrary thickness. Journal of Computational Physics, 325, 201 [Link].
De Vita, F., de Tullio, M.D., Verzicco, R. (2016). Numerical simulation of the non-Newtonian blood flow through a mechanical aortic valve: Non-Newtonian blood flow in the aortic root.Theoretical and Computational Fluid Dynamics, 30(1-2), 129 [Link].
Coclite, A., de Tullio, M.D., Pascazio, G., Decuzzi, P. (2016). A combined Lattice Boltzmann and Immersed boundary approach for predicting the vascular transport of differently shaped particles. Computers and Fluids, 136, 260 [Link].
De Marinis, D., De Tullio, M.D., Napolitano, M., Pascazio, G. (2016). Improving a conjugate-heattransfer immersed-boundary method.International Journal of Numerical Methods for Heat and Fluid Flow, 26(3-4), 1272 [Link].
Ezzeldin, H.M., de Tullio, M.D., Vanella, M., Solares, S.D., Balaras, E. (2015). A Strain-Based Model for Mechanical Hemolysis Based on a Coarse-Grained Red Blood Cell Model. Annals of Biomedical Engineering, 43(6), 1398 [Link].
Doronzo, D.M., Khalaf, E.A., Dellino, P., de Tullio, M.D., Dioguardi, F., Gurioli, L., Mele, D., Pascazio, G., Sulpizio, R. (2015). Local impact of dust storms around a suburban building in arid and semi-arid regions: numerical simulation examples from Dubai and Riyadh, Arabian Peninsula. Arabian Journal of Geosciences, 8(9), 7359 [Link].
Doronzo, D.M., de Tullio, M.D., Pascazio, G., Dellino, P., Liu, G. (2015). On the interaction between shear dusty currents and buildings in vertical collapse: Theoretical aspects, experimental observations, and 3D numerical simulation.Journal of Volcanology and Geothermal Research, 302, 190 [Link].
de Tullio, M.D., Singh, J., Pascazio, G., Decuzzi, P. (2014). Predicting the size-dependent tissue accumulation of agents released from vascular targeted nanoconstructs. Computational Mechanics, 53(3), 437 [Link].
Cherubini, S., De Tullio, M.D., De Palma, P., Pascazio, G. (2013). Transient growth in the flow past a three-dimensional smooth roughness element. Journal of Fluid Mechanics, 724, 642 [Link].
Stigliano, C., Aryal, S., de Tullio, M.D., Nicchia, G.P., Pascazio, G., Svelto, M., Decuzzi, P. (2013). SiRNA-chitosan complexes in poly(lactic-co-glycolic acid) nanoparticles for the silencing of aquaporin-1 in cancer cells.Molecular Pharmaceutics, 10(8), 3186 [Link].
Weltert, L., de Tullio, M.D., Afferrante, L., Salica, A., Scaffa, R., Maselli, D., Verzicco, R., De Paulis, R. (2013). Annular dilatation and loss of sino-tubular junction in aneurysmatic aorta: Implications on leaflet quality at the time of surgery. A finite element study.Interactive Cardiovascular and Thoracic Surgery, 17(1), 8 [Link].
de Tullio, M.D., Nam, J., Pascazio, G., Balaras, E., Verzicco, R. (2012). Computational prediction of mechanical hemolysis in aortic valved prostheses.European Journal of Mechanics, B/Fluids, 35, 47 [Link].
Adriani, G., de Tullio, M.D., Ferrari, M., Hussain, F., Paacazio, G., Liu, X., Decuzzi, P. (2012). The preferential targeting of the diseased microvasculature by disk-like particles. Biomaterials, 33(22), 5504 [Link].
de Tullio, M.D., Pedrizzetti, G., Verzicco, R. (2011). On the effect of aortic root geometry on the coronary entry-flow after a bileaflet mechanical heart valve implant: A numerical study.Acta Mechanica, 216(1-4), 147 [Link].
de Tullio, M.D., Afferrante, L., Demelio, G., Pascazio, G., Verzicco, R. (2011). Fluid-structure interaction of deformable aortic prostheses with a bileaflet mechanical valve. Journal of Biomechanics, 44(9), 1684 [Link].
Doronzo, D.M., de Tullio, M.D., Dellino, P., Pascazio, G. (2011). Numerical simulation of pyroclastic density currents using locally refined Cartesian grids. Computers and Fluids, 44(1), 56 [Link].
Valentine, G.A., Doronzo, D.M., Dellino, P., de Tullio, M.D. (2011). Effects of volcano profile on dilute pyroclastic densty currents: Numerical simulations. Geology, 39(10), 947 [Link].
Doronzo, D.M., Valentine, G.A., Dellino, P., de Tullio, M.D. (2010). Numerical analysis of the effect of topography on deposition from dilute pyroclastic density currents. Earth and Planetary Science Letters, 300(1-2), 164 [Link].
de Tullio, M.D., Cristallo, A., Balaras, E., Verzicco, R. (2009). Direct numerical simulation of the pulsatile flow through an aortic bileaflet mechanical heart valve. Journal of Fluid Mechanics, 622, 259 [Link].
de Tullio, M.D., De Palma, P., Iaccarino, G., Pascazio, G., Napolitano, M. (2007). An immersed boundary method for compressible flows using local grid refinement. Journal of Computational Physics, 225(2), 2098 [Link].
De Palma, P., de Tullio, M.D., Pascazio, G., Napolitano, M. (2006). An immersed-boundary method for compressible viscous flows. Computers and Fluids, 35(7), 702 [Link].
