Quantitative prediction of human pharmacokinetic responses to drugs via fluidically coupled vascularized organ chips A Herland, BM Maoz, D Das, MR Somayaji, R Prantil-Baun, R Novak, ... Nature biomedical engineering 4 (4), 421-436, 2020 | 302 | 2020 |
Robotic fluidic coupling and interrogation of multiple vascularized organ chips R Novak, M Ingram, S Marquez, D Das, A Delahanty, A Herland, BM Maoz, ... Nature biomedical engineering 4 (4), 407-420, 2020 | 294 | 2020 |
Modeling of spray droplets deformation and breakup EA Ibrahim, HQ Yang, AJ Przekwas Journal of Propulsion and Power 9 (4), 651-654, 1993 | 269 | 1993 |
A multi-organ chip with matured tissue niches linked by vascular flow K Ronaldson-Bouchard, D Teles, K Yeager, DN Tavakol, Y Zhao, ... Nature Biomedical Engineering 6 (4), 351-371, 2022 | 182 | 2022 |
A comparative study of advanced shock-capturing shcemes applied to Burgers' equation HQ Yang, AJ Przekwas Journal of Computational Physics 102 (1), 139-159, 1992 | 178 | 1992 |
Impinging jets atomization EA Ibrahim, AJ Przekwas Physics of Fluids A: Fluid Dynamics 3 (12), 2981-2987, 1991 | 176 | 1991 |
A coupled pressure-based computational method for incompressible/compressible flows ZJ Chen, AJ Przekwas Journal of Computational Physics 229 (24), 9150-9165, 2010 | 153 | 2010 |
Physiologically based pharmacokinetic and pharmacodynamic analysis enabled by microfluidically linked organs-on-chips R Prantil-Baun, R Novak, D Das, MR Somayaji, A Przekwas, DE Ingber Annual review of pharmacology and toxicology 58, 37-64, 2018 | 151 | 2018 |
Mathematical models of blast-induced TBI: current status, challenges, and prospects RK Gupta, A Przekwas Frontiers in neurology 4, 43326, 2013 | 144 | 2013 |
Numerical and analytical study of fluid dynamic forces in seals and bearings LT Tam, AJ Przekwas, A Muszynska, RC Hendricks, MJ Braun, RL Mullen | 104 | 1988 |
Implicit, pressure-based incompressible Navier-Stokes equations solver for unstructured meshes Y Jiang, A Przekwas 32nd Aerospace Sciences Meeting and Exhibit, 305, 1994 | 72 | 1994 |
General strong conservation formulation of Navier-Stokes equations in nonorthogonal curvilinear coordinates HQ Yang, SD Habchi, AJ Przekwas AIAA journal 32 (5), 936-941, 1994 | 65 | 1994 |
Washing hands and the face may reduce COVID-19 infection A Przekwas, Z Chen Medical hypotheses 144, 110261, 2020 | 64 | 2020 |
Synaptic mechanisms of blast-induced brain injury A Przekwas, MR Somayaji, RK Gupta Frontiers in neurology 7, 144857, 2016 | 61 | 2016 |
A 2n tree based automated viscous Cartesian grid methodology for feature capturing ZJ Wang, RF Chen, N Hariharan, AJ Przekwas, D Grove AIAA paper 3300, 1999, 1999 | 57 | 1999 |
Pharmaceutical aerosols deposition patterns from a Dry Powder Inhaler: Euler Lagrangian prediction and validation RR Kannan, AJ Przekwas, N Singh, R Delvadia, G Tian, R Walenga Medical engineering & physics 42, 35-47, 2017 | 52 | 2017 |
Computational modeling of blast wave interaction with a human body and assessment of traumatic brain injury XG Tan, AJ Przekwas, RK Gupta Shock Waves 27, 889-904, 2017 | 47 | 2017 |
A finite-volume method for fluid flow simulations with moving boundaries YG Lai, AJ Przekwas International Journal of Computational Fluid Dynamics 2 (1), 19-40, 1994 | 47 | 1994 |
Combination therapy for multi-target manipulation of secondary brain injury mechanisms MR Somayaji, AJ Przekwas, RK Gupta Current Neuropharmacology 16 (4), 484-504, 2018 | 36 | 2018 |
A computational model to detect and quantify a primary blast lung injury using near‐infrared optical tomography R Kannan, A Przekwas International Journal for Numerical Methods in Biomedical Engineering 27 (1 …, 2011 | 36 | 2011 |