Dilatational band formation in bone AA Poundarik, T Diab, GE Sroga, A Ural, AL Boskey, CM Gundberg, ...
Proceedings of the National Academy of Sciences 109 (47), 19178-19183, 2012
263 2012 A direct role of collagen glycation in bone fracture AA Poundarik, PC Wu, Z Evis, GE Sroga, A Ural, M Rubin, D Vashishth
Journal of the mechanical behavior of biomedical materials 52, 120-130, 2015
148 2015 Three-dimensional, parallel, finite element simulation of fatigue crack growth in a spiral bevel pinion gear A Ural, G Heber, PA Wawrzynek, AR Ingraffea, DG Lewicki, JBC Neto
Engineering Fracture Mechanics 72 (8), 1148-1170, 2005
146 2005 Cohesive finite element modeling of age-related toughness loss in human cortical bone A Ural, D Vashishth
Journal of biomechanics 39 (16), 2974-2982, 2006
135 2006 A cohesive zone model for fatigue crack growth allowing for crack retardation A Ural, VR Krishnan, KD Papoulia
International Journal of Solids and Structures 46 (11-12), 2453-2462, 2009
134 2009 Delamination buckling and propagation analysis of honeycomb panels using a cohesive element approach TS Han, A Ural, CS Chen, AT Zehnder, AR Ingraffea, SL Billington
International Journal of Fracture 115, 101-123, 2002
98 2002 Multiscale modeling of bone fracture using cohesive finite elements A Ural, S Mischinski
Engineering Fracture Mechanics 103, 141-152, 2013
86 2013 Fracture mechanics approach to facesheet delamination in honeycomb: measurement of energy release rate of the adhesive bond A Ural, AT Zehnder, AR Ingraffea
Engineering Fracture Mechanics 70 (1), 93-103, 2003
77 2003 The effect of strain rate on fracture toughness of human cortical bone: a finite element study A Ural, P Zioupos, D Buchanan, D Vashishth
Journal of the mechanical behavior of biomedical materials 4 (7), 1021-1032, 2011
75 2011 Effects of Intracortical Porosity on Fracture Toughness in Aging Human Bone: A -Based Cohesive Finite Element Study A Ural, D Vashishth
75 2007 Finite element modeling of microcrack growth in cortical bone S Mischinski, A Ural
66 2011 Interactions between microstructural and geometrical adaptation in human cortical bone A Ural, D Vashishth
Journal of Orthopaedic Research 24 (7), 1489-1498, 2006
63 2006 Thermal enhancement and shape stabilization of a phase-change energy-storage material via copper nanowire aerogel L Zhang, L An, Y Wang, A Lee, Y Schuman, A Ural, AS Fleischer, G Feng
Chemical Engineering Journal 373, 857-869, 2019
62 2019 Interaction of microstructure and microcrack growth in cortical bone: a finite element study S Mischinski, A Ural
Computer methods in biomechanics and biomedical engineering 16 (1), 81-94, 2013
61 2013 Anisotropy of age-related toughness loss in human cortical bone: a finite element study A Ural, D Vashishth
Journal of biomechanics 40 (7), 1606-1614, 2007
61 2007 Hierarchical perspective of bone toughness–from molecules to fracture A Ural, D Vashishth
International Materials Reviews 59 (5), 245-263, 2014
59 2014 Prediction of Colles’ fracture load in human radius using cohesive finite element modeling A Ural
Journal of Biomechanics 42 (1), 22-28, 2009
52 2009 Assessment of the effect of reduced compositional heterogeneity on fracture resistance of human cortical bone using finite element modeling A Demirtas, E Curran, A Ural
Bone 91, 92-101, 2016
35 2016 Association between non-enzymatic glycation, resorption, and microdamage in human tibial cortices A Ural, C Janeiro, L Karim, T Diab, D Vashishth
Osteoporosis International 26, 865-873, 2015
33 2015 Mineralized collagen fibril network spatial arrangement influences cortical bone fracture behavior Y Wang, A Ural
Journal of biomechanics 66, 70-77, 2018
31 2018