Peter Pivonka
Peter Pivonka
Queensland University of Technology, School of Mechanical, Medical and Process Engineering
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Cited by
Cited by
Model structure and control of bone remodeling: a theoretical study
P Pivonka, J Zimak, DW Smith, BS Gardiner, CR Dunstan, NA Sims, ...
Bone 43 (2), 249-263, 2008
In situ handheld three‐dimensional bioprinting for cartilage regeneration
C Di Bella, S Duchi, CD O'Connell, R Blanchard, C Augustine, Z Yue, ...
Journal of tissue engineering and regenerative medicine 12 (3), 611-621, 2018
Theoretical investigation of the role of the RANK–RANKL–OPG system in bone remodeling
P Pivonka, J Zimak, DW Smith, BS Gardiner, CR Dunstan, NA Sims, ...
Journal of Theoretical Biology 262 (2), 306-316, 2010
Microscopic effects on chloride diffusivity of cement pastes—a scale-transition analysis
P Pivonka, C Hellmich, D Smith
Cement and Concrete Research 34 (12), 2251-2260, 2004
Handheld co-axial bioprinting: application to in situ surgical cartilage repair
S Duchi, C Onofrillo, CD O’Connell, R Blanchard, C Augustine, ...
Scientific reports 7 (1), 1-12, 2017
Coupling systems biology with multiscale mechanics, for computer simulations of bone remodeling
S Scheiner, P Pivonka, C Hellmich
Computer Methods in Applied Mechanics and Engineering 254, 181-196, 2013
Mathematical modeling in bone biology: From intracellular signaling to tissue mechanics
P Pivonka, SV Komarova
Bone 47 (2), 181-189, 2010
The influence of bone surface availability in bone remodelling—a mathematical model including coupled geometrical and biomechanical regulations of bone cells
P Pivonka, PR Buenzli, S Scheiner, C Hellmich, CR Dunstan
Engineering Structures 47, 134-147, 2013
Role of mathematical modeling in bone fracture healing
P Pivonka, CR Dunstan
BoneKEy reports 1, 2012
Spatio-temporal structure of cell distribution in cortical bone multicellular units: a mathematical model
PR Buenzli, P Pivonka, DW Smith
Bone 48 (4), 918-926, 2011
Femoral shaft strains during daily activities: implications for atypical femoral fractures
S Martelli, P Pivonka, PR Ebeling
Clinical Biomechanics 29 (8), 869-876, 2014
The effect of cyclic deformation and solute binding on solute transport in cartilage
L Zhang, BS Gardiner, DW Smith, P Pivonka, A Grodzinsky
Archives of biochemistry and biophysics 457 (1), 47-56, 2007
Comparative studies of 3D‐constitutive models for concrete: application to mixed‐mode fracture
P Pivonka, J Ožbolt, R Lackner, HA Mang
International journal for numerical methods in engineering 60 (2), 549-570, 2004
The application of pulsed electromagnetic fields (PEMFs) for bone fracture repair: past and perspective findings
C Daish, R Blanchard, K Fox, P Pivonka, E Pirogova
Annals of biomedical engineering 46 (4), 525-542, 2018
Poromicromechanics reveals that physiological bone strains induce osteocyte-stimulating lacunar pressure
S Scheiner, P Pivonka, C Hellmich
Biomechanics and modeling in mechanobiology 15 (1), 9-28, 2016
Theoretical analysis of anion exclusion and diffusive transport through platy-clay soils
D Smith, P Pivonka, C Jungnickel, S Fityus
Transport in porous media 57 (3), 251-277, 2004
Characterization of drug-release kinetics in trabecular bone from titania nanotube implants
MS Aw, KA Khalid, K Gulati, GJ Atkins, P Pivonka, DM Findlay, D Losic
International journal of nanomedicine 7, 4883, 2012
A multiscale mechanobiological model of bone remodelling predicts site-specific bone loss in the femur during osteoporosis and mechanical disuse
C Lerebours, PR Buenzli, S Scheiner, P Pivonka
Biomechanics and modeling in mechanobiology 15 (1), 43-67, 2016
Comparative study of methods used to estimate ionic diffusion coefficients using migration tests
GA Narsilio, R Li, P Pivonka, DW Smith
Cement and Concrete Research 37 (8), 1152-1163, 2007
A mathematical multiscale model of bone remodeling, accounting for pore space-specific mechanosensation
MI Pastrama, S Scheiner, P Pivonka, C Hellmich
Bone 107, 208-221, 2018
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