Please refer to Google Scholar for more information.
| J39 | S. Jalalian, J. Weickenmeier. Alzheimer’s Disease Accelerates Cerebral Atrophy by Over a Decade Compared to Healthy Aging. Annals of Biomedical Engineering 2026; 170:1-22 (pdf) |
| J38 | N. Tueni, E. Griffiths, J. Weickenmeier, S. Rampp, S. Budday. Region-Dependent Mechanical Parameters in Simulating Cerebral Atrophy. APL Bioengineering 2026; 10:016104 (pdf) |
| J37 | X. Zhang, M. El Hamdaoui, S. Lim, R. Grytz, J. Weickenmeier. Microindentation Reveals Softening Of The Equatorial And Anterior Sclera During Early Myopia Development In Tree Shrew Eyes. Acta Biomaterialia 2025; 201:446-456 (pdf) |
| J36 | A. Amiri-Hezaveh, S. Tan, Q. Deng, D. Umulis, L. Cunniff, J. Weickenmeier, A. Buganza Tepole. A Physics-Informed Deep Learning Deformable Medical Image Registration Method Based on Neural ODEs. International Journal of Computer Vision, 2025; 133:6374-6399 (pdf) |
| J35 | A. Torza, R. Zgeib, X. Wang, A. Zaeri, F. Zhang, K. Cao, R. Chang, J. Weickenmeier. Triaxial Mechanical Characterization Of Ultrasoft 3D Support Bath-Based Bioprinted Tubular Gelma Constructs. International Journal of Solids and Structures 2024; 301:112938 (pdf) |
| J34 | X. Zhang, E. van den Hurk, J. Weickenmeier. Insights into the Mechanical Characterization of Mouse Brain Tissue Using Microindentation Testing. Current Protocols 2024; 4:e1011 (pdf) |
| J33 | X. Zhang, J. Weickenmeier. Brain Stiffness Follows Cuprizone-Induced Variations in Local Myelin Content. Acta Biomaterialia 2023; 170:1-12 (pdf) |
| J32 | P. Giolando, S. Kakaletsis, X. Zhang, J. Weickenmeier, E. Castillo, B. Dortdivanlioglu, M. Rausch. AI-dente: an open machine learning based tool to interpret nano-indentation data of soft tissues and materials. Soft Matter 2023; 19:6710–6720 (pdf) |
| J31 | J. Weickenmeier. Exploring the multiphysics of the brain during development, aging, and in neurological diseases. Brain Multiphysics 2023; 4:100068 (pdf) |
| J30 | A. Caçoilo, B. Dortdivanlioglu, H. Rusinek, J. Weickenmeier. A multiphysics model to predict periventricular white matter hyperintensity growth during healthy brain aging. Brain Multiphysics 2023; 5:100072 (pdf) |
| J29 | V. Visser, A. Caçoilo, H. Rusinek, J. Weickenmeier. Mechanical loading of the ventricular wall as a spatial indicator for periventricular white matter degeneration. Journal of the Mechanical Behavior of Biomedical Materials 2023; 143:105921 (pdf) |
| J28 | A. Caçoilo, H. Rusinek, J. Weickenmeier. 3D finite-element brain modeling of lateral ventricular wall loading to rationalize periventricular white matter hyperintensity locations. Engineering With Computers 2022; 38:3939–3955 (pdf) |
| J27 | V. Visser, H. Rusinek, J. Weickenmeier. Peak ependymal cell stretch overlaps with the onset locations of periventricular white matter lesions. Scientific Reports 2021; 11:1–12 (pdf) |
| J26 | T. Lee, M. Holl, J. Weickenmeier, A. Gosain, A. Tepole. The geometry of incompatibility in growing soft tissues: Theory and numerical characterization. Journal of the Mechanics And Physics of Solids 2021; 146:104177 (pdf) |
| J25 | Y. Blinkouskaya, J. Weickenmeier. Brain shape changes associated with cerebral atrophy in healthy aging and Alzheimer’s disease. Frontiers in Mechanical Engineering 2021; 146:64 (pdf) |
| J24 | Z. Wang, B. Martin, J. Weickenmeier, K. Garikipati. An inverse modelling study on the local volume changes during early morphoelastic growth of the fetal human brain. Brain Multiphysics 2021; 2:100023 (pdf) |
| J23 | Y. Blinkouskaya, A. Caçoilo, T. Gollamudi, S. Jalalian, J. Weickenmeier. Brain aging mechanisms with mechanical manifestations. Mechanisms of Ageing And Development 2021; 200:111575 (pdf) |
| J22 | J. Weickenmeier. Running A Virtual Summer Undergraduate Research Program: Lessons learned. In: 2020 Fall Asee Mid-atlantic Section Meeting 2020; 200:1–11 (pdf) |
| J21 | J. Weickenmeier, E. Mazza. Inverse Methods. In: Skin Biophysics 2019; 200:193–213 (pdf) |
| J20 | A. Schäfer, J. Weickenmeier, E. Kuhl. The interplay of biochemical and biomechanical degeneration in Alzheimer’s disease. Computer Methods in Applied Mechanics And Engineering 2019; 352:369–388 (pdf) |
| J19 | J. Weickenmeier, M. Jucker, A. Goriely, E. Kuhl. A physics-based model explains the prion-like features of neurodegeneration in Alzheimer’s disease, Parkinson’s disease, and amyotrophic lateral sclerosis. Journal of the Mechanics And Physics of Solids 2019; 124:264–281 (pdf) |
| J18 | J. Weickenmeier, E. Kuhl, A. Goriely. Multiphysics of Prionlike Diseases: Progression and Atrophy. Physical Review Letters 2018; 121:158101 (pdf) |
| J17 | J. Weickenmeier, M. Kurt, E. Ozkaya, R. deRooij, T. Ovaert, R. Ehman, K. Butts-Pauly, E. Kuhl. Brain stiffens post mortem. Journal of the Mechanical Behavior of Biomedical Materials 2018; 84:88–98 (pdf) |
| J16 | M. Pensalfini, J. Weickenmeier, M. Rominger, R. Santoprete, O. Distler, E. Mazza. Location-specific mechanical response and morphology of facial soft tissues. Journal of the Mechanical Behavior of Biomedical Materials 2018; 78:108–115 (pdf) |
| J15 | J. Weickenmeier, C. Fischer, D. Carter, E. Kuhl, A. Goriely. Dimensional, Geometrical, and Physical Constraints in Skull Growth. Physical Review Letters 2017; 118:248101 (pdf) |
| J14 | J. Weickenmeier, R. deRooij, S. Budday, T. Ovaert, E. Kuhl. The mechanical importance of myelination in the central nervous system. Journal of the Mechanical Behavior of Biomedical Materials 2017; 76:119–124 (pdf) |
| J13 | J. Weickenmeier, M. Kurt, E. Ozkaya, M. Wintermark, K. Pauly, E. Kuhl. Magnetic resonance elastography of the brain: A comparison between pigs and humans. Journal of the Mechanical Behavior of Biomedical Materials 2018; 77:702–710 (pdf) |
| J12 | J. Weickenmeier, M. Jabareen, B. LeR{\’e}v{\’e}rend, M. Ramaioli, E. Mazza. Experimental and numerical characterization of the mechanical masseter muscle response during biting. Journal of Biomechanical Engineering 2017; 139:121007 (pdf) |
| J11 | J. Weickenmeier, C. Butler, P. Young, A. Goriely, E. Kuhl. The mechanics of decompressive craniectomy: Personalized simulations. Computer Methods in Applied Mechanics And Engineering 2017; 314:180–195 (pdf) |
| J10 | N. Brown, D. Bubeck, D. Haeufle, J. Weickenmeier, E. Kuhl, W. Alt, S. Schmitt. Weekly Time Course of Neuro-Muscular Adaptation to Intensive Strength Training. Frontiers in Physiology 2017; 8:329 (pdf) |
| J9 | J. Weickenmeier, E. Kuhl, A. Goriely. The mechanics of decompressive craniectomy: Bulging in idealized geometries. Journal of the Mechanics And Physics of Solids 2016; 96:572–590 (pdf) |
| J8 | J. Weickenmeier, P. Saez, C. Butler, P. Young, A. Goriely, E. Kuhl. Bulging brains. Journal of Elasticity 2017; 129:197–212 (pdf) |
| J7 | A. Goriely, J. Weickenmeier, E. Kuhl. Stress singularities in swelling soft solids. Physical Review Letters 2016; 117:138001 (pdf) |
| J6 | J. Weickenmeier, R. deRooij, S. Budday, P. Steinmann, T. Ovaert, E. Kuhl. Brain stiffness increases with myelin content. Acta Biomaterialia 2016; 42:265–272 (pdf) |
| J5 | E. Lejeune, A. Javili, J. Weickenmeier, E. Kuhl, C. Linder. Tri-layer wrinkling as a mechanism for anchoring center initiation in the developing cerebellum. Soft Matter 2016; 12:5613–5620 (pdf) |
| J4 | J. Weickenmeier, M. Jabareen, E. Mazza. Suction based mechanical characterization of superficial facial soft tissues. Journal of Biomechanics 2015; 48:4279–4286 (pdf) |
| J3 | J. Weickenmeier, R. Wu, P. Lecomte-Grosbras, J. Witz, M. Brieu, S. Winklhofer, G. Andreisek, E. Mazza. Experimental characterization and simulation of layer interaction in facial soft tissues. International Symposium On Biomedical Simulation 2014; 6:233–241 (pdf) |
| J2 | J. Weickenmeier, M. Jabareen. Elastic–viscoplastic modeling of soft biological tissues using a mixed finite element formulation based on the relative deformation gradient. International Journal for Numerical Methods in Biomedical Engineering 2014; 30:1238–1262 (pdf) |
| J1 | J. Weickenmeier, M. Itskov, E. Mazza, M. Jabareen. A physically motivated constitutive model for 3D numerical simulation of skeletal muscles. International Journal for Numerical Methods in Biomedical Engineering 2014; 30:545–562 (pdf) |