Technology documented in International Literature

1. A. Sternheim;F. Traub;N. Trabelsi;S. Dadia;Y. Gortzak;N. Snir;M. Gorfine;Z. Yosibash, When and where do patients with bone metastases actually break their femurs?: A CT-BASED FINITE ELEMENT ANALYSIS The Bone & Joint Journal. 102B(5):638–645, MAY 2020 DOI: 10.1302/0301-620X.102B5.BJJ-2019-1328.R2

2. Sternheim A., Giladi O., Gortzak Y., Drexler M., Salai M., Trabelsi N., Milgrom C. and Yosibash Z., ``Pathological fracture risk assessment in patients with femoral metastases using CT-based finite element methods. A retrospective clinical study'',Bone, 110, (2018) pp. 215--220

3. Yosibash Z, Trabelsi N. and Milgrom, C., "Reliable simulations of the human proximal femur by high-order finite element analysis validated by experimental observations", Journal of Biomechanics, 40, pp. 3688-3699, (2007)

4. Yosibash Z., Trabelsi N. and Hellmich C., "Subject-specific p-FE analysis of the proximal femur utilizing micromechanics based material properties'', International Journal for Multiscale Computational Engineering, 6, Issue 5, pp. 483-498 (2008)

5. Trabelsi N., Yosibash Z, and Milgrom, C., "Validation of subject specific automated p-FE analysis of the proximal femur", Journal of Biomechanics, 42, pp. 234-241 (2009)

6. Yosibash Z, Tal David and Trabelsi N., "Predicting the yield of the proximal femur using high-order finite element analysis with inhomogeneous orthotropic material properties", Philosophical Transaction of the Royal Society, A, 368, pp. 2707-2723 (2010)

7. Trabelsi N., Yosibash Z, Wutte C., Augat P. and Eberle S., "Patient-specific finite element analysis of the human femur - A double-blinded biomechanical validation“, Journal of Biomechanics, 44, pp. 1666-1672 (2011)

8. Trabelsi N. and Yosibash Z., "Patient-specific FE analyses of the proximal femur with orthotropic material properties validated by experiments", ASME Journal of Biomechanical Engineering, 133 (6), pp. 061101-1-11, (2011).

9. Yosibash Z. and Trabelsi N., "Reliable patient-specific simulations of the femur", in Patient-Specific Modeling in Tomorrow's Medicine, A. Gefen Editor, Springer, ISBN 978-3-642-24617-3, pp. 3-26 (2012).

10. Ruess M., Tal D., Trabelsi N., Yosibash Z. and Rank, E., "The finite cell method for bone simulations: Verification and validation", Biomechanics and Modeling inMechanobiology, 11(3), pp. 425-437, (2012)

11. Wille H., Rank E. and Yosibash Z., "Prediction of the mechanical response of the femur with uncertain elastic properties", Journal of Biomechanics, 45(7), pp. 1140-1148, (2012).

12. Yosibash Z., "p-FEMs in biomechanics: Bones and Arteries", Computer Methods in Applied Mechanics and Engineering, 249-252, pp. 169-184, (2012).

13. Yosibash Z., Katz A. and Milgrom C., "Towards Verified and Validated FE Simulations of a Femur with a Cemented Hip Prosthesis", Medical Engineering and Physics, 35, pp. 978-987, (2013).

14. Trabelsi N., Milgrom, C. and Yosibash Z., "Patient-Specific FE Analyses of Metatarsal Bones with Inhomogeneous Isotropic Material Properties'', Journal of the Mechanical Behavior of Biomedical Materials, 29, pp. 177-189, (2014).

15. Yosibash Z., Plitman Mayo R., Dahan G., Trabelsi N, Amir G.and Milgrom, C., "Predicting the stiffness and strength of human femurs with realistic metastatic tumors'', Bone, 69, pp. 180-190, (2014).

16. Yosibash Z., Wille H., and Rank E., "Stochastic description of the peak hip contact force during walking free and going upstairs", Journal of Biomechanics, 48, pp. 1015-1022, (2015).

17. Yosibash Z., Myers, K., Trabelsi, N., and Sternheim, A, "Autonomous FEs (AFE) - A stride toward personalized medicine”, Computers and Mathematics with Applications 80 pp.2417–2432. (2020).

18. Yosibash Z., Trabelsi, N., Itay Buchnik, Myers, K., Moshe Salai, Iris Eshed, Yiftach Barash, Eyal Klang and Liana Tripto-Shkolnik, “Hip Fracture Risk Assessment in Elderly and Diabetic Patients: Combining Automous Finite Element Analysis and Machine Learning”, JBMR, (2023).