Difference between revisions of "Archived Reports"
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| + | ===2020:=== | ||
| + | Report # ISML/01/2020 [[Media:ISML_Research_Report_no._01-2020.pdf|Does Aneurysm Biomechanical Ratio Predict Rupture or Repair in Patients with Abdominal Aortic Aneurysm?]] K. Miller, G.R. Joldes, A. Wittek | ||
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| + | ===2019:=== | ||
| + | Report # ISML/01/2019 [https://{{SERVERNAME}}/ISML/Reports/An%20explicit%20meshless%20point%20collocation%20solver%20for%20incompressible%20Navier-Stokes%20equations.pdf An explicit meshless point collocation solver for incompressible Navier-Stokes equations] G. C. Bourantas | ||
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| + | ===2018:=== | ||
| + | Report # ISML/01/2018 [[Media:ISML 01-2018.pdf|Investigating the relationship between AAA Wall Stress and symptoms exhibited by patients]] Tavner et al. | ||
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| + | ===2017:=== | ||
| + | Report # ISML/03/2017 [[Media:WallThickness_ISML_report.pdf|Maximum Principal AAA Wall Stress is Proportional to Wall Thickness]] Miller et al. | ||
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| + | Report # ISML/02/2017 [[Media:Residual_stress_ISML_report.pdf|A simple and effective method of incorporating the effects of residual stress in the abdominal aortic aneurysm wall stress estimation]] Joldes et al. | ||
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| + | Report # ISML/01/2017 [[Media:BioPARR_ISML_report.pdf|BioPARR: A software system for estimating the rupture potential index for abdominal aortic aneurysms]] Joldes et al. | ||
| + | <span style="color: red; font-weight:bold">BioPARR software can be downloaded</span> [https://bioparr.mech.uwa.edu.au '''here'''] | ||
===2014:=== | ===2014:=== | ||
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Report # ISML/02/2007, July 2007. [[Media:isml-no-02-2007.pdf|Mathematical Methods for Computational Soft Tissue Medical Imaging]] | Report # ISML/02/2007, July 2007. [[Media:isml-no-02-2007.pdf|Mathematical Methods for Computational Soft Tissue Medical Imaging]] | ||
| − | Report # ISML/01/2007, June 2007. [[Media:isml-no-01-2007.pdf| | + | Report # ISML/01/2007, June 2007. [[Media:isml-no-01-2007.pdf|Mesh Free Methods of Soft Tissue Deformation in Computer Integrated Surgery II]] |
===2006:=== | ===2006:=== | ||
| − | Report # ISML/01/2006, February 2006. | + | Report # ISML/01/2006, February 2006. [[Media:isml-no-01-2006.pdf|Mathematical Models of Brain Deformation Behaviour for Computer-Integrated Neurosurgery]] |
| − | + | ||
| − | Report # ISML/02/2006, May 2006. | + | Report # ISML/02/2006, May 2006. [[Media:isml-no-02-2006.pdf|Mesh Free Methods for Soft Tissue Deformation in Computer Integrated Surgery]] |
| − | Report # ISML/03/2006, June 2006. | + | Report # ISML/03/2006, June 2006. [[Media:isml-no-03-2006.pdf|Initial Investigative Report on Normal Pressure Hydrocephalus]] |
Latest revision as of 10:07, 29 May 2020
2020:
Report # ISML/01/2020 Does Aneurysm Biomechanical Ratio Predict Rupture or Repair in Patients with Abdominal Aortic Aneurysm? K. Miller, G.R. Joldes, A. Wittek
2019:
Report # ISML/01/2019 An explicit meshless point collocation solver for incompressible Navier-Stokes equations G. C. Bourantas
2018:
Report # ISML/01/2018 Investigating the relationship between AAA Wall Stress and symptoms exhibited by patients Tavner et al.
2017:
Report # ISML/03/2017 Maximum Principal AAA Wall Stress is Proportional to Wall Thickness Miller et al.
Report # ISML/02/2017 A simple and effective method of incorporating the effects of residual stress in the abdominal aortic aneurysm wall stress estimation Joldes et al.
Report # ISML/01/2017 BioPARR: A software system for estimating the rupture potential index for abdominal aortic aneurysms Joldes et al. BioPARR software can be downloaded here
2014:
Report # ISML/02/2014 Modified Moving Least Squares with Polynomial Bases for Scattered Data Approximation Joldes et al.
Report # ISML/01/2014 Portable Experimental Device for Determining the Mechanical Properties of Brain-Skull Interface Agrawal et al.
2013:
Report # ISML/03/2013 Final Year Thesis. Towards Non-Rigid Registration Of Whole-Body Radiographic Images, Using Patient-Specific Biomechanical Models Ovidio et al.
Report # ISML/02/2013 Evaluation of accuracy of patient-specific non-linear biomechanical models used to predict intraoperative brain shift Roy et al.
Report # ISML/01/2013 Non-linear finite element biomechanical model as a registration tool for image-guided neurosurgery: evaluation of accuracy against BSpline registration Mostayed et al.
2011:
Report # ISML/03/2011 Meshless Algorithm For Simulation of Soft Tissue Cutting For Computer-Integrated Surgery Jin et al.
Report # ISML/02/2011 Beyond Finite Element Analysis in Injury Simulation: Meshless Algorithm for Modelling of Soft Tissue Responses Undergoing Very Large Strains and Damage Jin et al.
Report # ISML/01/2011 Stable time steps for mesh-free particle methods Joldes et al. (2011) IJNME preprint
2009:
Report # ISML/03/2009, June 2009. Real-Time Nonlinear Finite Element Computations on GPU for Surgical Simulation Authors: Grand Joldes, Adam Wittek, Karol Miller
Report # ISML/02/2009, February 2009. Accuracy of Non-Linear Finite Modelling for Neurosurgical Simulation; Study Using Brain Phantom Authors: Jiajie Ma, Adam Wittek, Karol Miller
Report # ISML/01/2009, February 2009. Evaluation of the Accuracy of Nonlinear Finite Element Modelling for Predicting Intraoperative Brain Deformations: Study of Six Craniotomy Cases Authors: Adam Wittek, Grand Joldes, Karol Miller
2007:
Report # ISML/02/2007, July 2007. Mathematical Methods for Computational Soft Tissue Medical Imaging
Report # ISML/01/2007, June 2007. Mesh Free Methods of Soft Tissue Deformation in Computer Integrated Surgery II
2006:
Report # ISML/01/2006, February 2006. Mathematical Models of Brain Deformation Behaviour for Computer-Integrated Neurosurgery
Report # ISML/02/2006, May 2006. Mesh Free Methods for Soft Tissue Deformation in Computer Integrated Surgery
Report # ISML/03/2006, June 2006. Initial Investigative Report on Normal Pressure Hydrocephalus
