Difference between revisions of "2010 Winter Project Week Tractography"
From NAMIC Wiki
(status update) |
|||
(6 intermediate revisions by 2 users not shown) | |||
Line 2: | Line 2: | ||
<gallery> | <gallery> | ||
Image:PW-SLC2010.png|[[2010_Winter_Project_Week#Projects|Projects List]] | Image:PW-SLC2010.png|[[2010_Winter_Project_Week#Projects|Projects List]] | ||
+ | Image:Filtered_tractography.png|Left hemisphere | ||
</gallery> | </gallery> | ||
==Key Investigators== | ==Key Investigators== | ||
− | * BWH: Peter Savadjiev | + | * BWH: James Malcolm, Peter Savadjiev, Yogesh Rathi, C-F Westin |
<div style="margin: 20px;"> | <div style="margin: 20px;"> | ||
Line 13: | Line 14: | ||
<div style="width: 27%; float: left; padding-right: 3%"> | <div style="width: 27%; float: left; padding-right: 3%"> | ||
− | <h3> | + | <h3>Plan</h3> |
− | Implement various local models and filtering techniques. Support both region-of-interest and fiducial seeding. Support both interactive and batch processing.</div> | + | Implement various local models and filtering techniques. Support both region-of-interest and fiducial seeding. Support both interactive and batch processing. Picking fibers and moving them between polydata structures.</div> |
<div style="width: 27%; float: left; padding-right: 3%"> | <div style="width: 27%; float: left; padding-right: 3%"> | ||
<h3>Progress</h3> | <h3>Progress</h3> | ||
− | We have | + | We have Python/NumPy implementations of various local models (single-tensor, two-tensor, Watson functions, weighted mixtures of these, etc.) and various model-based filters (Kalman, unscented Kalman, particle, etc.) and deterministic tractography infrastructure. |
+ | |||
+ | However, it is unusably slow (the MATLAB version runs faster). Profiling the code seems to indicate that there is too much NumPy overhead in manipulating lots of small matrices/vectors. Now reimplementing in C/C++. | ||
</div> | </div> | ||
<p> | <p> | ||
<div style="width: 97%; float: left; padding-right: 3%"> | <div style="width: 97%; float: left; padding-right: 3%"> | ||
− | |||
# Malcolm, Michailovich, Bouix, Westin, Shenton, Rathi. "A filtered approach to neural tractography using the Watson directional function", MedIA 14(1), p.58-69, 2010. | # Malcolm, Michailovich, Bouix, Westin, Shenton, Rathi. "A filtered approach to neural tractography using the Watson directional function", MedIA 14(1), p.58-69, 2010. | ||
− | # Malcolm, Shenton, Rathi. "Neural | + | # Malcolm, Shenton, Rathi. "Neural tractography using an unscented Kalman filter", IPMI, p.126-138, 2009. |
+ | # Savadjiev, Zucker, Siddiqi. "On the Differential Geometry of 3D Flow Patterns: Generalized Helicoids and Diffusion MRI Analysis", ICCV 2007 | ||
</div> | </div> |
Latest revision as of 15:46, 8 January 2010
Home < 2010 Winter Project Week TractographyKey Investigators
- BWH: James Malcolm, Peter Savadjiev, Yogesh Rathi, C-F Westin
Objective
Integrate recent methods for filtered tractography into Slicer3 using Python.Plan
Implement various local models and filtering techniques. Support both region-of-interest and fiducial seeding. Support both interactive and batch processing. Picking fibers and moving them between polydata structures.Progress
We have Python/NumPy implementations of various local models (single-tensor, two-tensor, Watson functions, weighted mixtures of these, etc.) and various model-based filters (Kalman, unscented Kalman, particle, etc.) and deterministic tractography infrastructure.
However, it is unusably slow (the MATLAB version runs faster). Profiling the code seems to indicate that there is too much NumPy overhead in manipulating lots of small matrices/vectors. Now reimplementing in C/C++.
- Malcolm, Michailovich, Bouix, Westin, Shenton, Rathi. "A filtered approach to neural tractography using the Watson directional function", MedIA 14(1), p.58-69, 2010.
- Malcolm, Shenton, Rathi. "Neural tractography using an unscented Kalman filter", IPMI, p.126-138, 2009.
- Savadjiev, Zucker, Siddiqi. "On the Differential Geometry of 3D Flow Patterns: Generalized Helicoids and Diffusion MRI Analysis", ICCV 2007