- The code is for reconstructing diffusion model parameters from various diffusion gradient schemes and b-values using deep learning (DIFFnet).
- last update : 2020. 02. 04
- The source data for training can be shared to academic institutions. Request should be sent to snu.list.software@gmail.com. For each request, individual approval from our institutional review board is required (i.e. takes time)
- DIFFnet: Diffusion parameter mapping network generalized for input diffusion gradient schemes and bvalues. J. Park, W. Jung, E-J. Choi, S-H. Oh, D. Shin, H. An, and J. Lee.
https://arxiv.org/abs/2102.02463
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Python 3.7
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TensorFlow-gpu 1.15
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NVIDIA GPU (CUDA 10.0)
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MATLAB 2019a
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3T MRI system (Tim Trio, SIEMENS, Erlangen, Germany) using a 32-channel phased-array head coil.
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DatasetDTI-A and DatasetNODDI-A were form below reference.
- W. Jung et al., "Whole brain g-ratio mapping using myelin water imaging (MWI) and neurite orientation dispersion and density imaging (NODDI)," NeuroImage, vol. 182, pp. 379-388, Nov. 2018. https://www.sciencedirect.com/science/article/pii/S1053811917308017
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DatasetDTI-A (b = 700 s/mm^2 with 32 directinos)
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DatasetDTI-B (b = 1000 s/mm^2 with 30 directions)
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DatasetNODDI-A (b = 300 s/mm^2 with 8 directions; b = 700 s/mm^2 with 32 directions; b = 2000 s/mm^2 with 64 directions)
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DatasetNODDI-B (b = 300 s/mm^2 with 8 directions; b = 700 s/mm^2 with 30 directions; b = 2000 s/mm^2 with 60 directions)
- Monte-Carlo diffusion simulation code to generate diffusion-weighted signals for training.
- The source code for training DIFFnet. Simulated data from Monte-Carlo diffusion simulation has to be required.
- The source code for evaluation of the trained networks.
- In-vivo data and simulated data can be evaluated both.
- Networks generate diffusion model parameters.