Angular upsampling in diffusion MRI using contextual HemiHex
sub-sampling in q-space
- URL: http://arxiv.org/abs/2211.00240v1
- Date: Tue, 1 Nov 2022 03:13:07 GMT
- Title: Angular upsampling in diffusion MRI using contextual HemiHex
sub-sampling in q-space
- Authors: Abrar Faiyaz, Md Nasir Uddin, Giovanni Schifitto
- Abstract summary: It is important to incorporate relevant context for the data to ensure that maximum prior information is provided for the AI model to infer the posterior.
In this paper, we introduce HemiHex subsampling to suggestively address training data sampling on q-space geometry.
Our proposed approach is a geometrically optimized regression technique which infers the unknown q-space thus addressing the limitations in the earlier studies.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-sa/4.0/
- Abstract: Artificial Intelligence (Deep Learning(DL)/ Machine Learning(ML)) techniques
are widely being used to address and overcome all kinds of ill-posed problems
in medical imaging which was or in fact is seemingly impossible. Reducing
gradient directions but harnessing high angular resolution(HAR) diffusion data
in MR that retains clinical features is an important and challenging problem in
the field. While the DL/ML approaches are promising, it is important to
incorporate relevant context for the data to ensure that maximum prior
information is provided for the AI model to infer the posterior. In this paper,
we introduce HemiHex (HH) subsampling to suggestively address training data
sampling on q-space geometry, followed by a nearest neighbor regression
training on the HH-samples to finally upsample the dMRI data. Earlier studies
has tried to use regression for up-sampling dMRI data but yields performance
issues as it fails to provide structured geometrical measures for inference.
Our proposed approach is a geometrically optimized regression technique which
infers the unknown q-space thus addressing the limitations in the earlier
studies.
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