DDoS-UNet: Incorporating temporal information using Dynamic Dual-channel
UNet for enhancing super-resolution of dynamic MRI
- URL: http://arxiv.org/abs/2202.05355v1
- Date: Thu, 10 Feb 2022 22:20:58 GMT
- Title: DDoS-UNet: Incorporating temporal information using Dynamic Dual-channel
UNet for enhancing super-resolution of dynamic MRI
- Authors: Soumick Chatterjee, Chompunuch Sarasaen, Georg Rose, Andreas
N\"urnberger and Oliver Speck
- Abstract summary: Magnetic resonance imaging (MRI) provides high spatial resolution and excellent soft-tissue contrast without using harmful ionising radiation.
MRI with high temporal resolution suffers from limited spatial resolution.
Deep learning based super-resolution approaches have been proposed to mitigate this trade-off.
This research addresses the problem by creating a deep learning model which attempts to learn both spatial and temporal relationships.
- Score: 0.27998963147546135
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Magnetic resonance imaging (MRI) provides high spatial resolution and
excellent soft-tissue contrast without using harmful ionising radiation.
Dynamic MRI is an essential tool for interventions to visualise movements or
changes of the target organ. However, such MRI acquisition with high temporal
resolution suffers from limited spatial resolution - also known as the
spatio-temporal trade-off of dynamic MRI. Several approaches, including deep
learning based super-resolution approaches, have been proposed to mitigate this
trade-off. Nevertheless, such an approach typically aims to super-resolve each
time-point separately, treating them as individual volumes. This research
addresses the problem by creating a deep learning model which attempts to learn
both spatial and temporal relationships. A modified 3D UNet model, DDoS-UNet,
is proposed - which takes the low-resolution volume of the current time-point
along with a prior image volume. Initially, the network is supplied with a
static high-resolution planning scan as the prior image along with the
low-resolution input to super-resolve the first time-point. Then it continues
step-wise by using the super-resolved time-points as the prior image while
super-resolving the subsequent time-points. The model performance was tested
with 3D dynamic data that was undersampled to different in-plane levels. The
proposed network achieved an average SSIM value of 0.951$\pm$0.017 while
reconstructing the lowest resolution data (i.e. only 4\% of the k-space
acquired) - which could result in a theoretical acceleration factor of 25. The
proposed approach can be used to reduce the required scan-time while achieving
high spatial resolution.
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