Spatio-Temporal Deep Learning Methods for Motion Estimation Using 4D OCT
Image Data
- URL: http://arxiv.org/abs/2004.10114v1
- Date: Tue, 21 Apr 2020 15:43:01 GMT
- Title: Spatio-Temporal Deep Learning Methods for Motion Estimation Using 4D OCT
Image Data
- Authors: Marcel Bengs and Nils Gessert and Matthias Schl\"uter and Alexander
Schlaefer
- Abstract summary: Localizing structures and estimating the motion of a specific target region are common problems for navigation during surgical interventions.
We investigate whether using a temporal stream of OCT image volumes can improve deep learning-based motion estimation performance.
Using 4D information for the model input improves performance while maintaining reasonable inference times.
- Score: 63.73263986460191
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Purpose. Localizing structures and estimating the motion of a specific target
region are common problems for navigation during surgical interventions.
Optical coherence tomography (OCT) is an imaging modality with a high spatial
and temporal resolution that has been used for intraoperative imaging and also
for motion estimation, for example, in the context of ophthalmic surgery or
cochleostomy. Recently, motion estimation between a template and a moving OCT
image has been studied with deep learning methods to overcome the shortcomings
of conventional, feature-based methods.
Methods. We investigate whether using a temporal stream of OCT image volumes
can improve deep learning-based motion estimation performance. For this
purpose, we design and evaluate several 3D and 4D deep learning methods and we
propose a new deep learning approach. Also, we propose a temporal
regularization strategy at the model output.
Results. Using a tissue dataset without additional markers, our deep learning
methods using 4D data outperform previous approaches. The best performing 4D
architecture achieves an correlation coefficient (aCC) of 98.58% compared to
85.0% of a previous 3D deep learning method. Also, our temporal regularization
strategy at the output further improves 4D model performance to an aCC of
99.06%. In particular, our 4D method works well for larger motion and is robust
towards image rotations and motion distortions.
Conclusions. We propose 4D spatio-temporal deep learning for OCT-based motion
estimation. On a tissue dataset, we find that using 4D information for the
model input improves performance while maintaining reasonable inference times.
Our regularization strategy demonstrates that additional temporal information
is also beneficial at the model output.
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