A Proof-of-Concept Study of Artificial Intelligence Assisted Contour
Revision
- URL: http://arxiv.org/abs/2107.13465v1
- Date: Wed, 28 Jul 2021 16:18:29 GMT
- Title: A Proof-of-Concept Study of Artificial Intelligence Assisted Contour
Revision
- Authors: Ti Bai, Anjali Balagopal, Michael Dohopolski, Howard E. Morgan, Rafe
McBeth, Jun Tan, Mu-Han Lin, David J. Sher, Dan Nguyen, and Steve Jiang
- Abstract summary: We present a novel concept called artificial intelligence assisted contour revision (AIACR)
The concept uses deep learning (DL) models to assist clinicians in revising contours in an efficient and effective way.
We demonstrated its feasibility by using 2D axial CT images from three head-and-neck cancer datasets.
- Score: 4.195764918318819
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Automatic segmentation of anatomical structures is critical for many medical
applications. However, the results are not always clinically acceptable and
require tedious manual revision. Here, we present a novel concept called
artificial intelligence assisted contour revision (AIACR) and demonstrate its
feasibility. The proposed clinical workflow of AIACR is as follows given an
initial contour that requires a clinicians revision, the clinician indicates
where a large revision is needed, and a trained deep learning (DL) model takes
this input to update the contour. This process repeats until a clinically
acceptable contour is achieved. The DL model is designed to minimize the
clinicians input at each iteration and to minimize the number of iterations
needed to reach acceptance. In this proof-of-concept study, we demonstrated the
concept on 2D axial images of three head-and-neck cancer datasets, with the
clinicians input at each iteration being one mouse click on the desired
location of the contour segment. The performance of the model is quantified
with Dice Similarity Coefficient (DSC) and 95th percentile of Hausdorff
Distance (HD95). The average DSC/HD95 (mm) of the auto-generated initial
contours were 0.82/4.3, 0.73/5.6 and 0.67/11.4 for three datasets, which were
improved to 0.91/2.1, 0.86/2.4 and 0.86/4.7 with three mouse clicks,
respectively. Each DL-based contour update requires around 20 ms. We proposed a
novel AIACR concept that uses DL models to assist clinicians in revising
contours in an efficient and effective way, and we demonstrated its feasibility
by using 2D axial CT images from three head-and-neck cancer datasets.
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