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Main Authors: Akahori, Shizuka, Teruya, Shotaro, Shrestha, Pragyan, Yoshii, Yuichi, Michinobu, Ryuhei, Iizuka, Satoshi, Kitahara, Itaru
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.13010
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author Akahori, Shizuka
Teruya, Shotaro
Shrestha, Pragyan
Yoshii, Yuichi
Michinobu, Ryuhei
Iizuka, Satoshi
Kitahara, Itaru
author_facet Akahori, Shizuka
Teruya, Shotaro
Shrestha, Pragyan
Yoshii, Yuichi
Michinobu, Ryuhei
Iizuka, Satoshi
Kitahara, Itaru
contents Ultrasound imaging of the medial elbow is crucial for the early diagnosis of Ulnar Collateral Ligament (UCL) injuries. Specifically, measuring the elbow joint space in ultrasound images is used to assess the valgus instability of the elbow caused by UCL injuries. To automate this measurement, a model trained on a precisely annotated dataset is necessary; however, no publicly available dataset exists to date. This study introduces a novel ultrasound medial elbow dataset to measure the joint space. The dataset comprises 4,201 medial elbow ultrasound images from 22 subjects, with landmark annotations on the humerus and ulna, based on the expertise of three orthopedic surgeons. We evaluated joint space measurement methods on our proposed dataset using heatmap-based, regression-based, and token-based landmark detection methods. While heatmap-based landmark detection methods generally achieve high accuracy, they sometimes produce multiple peaks on a heatmap, leading to incorrect detection. To mitigate this issue and enhance landmark localization, we propose Shape Subspace (SS) landmark refinement by measuring geometrical similarities between the detected and reference landmark positions. The results show that the mean joint space measurement error is 0.116 mm when using HRNet. Furthermore, SS landmark refinement can reduce the mean absolute error of landmark positions by 0.010 mm with HRNet and by 0.103 mm with ViTPose on average. These highlight the potential for high-precision, real-time diagnosis of UCL injuries by accurately measuring joint space. Lastly, we demonstrate point-based segmentation for the humerus and ulna using the detected landmarks as inputs. Our dataset will be publicly available at https://github.com/Akahori000/Ultrasound-Medial-Elbow-Dataset
format Preprint
id arxiv_https___arxiv_org_abs_2412_13010
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Measurement of Medial Elbow Joint Space using Landmark Detection
Akahori, Shizuka
Teruya, Shotaro
Shrestha, Pragyan
Yoshii, Yuichi
Michinobu, Ryuhei
Iizuka, Satoshi
Kitahara, Itaru
Computer Vision and Pattern Recognition
Ultrasound imaging of the medial elbow is crucial for the early diagnosis of Ulnar Collateral Ligament (UCL) injuries. Specifically, measuring the elbow joint space in ultrasound images is used to assess the valgus instability of the elbow caused by UCL injuries. To automate this measurement, a model trained on a precisely annotated dataset is necessary; however, no publicly available dataset exists to date. This study introduces a novel ultrasound medial elbow dataset to measure the joint space. The dataset comprises 4,201 medial elbow ultrasound images from 22 subjects, with landmark annotations on the humerus and ulna, based on the expertise of three orthopedic surgeons. We evaluated joint space measurement methods on our proposed dataset using heatmap-based, regression-based, and token-based landmark detection methods. While heatmap-based landmark detection methods generally achieve high accuracy, they sometimes produce multiple peaks on a heatmap, leading to incorrect detection. To mitigate this issue and enhance landmark localization, we propose Shape Subspace (SS) landmark refinement by measuring geometrical similarities between the detected and reference landmark positions. The results show that the mean joint space measurement error is 0.116 mm when using HRNet. Furthermore, SS landmark refinement can reduce the mean absolute error of landmark positions by 0.010 mm with HRNet and by 0.103 mm with ViTPose on average. These highlight the potential for high-precision, real-time diagnosis of UCL injuries by accurately measuring joint space. Lastly, we demonstrate point-based segmentation for the humerus and ulna using the detected landmarks as inputs. Our dataset will be publicly available at https://github.com/Akahori000/Ultrasound-Medial-Elbow-Dataset
title Measurement of Medial Elbow Joint Space using Landmark Detection
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2412.13010