Fracture Detection in Wrist X-ray Images Using Deep Learning-Based
Object Detection Models
- URL: http://arxiv.org/abs/2111.07355v1
- Date: Sun, 14 Nov 2021 14:21:24 GMT
- Title: Fracture Detection in Wrist X-ray Images Using Deep Learning-Based
Object Detection Models
- Authors: F{\i}rat Hardala\c{c}, Fatih Uysal, Ozan Peker, Murat
\c{C}i\c{c}eklida\u{g}, Tolga Tolunay, Nil Tokg\"oz, U\u{g}urhan Kutbay,
Boran Demirciler and Fatih Mert
- Abstract summary: This study aims to perform fracture detection using deep learning on wrist Xray images.
Based on detection of 26 different fractures in total, the highest result of detection was 0.8639 average precision (AP50) in WFD_C model developed.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Wrist fractures are common cases in hospitals, particularly in emergency
services. Physicians need images from various medical devices, and patients
medical history and physical examination to diagnose these fractures correctly
and apply proper treatment. This study aims to perform fracture detection using
deep learning on wrist Xray images to assist physicians not specialized in the
field, working in emergency services in particular, in diagnosis of fractures.
For this purpose, 20 different detection procedures were performed using deep
learning based object detection models on dataset of wrist Xray images obtained
from Gazi University Hospital. DCN, Dynamic R_CNN, Faster R_CNN, FSAF, Libra
R_CNN, PAA, RetinaNet, RegNet and SABL deep learning based object detection
models with various backbones were used herein. To further improve detection
procedures in the study, 5 different ensemble models were developed, which were
later used to reform an ensemble model to develop a detection model unique to
our study, titled wrist fracture detection combo (WFD_C). Based on detection of
26 different fractures in total, the highest result of detection was 0.8639
average precision (AP50) in WFD_C model developed. This study is supported by
Huawei Turkey R&D Center within the scope of the ongoing cooperation project
coded 071813 among Gazi University, Huawei and Medskor.
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