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Auteurs principaux: Wang, Yubo, Fridberg, Marie, Bafor, Anirejuoritse, Rahbek, Ole, Iobst, Christopher, Kold, Søren Vedding, Shen, Ming
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2603.24815
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author Wang, Yubo
Fridberg, Marie
Bafor, Anirejuoritse
Rahbek, Ole
Iobst, Christopher
Kold, Søren Vedding
Shen, Ming
author_facet Wang, Yubo
Fridberg, Marie
Bafor, Anirejuoritse
Rahbek, Ole
Iobst, Christopher
Kold, Søren Vedding
Shen, Ming
contents Pin sites represent the interface where a metal pin or wire from the external environment passes through the skin into the internal environment of the limb. These pins or wires connect an external fixator to the bone to stabilize the bone segments in a patient with trauma or deformity. Because these pin sites represent an opportunity for external skin flora to enter the internal environment of the limb, infections of the pin site are common. These pin site infections are painful, annoying, and cause increased morbidity to the patients. Improving the identification and management of pin site infections would greatly enhance the patient experience when external fixators are used. For this, this paper collects and produces a dataset on pin sites wound infections and proposes a deep learning (DL) method to classify pin sites images based on their appearance: Group A displayed signs of inflammation or infection, while Group B showed no evident complications. Unlike studies that primarily focus on open wounds, our research includes potential interventions at the metal pin/skin interface. Our attention-based deep learning model addresses this complexity by emphasizing relevant regions and minimizing distractions from the pins. Moreover, we introduce an Efficient Redundant Reconstruction Convolution (ERRC) method to enhance the richness of feature maps while reducing the number of parameters. Our model outperforms baseline methods with an AUC of 0.975 and an F1-score of 0.927, requiring only 5.77 M parameters. These results highlight the potential of DL in differentiating pin sites only based on visual signs of infection, aligning with healthcare professional assessments, while further validation with more data remains essential.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24815
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Attention-based Pin Site Image Classification in Orthopaedic Patients with External Fixators
Wang, Yubo
Fridberg, Marie
Bafor, Anirejuoritse
Rahbek, Ole
Iobst, Christopher
Kold, Søren Vedding
Shen, Ming
Computer Vision and Pattern Recognition
Pin sites represent the interface where a metal pin or wire from the external environment passes through the skin into the internal environment of the limb. These pins or wires connect an external fixator to the bone to stabilize the bone segments in a patient with trauma or deformity. Because these pin sites represent an opportunity for external skin flora to enter the internal environment of the limb, infections of the pin site are common. These pin site infections are painful, annoying, and cause increased morbidity to the patients. Improving the identification and management of pin site infections would greatly enhance the patient experience when external fixators are used. For this, this paper collects and produces a dataset on pin sites wound infections and proposes a deep learning (DL) method to classify pin sites images based on their appearance: Group A displayed signs of inflammation or infection, while Group B showed no evident complications. Unlike studies that primarily focus on open wounds, our research includes potential interventions at the metal pin/skin interface. Our attention-based deep learning model addresses this complexity by emphasizing relevant regions and minimizing distractions from the pins. Moreover, we introduce an Efficient Redundant Reconstruction Convolution (ERRC) method to enhance the richness of feature maps while reducing the number of parameters. Our model outperforms baseline methods with an AUC of 0.975 and an F1-score of 0.927, requiring only 5.77 M parameters. These results highlight the potential of DL in differentiating pin sites only based on visual signs of infection, aligning with healthcare professional assessments, while further validation with more data remains essential.
title Attention-based Pin Site Image Classification in Orthopaedic Patients with External Fixators
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.24815