利用支气管镜图像构建和验证人工智能模型以识别气管支气管软骨病。
Building and validating an artificial intelligence model to identify tracheobronchopathia osteochondroplastica by using bronchoscopic images.
机构信息
State Key Laboratory of Respiratory Disease, National Clinical Research Center for Respiratory Disease, Guangzhou Institute of Respiratory Health, The First Affiliated Hospital of Guangzhou Medical University, Guangzhou, Guangdong Province, China.
Department of Interventional Pulmonary and Endoscopic Diagnosis and Treatment Center, Anhui Chest Hospital, Hefei, Anhui Province, China.
出版信息
Ther Adv Respir Dis. 2024 Jan-Dec;18:17534666241253694. doi: 10.1177/17534666241253694.
BACKGROUND
Given the rarity of tracheobronchopathia osteochondroplastica (TO), many young doctors in primary hospitals are unable to identify TO based on bronchoscopy findings.
OBJECTIVES
To build an artificial intelligence (AI) model for differentiating TO from other multinodular airway diseases by using bronchoscopic images.
DESIGN
We designed the study by comparing the imaging data of patients undergoing bronchoscopy from January 2010 to October 2022 by using EfficientNet. Bronchoscopic images of 21 patients with TO at Anhui Chest Hospital from October 2019 to October 2022 were collected for external validation.
METHODS
Bronchoscopic images of patients with multinodular airway lesions (including TO, amyloidosis, tumors, and inflammation) and without airway lesions in the First Affiliated Hospital of Guangzhou Medical University were collected. The images were randomized (4:1) into training and validation groups based on different diseases and utilized for deep learning by convolutional neural networks (CNNs).
RESULTS
We enrolled 201 patients with multinodular airway disease (38, 15, 75, and 73 patients with TO, amyloidosis, tumors, and inflammation, respectively) and 213 without any airway lesions. To find multinodular lesion images for deep learning, we utilized 2183 bronchoscopic images of multinodular lesions (including TO, amyloidosis, tumor, and inflammation) and compared them with images without any airway lesions (1733). The accuracy of multinodular lesion identification was 98.9%. Further, the accuracy of TO detection based on the bronchoscopic images of multinodular lesions was 89.2%. Regarding external validation (using images from 21 patients with TO), all patients could be diagnosed with TO; the accuracy was 89.8%.
CONCLUSION
We built an AI model that could differentiate TO from other multinodular airway diseases (mainly amyloidosis, tumors, and inflammation) by using bronchoscopic images. The model could help young physicians identify this rare airway disease.
背景
由于气管支气管软骨病(TO)罕见,许多基层医院的年轻医生无法根据支气管镜检查结果识别 TO。
目的
通过支气管镜图像建立一种人工智能(AI)模型来区分 TO 与其他多结节气道疾病。
设计
我们通过使用 EfficientNet 比较 2010 年 1 月至 2022 年 10 月期间在安徽胸科医院行支气管镜检查的患者的影像数据来设计研究。2019 年 10 月至 2022 年 10 月期间收集了 21 例 TO 患者的支气管镜图像进行外部验证。
方法
收集了广州医科大学第一附属医院多结节气道病变(包括 TO、淀粉样变性、肿瘤和炎症)患者和无气道病变患者的支气管镜图像。根据不同疾病将图像随机(4:1)分为训练组和验证组,并通过卷积神经网络(CNNs)进行深度学习。
结果
我们纳入了 201 例多结节气道疾病患者(38、15、75 和 73 例分别为 TO、淀粉样变性、肿瘤和炎症患者)和 213 例无任何气道病变患者。为了找到多结节病变图像进行深度学习,我们利用了 2183 例多结节病变(包括 TO、淀粉样变性、肿瘤和炎症)的支气管镜图像,并将其与无任何气道病变的图像(1733 例)进行了比较。多结节病变识别的准确率为 98.9%。进一步的,基于多结节病变的支气管镜图像,TO 检测的准确率为 89.2%。对于外部验证(使用 21 例 TO 患者的图像),所有患者均能被诊断为 TO,准确率为 89.8%。
结论
我们建立了一种人工智能模型,可通过支气管镜图像将 TO 与其他多结节气道疾病(主要是淀粉样变性、肿瘤和炎症)区分开来。该模型有助于年轻医生识别这种罕见的气道疾病。
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