过去一年中添加的文章,按日期排序
LNAS: A clinically applicable deep-learning system for mediastinal enlarged lymph nodes segmentation and station mapping without regard to the pathogenesis using …
Y Cao, J Feng, C Wang, F Yang, X Wang, J Xu… - La radiologia …, 2024 - Springer
La radiologia medica, 2024•Springer
226 天前 - Background The accurate identification and evaluation of lymph nodes by CT
images is of great significance for disease diagnosis, treatment, and prognosis. Purpose To
assess the lymph nodes' segmentation, size, and station by artificial intelligence (AI) for
unenhanced chest CT images and evaluate its value in clinical scenarios. Material and
methods This retrospective study proposed an end-to-end Lymph Nodes Analysis System
(LNAS) consisting of three models: the Lymph Node Segmentation model (LNS), the …
images is of great significance for disease diagnosis, treatment, and prognosis. Purpose To
assess the lymph nodes' segmentation, size, and station by artificial intelligence (AI) for
unenhanced chest CT images and evaluate its value in clinical scenarios. Material and
methods This retrospective study proposed an end-to-end Lymph Nodes Analysis System
(LNAS) consisting of three models: the Lymph Node Segmentation model (LNS), the …
Background
The accurate identification and evaluation of lymph nodes by CT images is of great significance for disease diagnosis, treatment, and prognosis.
Purpose
To assess the lymph nodes’ segmentation, size, and station by artificial intelligence (AI) for unenhanced chest CT images and evaluate its value in clinical scenarios.
Material and methods
This retrospective study proposed an end-to-end Lymph Nodes Analysis System (LNAS) consisting of three models: the Lymph Node Segmentation model (LNS), the Mediastinal Organ Segmentation model (MOS), and the Lymph Node Station Registration model (LNR). We selected a healthy chest CT image as the template image and annotated 14 lymph node station masks according to the IASLC to build the lymph node station mapping template. The exact contours and stations of the lymph nodes were annotated by two junior radiologists and reviewed by a senior radiologist. Patients aged 18 and above, who had undergone unenhanced chest CT and had at least one suspicious enlarged mediastinal lymph node in imaging reports, were included. Exclusions were patients who had thoracic surgeries in the past 2 weeks or artifacts on CT images affecting lymph node observation by radiologists. The system was trained on 6725 consecutive chest CTs that from Tianjin Medical University General Hospital, among which 6249 patients had suspicious enlarged mediastinal lymph nodes. A total of 519 consecutive chest CTs from Qilu Hospital of Shandong University (Qingdao) were used for external validation. The gold standard for each CT was determined by two radiologists and reviewed by one senior radiologist.
Results
The patient-level sensitivity of the LNAS system reached of 93.94% and 92.89% in internal and external test dataset, respectively. And the lesion-level sensitivity (recall) reached 89.48% and 85.97% in internal and external test dataset. For man–machine comparison, AI significantly apparently shortened the average reading time (p < 0.001) and had better lesion-level and patient-level sensitivities.
Conclusion
AI improved the sensitivity lymph node segmentation by radiologists with an advantage in reading time.
Springer