Artificial Intelligence to Diagnose Tibial Plateau Fractures: An Intelligent Assistant for Orthopedic Physicians

Peng-ran Liu; Jia-yao Zhang; Ming-di Xue; Yu-yu Duan; Jia-lang Hu; Song-xiang Liu; Yi Xie; Hong-lin Wang; Jun-wen Wang; Tong-tong Huo; Zhe-wei Ye

doi:10.1007/s11596-021-2501-4

Current Medical Science ›› 2021, Vol. 41 ›› Issue (6) : 1158 -1164. DOI: 10.1007/s11596-021-2501-4

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Artificial Intelligence to Diagnose Tibial Plateau Fractures: An Intelligent Assistant for Orthopedic Physicians

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Abstract

Objective

To explore a new artificial intelligence (AI)-aided method to assist the clinical diagnosis of tibial plateau fractures (TPFs) and further measure its validity and feasibility.

Methods

A total of 542 X-rays of TPFs were collected as a reference database. An AI algorithm (RetinaNet) was trained to analyze and detect TPF on the X-rays. The ability of the AI algorithm was determined by indexes such as detection accuracy and time taken for analysis. The algorithm performance was also compared with orthopedic physicians.

Results

The AI algorithm showed a detection accuracy of 0.91 for the identification of TPF, which was similar to the performance of orthopedic physicians (0.92±0.03). The average time spent for analysis of the AI was 0.56 s, which was 16 times faster than human performance (8.44±3.26 s).

Conclusion

The AI algorithm is a valid and efficient method for the clinical diagnosis of TPF. It can be a useful assistant for orthopedic physicians, which largely promotes clinical workflow and further guarantees the health and security of patients.

Cite this article

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Peng-ran Liu, Jia-yao Zhang, Ming-di Xue, Yu-yu Duan, Jia-lang Hu, Song-xiang Liu, Yi Xie, Hong-lin Wang, Jun-wen Wang, Tong-tong Huo, Zhe-wei Ye. Artificial Intelligence to Diagnose Tibial Plateau Fractures: An Intelligent Assistant for Orthopedic Physicians. Current Medical Science, 2021, 41(6): 1158-1164 DOI:10.1007/s11596-021-2501-4

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