Cheng Yong-Zhong, Yin Xiao-Dong, Liu Fei, Deng Xin-Heng, Wang Chao-Lu, Cui Shu-Ke, Li Yong-Yao, Yan Wei
Wangjing Hospital, China Academy of Chinese Medical Sciences, Beijing 100102, China; Nanyang City Traditional Chinese Medicine Hospital, Nanyang 473000, Henan, China.
Wangjing Hospital, China Academy of Chinese Medical Sciences, Beijing 100102, China.
Zhongguo Gu Shang. 2025 Jan 25;38(1):31-40. doi: 10.12200/j.issn.1003-0034.20240601.
To explore the accuracy of human-computer interaction software in identifying and locating type C1 distal radius fractures.
Based on relevant inclusion and exclusion criteria, 14 cases of type C1 distal radius fractures between September 2023 and March 2024 were retrospectively analyzed, comprising 3 males and 11 females(aged from 27 to 82 years). The data were assigned randomized identifiers. A senior orthopedic physician reviewed the films and measured the ulnar deviation angle, radial height, palmar inclination angle, intra-articular step, and intra-articular gap for each case on the hospital's imaging system. Based on the reduction standard for distal radius fractures, cases were divided into reduction group and non-reduction group. Then, the data were sequentially imported into a human-computer interaction intelligent software, where a junior orthopedic physician analyzed the same radiological parameters, categorized cases, and measured fracture details. The categorization results from the software were consistent with manual classifications (6 reduction cases and 8 non-reduction cases). For non-reduction cases, the software performed further analyses, including bone segmentation and fracture recognition, generating 8 diagnostic reports containing fracture recognition information. For the 6 reduction cases, the senior and junior orthopedic physicians independently analyzed the data on the hospital's imaging system and the AI software, respectively. Bone segments requiring reduction were identified, verified by two senior physicians, and measured for displacement and rotation along the X (inward and outward), Z (front and back), and Y (up and down) axes. The AI software generated comprehensive diagnostic reports for these cases, which included all measurements and fracture recognition details.
Both the manual and AI software methods consistently categorized the 14 cases into 6 reduction and 8 non-reduction groups, with identical data distributions. A paired sample t-test revealed no statistically significant differences (>0.05) between the manual and software-based measurements for ulnar deviation angle, radial ulnar bone height, palmar inclination angle, intra-articular step, and joint space. In fracture recognition, the AI software correctly identified 10 C-type fractures and 4 B-type fractures. For the 6 reduction cases, a total of 24 bone fragments were analyzed across both methods. After verification, it was found that the bone fragments identified by the two methods were consistent. A paired sample t-tests revealed that the identified bone fragments and measured displacement and rotation angles along the X, Y, and Z axes were consistent between the two methods. No statistically significant differences(>0.05) were found between manual and software measurements for these parameters.
Human-computer interaction software employing AI technology demonstrated comparable accuracy to manual measurement in identifying and locating type C1 distal radius fractures on CT imaging.
探讨人机交互软件在识别和定位桡骨远端C1型骨折方面的准确性。
根据相关纳入和排除标准,回顾性分析2023年9月至2024年3月期间的14例桡骨远端C1型骨折病例,其中男性3例,女性11例(年龄27至82岁)。数据被赋予随机标识符。一名资深骨科医生在医院的影像系统上查看X线片,并测量每例患者的尺偏角、桡骨高度、掌倾角、关节内台阶和关节间隙。根据桡骨远端骨折的复位标准,将病例分为复位组和未复位组。然后,将数据依次导入人机交互智能软件,由一名初级骨科医生分析相同的放射学参数,对病例进行分类,并测量骨折细节。软件的分类结果与人工分类一致(6例复位病例和8例未复位病例)。对于未复位病例,软件进行进一步分析,包括骨分割和骨折识别,生成8份包含骨折识别信息的诊断报告。对于6例复位病例,资深和初级骨科医生分别在医院的影像系统和人工智能软件上独立分析数据。识别出需要复位的骨块,由两名资深医生进行核实,并测量其在X(向内和向外)、Z(前后)和Y(上下)轴上的位移和旋转。人工智能软件为这些病例生成综合诊断报告,其中包括所有测量值和骨折识别细节。
人工和人工智能软件方法均将14例病例一致分为6例复位组和8例未复位组,数据分布相同。配对样本t检验显示,在尺偏角、桡尺骨高度、掌倾角、关节内台阶和关节间隙的人工测量与基于软件的测量之间,差异无统计学意义(>0.05)。在骨折识别方面,人工智能软件正确识别出10例C型骨折和4例B型骨折。对于6例复位病例,两种方法共分析了24块骨块。经核实,发现两种方法识别出的骨块一致。配对样本t检验显示,两种方法识别出的骨块以及在X、Y和Z轴上测量的位移和旋转角度一致。这些参数的人工测量与软件测量之间差异无统计学意义(>0.05)。
采用人工智能技术的人机交互软件在CT影像上识别和定位桡骨远端C1型骨折方面,显示出与人工测量相当的准确性。
