Liu Zhaochen, Wang Peiyan, Deng Nian, Zhang Hui, Xin Fangjie, Yu Xiaofei, Yuan Mujie, Yu Qiyue, Tang Yuhao, Dou Keke, Zhao Jie, He Bing, Deng Jing
Department of Stomatology, The Affiliated Hospital of Qingdao University, Qingdao, China.
School of Stomatology, Qingdao University, Qingdao, China.
Front Med (Lausanne). 2025 Mar 12;12:1550512. doi: 10.3389/fmed.2025.1550512. eCollection 2025.
This study aimed to evaluate the feasibility of applying deep learning combined with a super-resolution scanner for the digital scanning and diagnosis of oral epithelial dysplasia (OED) slides. A model of a super-resolution digital slide scanning system based on deep learning was built and trained using 40 pathological slides of oral epithelial tissue. Two hundred slides with definite OED diagnoses were scanned into digital slides by the DS30R and Nikon scanners, and the scanner parameters were obtained for comparison. Considering that diagnosis under a microscope is the gold standard, the sensitivity and specificity of OED pathological feature recognition by the same pathologist when reading different scanner images were evaluated. Furthermore, the consistency of whole-slide diagnosis results obtained by pathologists using various digital scanning imaging systems was assessed. This was done to evaluate the feasibility of the super-resolution digital slide-scanning system, which is based on deep learning, for the pathological diagnosis of OED. The DS30R scanner processes an entire slide in a single layer within 0.25 min, occupying 0.35GB of storage. In contrast, the Nikon scanner requires 15 min for scanning, utilizing 0.5GB of storage. Following model training, the system enhanced the clarity of imaging pathological sections of oral epithelial tissue. Both the DS30R and Nikon scanners demonstrate high sensitivity and specificity for detecting structural features in OED pathological images; however, DS30R excels at identifying certain cellular features. The agreement in full-section diagnostic conclusions by the same pathologist using different imaging systems was exceptionally high, with kappa values of 0.969 for DS30R-optical microscope and 0.979 for DS30R-Nikon-optical microscope. The performance of the super-resolution microscopic imaging system based on deep learning has improved. It preserves the diagnostic information of the OED and addresses the shortcomings of existing digital scanners, such as slow imaging speed, large data volumes, and challenges in rapid transmission and sharing. This high-quality super-resolution image lays a solid foundation for the future popularization of artificial intelligence (AI) technology and will aid AI in the accurate diagnosis of oral potential malignant diseases.
本研究旨在评估将深度学习与超分辨率扫描仪相结合用于口腔上皮发育异常(OED)玻片数字扫描及诊断的可行性。构建了基于深度学习的超分辨率数字玻片扫描系统模型,并使用40张口腔上皮组织病理玻片进行训练。将200张确诊为OED的玻片通过DS30R和尼康扫描仪扫描成数字玻片,并获取扫描仪参数进行比较。鉴于显微镜诊断是金标准,评估了同一位病理学家在读取不同扫描仪图像时对OED病理特征识别的敏感性和特异性。此外,还评估了病理学家使用各种数字扫描成像系统获得的全玻片诊断结果的一致性。这样做是为了评估基于深度学习的超分辨率数字玻片扫描系统用于OED病理诊断的可行性。DS30R扫描仪在0.25分钟内单层处理一整张玻片,占用0.35GB存储空间。相比之下,尼康扫描仪扫描需要15分钟,占用0.5GB存储空间。模型训练后,该系统提高了口腔上皮组织成像病理切片的清晰度。DS30R和尼康扫描仪在检测OED病理图像中的结构特征方面均表现出高敏感性和特异性;然而,DS30R在识别某些细胞特征方面表现出色。同一位病理学家使用不同成像系统得出的全切片诊断结论一致性非常高,DS30R与光学显微镜的kappa值为0.969,DS30R与尼康光学显微镜的kappa值为0.979。基于深度学习的超分辨率显微成像系统的性能有所提升。它保留了OED的诊断信息,解决了现有数字扫描仪成像速度慢、数据量大以及快速传输和共享方面的挑战等缺点。这种高质量的超分辨率图像为未来人工智能(AI)技术的普及奠定了坚实基础,并将有助于AI对口腔潜在恶性疾病进行准确诊断。
