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Journal Of Modern Oncology[ISSN:1672-4992/CN:61-1415/R]

Issue:

2024 22

Page:

4250-4254

Research Field:

Publishing date:

Info

Title:

Study on pathological diagnosis model of intraoperative frozen sections of epithelial ovarian cancer based on deep transfer learning

Author(s):

FU Xiaojuan¹; ZHAO Ying¹; ZHOU Zhihao²; LI Xiaorong¹; HOU Mengchen¹; CAI Fengmei¹; WANG Huifang¹

1.Department of Pathology,Xi'an People's Hospital (The Fourth Hospital of Xi'an),Shaanxi Xi'an 710004,China;2.School of Information Science and Technology,Northwest University,Shaanxi Xi'an 710127,China.

Keywords:

epithelial ovarian cancer; intraoperative frozen section; artificial intelligence; transfer learning; pathological diagnosis

PACS:

R737.31

DOI:

10.3969/j.issn.1672-4992.2024.22.006

Abstract:

Objective:To explore the pathological diagnostic model for intraoperative frozen sections of epithelial ovarian cancer using deep transfer learning and to assess its practical value.Methods:From January 2021 to December 2022,25 intraoperative frozen sections and 121 postoperative paraffin sections of ovarian epithelial cancer from department of pathology of our hospital were collected.These included five histopathological types (serous carcinoma,mucinous carcinoma,endometrioid carcinoma,clear cell carcinoma,and metastatic signet ring cell carcinoma),which were scanned into whole-slide digital pathology images.Image block datasets were extracted from these sections,with those outside the annotation frames categorized as "Other", resulting in six distinct image block datasets.The datasets were split into training,testing,and validation sets in a 3∶1∶1 ratio respectively.A model from scratch was trained using the frozen section dataset,while a pretrained model was trained using the paraffin section dataset.The pretrained model was further optimized on the frozen section dataset through transfer learning to develop a deep transfer learning model.The performance of the trained six-category datasets was compared in corresponding test sets with and without the application of the transfer learning model.Results:Compared to the model trained from scratch,the transfer learning model presented a significant improvement across all metrics,achieving a prediction accuracy of 90% for all six classes of image blocks.Conclusion:The transfer learning model exhibits a high level of accuracy and stability in the classification of pathological images from intraoperative frozen sections of epithelial ovarian cancer,indicating good potential for wider implementation.

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Memo

Memo:

陕西省2022年重点研发计划项目（编号：2022SF-504）

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