Abstract 1234P
Background
Recently, the field of digital pathology has seen an increase in research utilizing deep learning techniques. This allows for predictions such as cancer diagnosis, prognosis, and treatment response, which previously required additional analysis, such as genetic analysis that was both time-consuming and costly, to be made based on pathological imaging. However, digital pathology images often contain noise, such as inconsistent staining and inconsistent annotations. To address this issue, image preprocessing is essential in deep learning analysis of digital pathology images, and various preprocessing techniques have been proposed to address issues such as bias, overfitting, and robust deep learning model development. However, automated preprocessing methods for digital pathology images have not yet been fully developed.
Methods
To address this, we have developed a user-friendly tool for image preprocessing analysis called HistoMate.
Results
HistoMate provides GUI-based image segmentation, image tiling, color normalization, and deep learning-based data augmentation to automate the preprocessing process. It also provides functionality to evaluate image quality and select appropriate patches.
Conclusions
In conclusion, HistoMate provides an automated preprocessing tool for pathological image-based research, accelerating digital pathology-based research.
Clinical trial identification
Editorial acknowledgement
This work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korean Government (MSIT) (grant no. NRF-2021R1C1C1013706), and research fund by Seoul National University Bundang Hospital (grant no. 14-2018-0013).
Legal entity responsible for the study
The authors.
Funding
This work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korean Government (MSIT) (grant no. NRF-2021R1C1C1013706), and research fund by Seoul National University Bundang Hospital (grant no. 14-2018-0013).
Disclosure
All authors have declared no conflicts of interest.
Resources from the same session
1241P - Decoding the glycan code: Pioneering early detection of non-small cell lung cancer through glycoproteomics
Presenter: Kai He
Session: Poster session 14
1242P - Implementing functional precision oncology in real-world patients: Translating extensive in vitro data into personalized treatment combining genetics and functional assays
Presenter: Dörthe Schaffrin-Nabe
Session: Poster session 14
1243P - Ocular surface squamous neoplasia early diagnosis using an AI-empowered autofluorescence multispectral imaging technique
Presenter: Abbas HABIBALAHI
Session: Poster session 14
1244P - AI-based accurate PD-L1 IHC assessment in non-small cell lung cancer across multiple sites and scanners
Presenter: Ramona Erber
Session: Poster session 14
1245P - A lymph nodal staging assessment model for various histologic types of small intestinal tumors
Presenter: YOUSHENG LI
Session: Poster session 14
1246P - Detection of alternative lengthening of telomeres (ALT) across cancer types based on tumor-normal multigene panel sequencing
Presenter: Juan Blanco Heredia
Session: Poster session 14
1247P - A detection model for EGFR mutations in lung adenocarcinoma patients based on volatile organic compounds
Presenter: Yunpeng Yang
Session: Poster session 14
1248P - Development of a high performance and noninvasive diagnostic model using blood cell-free microRNAs for multi-cancer early detection
Presenter: Jason Zhang
Session: Poster session 14
1249P - Whole genome sequencing-based cancer diagnostics in routine clinical practice: An interim analysis of two years of real-world data
Presenter: Jeffrey van Putten
Session: Poster session 14
1250P - Assessing lung carcinoma: A retrospective study on volume evaluation, consolidation and infiltration using chest OMX
Presenter: Swarnambiga Ayyachamy
Session: Poster session 14