A Deep Learning Model Using Hyperspectral Image for EUS-FNA Cytology Diagnosis in Pancreatic Ductal Adenocarcinoma

Overview

Journal Cancer Med

Specialty Oncology

Date 2023 Jul 17

PMID 37455599

Authors

Xianzheng Qin

Minmin Zhang

Chunhua Zhou

Taojing Ran

Yundi Pan

Yingjiao Deng

XingRan Xie

Yao Zhang

Tingting Gong

Benyan Zhang

Ling Zhang

Yan Wang

Qingli Li

Dong Wang

Lili Gao

Duowu Zou

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Endoscopic ultrasonography-guided fine-needle aspiration/biopsy (EUS-FNA/B) is considered to be a first-line procedure for the pathological diagnosis of pancreatic cancer owing to its high accuracy and low complication rate. The number of new cases of pancreatic ductal adenocarcinoma (PDAC) is increasing, and its accurate pathological diagnosis poses a challenge for cytopathologists. Our aim was to develop a hyperspectral imaging (HSI)-based convolution neural network (CNN) algorithm to aid in the diagnosis of pancreatic EUS-FNA cytology specimens.

Methods: HSI images were captured of pancreatic EUS-FNA cytological specimens from benign pancreatic tissues (n = 33) and PDAC (n = 39) prepared using a liquid-based cytology method. A CNN was established to test the diagnostic performance, and Attribution Guided Factorization Visualization (AGF-Visualization) was used to visualize the regions of important classification features identified by the model.

Results: A total of 1913 HSI images were obtained. Our ResNet18-SimSiam model achieved an accuracy of 0.9204, sensitivity of 0.9310 and specificity of 0.9123 (area under the curve of 0.9625) when trained on HSI images for the differentiation of PDAC cytological specimens from benign pancreatic cells. AGF-Visualization confirmed that the diagnoses were based on the features of tumor cell nuclei.

Conclusions: An HSI-based model was developed to diagnose cytological PDAC specimens obtained using EUS-guided sampling. Under the supervision of experienced cytopathologists, we performed multi-staged consecutive in-depth learning of the model. Its superior diagnostic performance could be of value for cytologists when diagnosing PDAC.

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