Semantic Segmentation of Urinary Bladder Cancer Masses from CT Images: A Transfer Learning Approach.

Sandi Baressi Šegota,Josip Španjol,Nikola Anđelić,Zlatan Car,Vedran Mrzljak,Dean Markić,Jelena Musulin,Klara Smolić,Ivan Lorencin,Daniel Štifanić

doi:10.3390/biology10111134

Abstract

Simple SummaryBladder cancer is a common cancer of the urinary tract, characterized by high metastatic potential and recurrence. The research applies a transfer learning approach on CT images (frontal, axial, and saggital axes) for the purpose of semantic segmentation of areas affected by bladder cancer. A system consisting of AlexNet network for plane recognition, using transfer learning-based U-net networks for the segmentation task. Achieved results show that the proposed system has a high performance, suggesting possible use in clinical practice.Urinary bladder cancer is one of the most common cancers of the urinary tract. This cancer is characterized by its high metastatic potential and recurrence rate. Due to the high metastatic potential and recurrence rate, correct and timely diagnosis is crucial for successful treatment and care. With the aim of increasing diagnosis accuracy, artificial intelligence algorithms are introduced to clinical decision making and diagnostics. One of the standard procedures for bladder cancer diagnosis is computer tomography (CT) scanning. In this research, a transfer learning approach to the semantic segmentation of urinary bladder cancer masses from CT images is presented. The initial data set is divided into three sub-sets according to image planes: frontal (4413 images), axial (4993 images), and sagittal (996 images). First, AlexNet is utilized for the design of a plane recognition system, and it achieved high classification and generalization performances with an of 0.9999 and of 0.0006. Furthermore, by applying the transfer learning approach, significant improvements in both semantic segmentation and generalization performances were achieved. For the case of the frontal plane, the highest performances were achieved if pre-trained ResNet101 architecture was used as a backbone for U-net with up to 0.9587 and of 0.0059. When U-net was used for the semantic segmentation of urinary bladder cancer masses from images in the axial plane, the best results were achieved if pre-trained ResNet50 was used as a backbone, with a up to 0.9372 and of 0.0147. Finally, in the case of images in the sagittal plane, the highest results were achieved with VGG-16 as a backbone. In this case, values up to 0.9660 with a of 0.0486 were achieved. From the listed results, the proposed semantic segmentation system worked with high performance both from the semantic segmentation and generalization standpoints. The presented results indicate that there is the possibility for the utilization of the semantic segmentation system in clinical practice.

Highlights

Urinary bladder cancer is one of the ten most common cancers worldwide
When the results of plane classification achieved by using AlexNet CNN architecture are observed, it can be noticed that the highest classification and generalization performances are achieved if the AlexNet architecture is trained by using RMS-prop optimizer for 10 consecutive epochs with data batches of 16
If DCS and σ ( DSC ) achieved on all three planes are compared, it can be noticed that the highest semantic segmentation performances are achieved on the sagittal plane, if pre-trained VGG-16 architecture is used as a backbone

Summary

Introduction

Urinary bladder cancer is one of the ten most common cancers worldwide. It is characterized by an cancerous alteration and uncontrollable growth of bladder tissue, typically urothelial cells, which develop into a tumor and can spread into other organs.Patients who suffer from bladder cancer may exhibit various symptoms, such as painful and frequent urination, blood in the urine, and lower back pain. Urinary bladder cancer is one of the ten most common cancers worldwide It is characterized by an cancerous alteration and uncontrollable growth of bladder tissue, typically urothelial cells, which develop into a tumor and can spread into other organs. Research indicates that tobacco smoking largely increases the risk of developing bladder cancer [1]. Other external factors that may increase the risk of bladder cancer are a previous exposure to radiation, frequent bladder infections, obesity, and exposure to certain chemicals, such as aromatic amines [2,3]. Multiple different pathohistological subtypes of bladder cancer exist, including urothelial carcinoma (transitional cell carcinoma)—the most common type of bladder cancer [4]; squamous cell carcinoma—which is rare and associated with chronic irritation of the bladder commonly due to infections or prolonged catheterization [5]; adenocarcinoma—a very rare subtype of cancer, arising in other, neighboring organs as well [6]; small cell carcinoma—a highly aggressive type of cancer with a high metastatic potential, commonly diagnosed at advanced stages [7]; and sarcoma—an extremely rare and aggressive type of bladder cancer [8]

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