Abstract
It can be challenging to detect tumor margins during surgery for complete resection. The purpose of this work is to develop a novel learning method that learns the difference between the tumor and benign tissue adaptively for cancer detection on hyperspectral images in an animal model. Specifically, an auto-encoder network is trained based on the wavelength bands on hyperspectral images to extract the deep information to create a pixel-wise prediction of cancerous and benign pixel. According to the output hypothesis of each pixel, the misclassified pixels would be reclassified in the right prediction direction based on their adaptive weights. The auto-encoder network is again trained based on these updated pixels. The learner can adaptively improve the ability to identify the cancer and benign tissue by focusing on the misclassified pixels, and thus can improve the detection performance. The adaptive deep learning method highlighting the tumor region proved to be accurate in detecting the tumor boundary on hyperspectral images and achieved a sensitivity of 92.32% and a specificity of 91.31% in our animal experiments. This adaptive learning method on hyperspectral imaging has the potential to provide a noninvasive tool for tumor detection, especially, for the tumor whose margin is indistinct and irregular.
Highlights
Orophary cancer is a common cancer worldwide and in recent years its incidence increased in a fast pace in both America and Europe [1]
We demonstrate the efficiency and effectiveness of the auto-encoder and adaptive deep learning in Hyperspectral imaging (HSI) for head and neck cancer detection in an animal model
Tumor cells had green fluorescence protein (GFP) signals and GFP images were acquired as the reference standard to evaluate the proposed tumor detection algorithm
Summary
Orophary cancer is a common cancer worldwide and in recent years its incidence increased in a fast pace in both America and Europe [1]. More than half a million patients receive the diagnosis of squamous-cell carcinoma of the head and neck worldwide each year [2]. Survival rate of patients relates directly to the size of the primary tumor at first diagnosis, early detection can be helpful in curing the disease completely. Squamous-cell carcinoma of the head and neck is a complex disease, which can be biopsied for histopathological assessment to make a definitive diagnosis traditionally. That is time consuming and invasive, and subjective and inconsistent [3]. Hyperspectral imaging (HSI) is a technology that can acquire a series of images in many adjacent narrow
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