Most Relevant Spectral Bands Identification for Brain Cancer Detection Using Hyperspectral Imaging.

Beatriz Martinez,Jesus Morera,Gustavo M Callico,Juan F Piñeiro,David Carrera,Mariano Marquez,Rafael Camacho,Sara Bisshopp,Samuel Ortega,Maria Hernandez,Carlos Espino,Raquel Leon,Aruma J O’Shanahan,Coralia Sosa,Maria De La Luz Plaza,Adam Szolna,Himar Fabelo

doi:10.3390/s19245481

Abstract

Hyperspectral imaging (HSI) is a non-ionizing and non-contact imaging technique capable of obtaining more information than conventional RGB (red green blue) imaging. In the medical field, HSI has commonly been investigated due to its great potential for diagnostic and surgical guidance purposes. However, the large amount of information provided by HSI normally contains redundant or non-relevant information, and it is extremely important to identify the most relevant wavelengths for a certain application in order to improve the accuracy of the predictions and reduce the execution time of the classification algorithm. Additionally, some wavelengths can contain noise and removing such bands can improve the classification stage. The work presented in this paper aims to identify such relevant spectral ranges in the visual-and-near-infrared (VNIR) region for an accurate detection of brain cancer using in vivo hyperspectral images. A methodology based on optimization algorithms has been proposed for this task, identifying the relevant wavelengths to achieve the best accuracy in the classification results obtained by a supervised classifier (support vector machines), and employing the lowest possible number of spectral bands. The results demonstrate that the proposed methodology based on the genetic algorithm optimization slightly improves the accuracy of the tumor identification in ~5%, using only 48 bands, with respect to the reference results obtained with 128 bands, offering the possibility of developing customized acquisition sensors that could provide real-time HS imaging. The most relevant spectral ranges found comprise between 440.5–465.96 nm, 498.71–509.62 nm, 556.91–575.1 nm, 593.29–615.12 nm, 636.94–666.05 nm, 698.79–731.53 nm and 884.32–902.51 nm.

Highlights

Around 260,000 brain tumor cases are detected each year, with the main brain tumor type being detected the glioblastoma multiforme (GBM) that has the highest death rate (22%) [1]
This section will present the results obtained in the three proposed processing frameworks, as well as the overall discussion of the results
The Processing Framework 1 (PF1) has the goal of performing a comparison between the use of different numbers of spectral bands in the HS database, modifying the sampling interval of the spectral data in order to simulate the use of different HS cameras and reducing the size of the database

Summary

Introduction

Around 260,000 brain tumor cases are detected each year, with the main brain tumor type being detected the glioblastoma multiforme (GBM) that has the highest death rate (22%) [1] This type of cancer leads to death in children under the age of 20, and is one of the principal causes of death among 20- to 29-year-old males [2]. Several image guidance tools, such as intra-operative neuro-navigation, intra-operative magnetic resonance imaging (iMRI) and fluorescent tumor markers, have been commonly used to assist in the identification of brain tumor boundaries. These technologies have several limitations, producing side effects in the patient or invalidating the patient-to-image mapping, reducing the effectiveness of using pre-operative images for intra-operative surgical guidance [4]. HS testwith dataset with area the surrounded tumor area in yellow (first row) and gold standard maps obtained with the semi-automatic labeling tool the surrounded in yellow (first row) and gold standard maps obtained with the semi-automatic from labeling

Objectives

Methods

Results

Conclusion