Hyperparameter Optimization for Brain Tumor Classification with Hyperspectral Images

Hyperparameter Optimization for Brain Tumor Classification with Hyperspectral Images

Hyperspectral (HS) imaging (HSI) techniques have demonstrated to be useful in the medical field to characterize tissues without any contact and without ionizing the patient. Besides, HSI combined with supervised machine learning (ML) algorithms have proven to be an effective technique to assist neur...

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Bibliographic Details
Published in:2022 25th Euromicro Conference on Digital System Design (DSD) pp. 835 - 842
Main Authors: Martin-Perez, Alberto, Villa, Manuel, Vazquez, Guillermo, Sancho, Jaime, Rosa, Gonzalo, Sutradhar, Pallab, Chavarrias, Miguel, Lagares, Alfonso, Juarez, Eduardo, Sanz, Cesar
Format: Conference Proceeding
Language:English
Published: IEEE 01-08-2022
Subjects:
Brain modeling
brain tumor
Classification algorithms
glioblastoma
grid search
hyperparameter
hyperspectral imaging
Machine learning algorithms
Radio frequency
random forest
random search
sequential based-model optimization
Spatial resolution
support vector machine
Support vector machine classification
Support vector machines
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Summary:Hyperspectral (HS) imaging (HSI) techniques have demonstrated to be useful in the medical field to characterize tissues without any contact and without ionizing the patient. Besides, HSI combined with supervised machine learning (ML) algorithms have proven to be an effective technique to assist neurosurgeons to resect brain tumors. This research looks at the effects of hyperparameter optimization on two common supervised ML algorithms used for brain tumor classification: support vector machines (SVM) and random forest (RF). Correctly classifying brain tumor with HS data containing low spatial and spectral information can be challenging. To tackle this problem, this study has applied hyperparameter optimization techniques on SVM and RF with 10 brain images of patients suffering from glioblastoma multiforme (GBM) with non-mutated isocitrate dehydrogenase (IDH) enzymes. These captures have 409x217 spatial resolution and 25 normalized reflectance wavelengths gathered from 665 to 960 nm with a HS snapshot camera. Results show how this work has been able to obtain 98,60% of weighted area under the curve (AUC) on the test score by employing naive optimizations like grid search (GS) or random search (RS) and even more complex methods based on Bayesian optimization (BO). Not only the weighted AUC of SVM has been improved by 8%, but BO have also enhanced the AUC of the tumor class by 22.50% in comparison with non-optimized SVM models in the state-of-the-art, achieving AUC values of 95,49% on the tumor class. Furthermore, these improvements have been illustrated with classification maps to demonstrate the importance of hyperparameter optimization on SVM to clearly classify brain tumor, whereas non-optimized models from previous studies are unable to detect the tumor.
ISSN:2771-2508
DOI:10.1109/DSD57027.2022.00117