Improved Machine Learning Method for Intracranial Tumor Detection with Accelerated Particle Swarm Optimization.
K R PradeepSyam Machinathu Parambil GangadharanWesam Atef HatamlehHussam TaraziPiyush Kumar ShuklaBasant TiwariPublished in: Journal of healthcare engineering (2022)
The field of image processing is distinguished by the variety of functions it offers and the wide range of applications it has in biomedical imaging. It becomes a difficult and time-consuming process for radiologists to do the manual identification and categorization of the tumour. It is a complex and time-consuming procedure conducted by radiologists or clinical professionals to remove the contaminated tumour region from magnetic resonance (MR) pictures. It is the goal of this study to improve the performance and reduce the complexity of the image segmentation process by investigating FCM predicted image segmentation procedures in order to reduce the intricacy of the process. Furthermore, relevant characteristics are collected from each segmented tissue and aligned as input to the classifiers for autonomous identification and relegation of encephalon cancers in order to increase the accuracy and quality rate of the neural network classifier. An evaluation, validation, and presentation of the experimental performance of the suggested approach have been completed. A unique APSO (accelerated particle swarm optimization) based artificial neural network model (ANNM) for the relegation of benign and malignant tumours is presented in this study effort, which allows for the automated identification and categorization of brain tumours. Using APSO training to improve the suggested ANNM model parameters would give a unique method to alleviate the stressful work of radiologists performing manual identification of encephalon cancers from MR images. The use of an APSO-based ANNM (artificial neural network model) model for automated brain tumour classification has been presented in order to demonstrate the resilience of the classification model. It has been suggested to utilise the improved enhanced fuzzy c means (IEnFCM) method for image segmentation, while the GLCM (gray level co-occurrence matrix) feature extraction approach has been employed for feature extraction from magnetic resonance imaging (MR pictures).
Keyphrases
- deep learning
- neural network
- machine learning
- artificial intelligence
- convolutional neural network
- magnetic resonance
- magnetic resonance imaging
- contrast enhanced
- big data
- risk assessment
- computed tomography
- heavy metals
- high resolution
- climate change
- bioinformatics analysis
- resting state
- young adults
- photodynamic therapy
- quantum dots
- virtual reality