The Application of Deep Convolutional Neural Networks to Brain Cancer Images: A Survey

Shirazi, Amin Zadeh; Fornaciari, Eric; McDonnell, Mark D.; Yaghoobi, Mahdi; Cevallos, Yesenia; Tello-Oquendo, Luis; Inca, Deysi; Gómez, Guillermo A.

doi:10.3390/jpm10040224

Cited by 40 publications

(20 citation statements)

References 79 publications

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“…We have previously shown that DCNN models can be trained and applied to TCGA H&E histopathological images to predict brain cancer patient survival 46 (see also review in ref. 47 ). To analyse the relationship between segmentation results and patient survival, we next performed Pearson correlation analysis between the area of different brain tumour regions and patient survival across (i) all TCGA glioblastomas, and (ii) brain tumours harbouring the 13 most frequent mutations (PTEN, TP53, EGFR, NF1, PIK3CA, PI3KR1, TRAPP, ATRX, PDGFRA, KMT2C, PB1, GRIN2A, IDH1; see Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

A deep convolutional neural network for segmentation of whole-slide pathology images identifies novel tumour cell-perivascular niche interactions that are associated with poor survival in glioblastoma

et al. 2021

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Background Glioblastoma is the most aggressive type of brain cancer with high-levels of intra- and inter-tumour heterogeneity that contribute to its rapid growth and invasion within the brain. However, a spatial characterisation of gene signatures and the cell types expressing these in different tumour locations is still lacking. Methods We have used a deep convolutional neural network (DCNN) as a semantic segmentation model to segment seven different tumour regions including leading edge (LE), infiltrating tumour (IT), cellular tumour (CT), cellular tumour microvascular proliferation (CTmvp), cellular tumour pseudopalisading region around necrosis (CTpan), cellular tumour perinecrotic zones (CTpnz) and cellular tumour necrosis (CTne) in digitised glioblastoma histopathological slides from The Cancer Genome Atlas (TCGA). Correlation analysis between segmentation results from tumour images together with matched RNA expression data was performed to identify genetic signatures that are specific to different tumour regions. Results We found that spatially resolved gene signatures were strongly correlated with survival in patients with defined genetic mutations. Further in silico cell ontology analysis along with single-cell RNA sequencing data from resected glioblastoma tissue samples showed that these tumour regions had different gene signatures, whose expression was driven by different cell types in the regional tumour microenvironment. Our results further pointed to a key role for interactions between microglia/pericytes/monocytes and tumour cells that occur in the IT and CTmvp regions, which may contribute to poor patient survival. Conclusions This work identified key histopathological features that correlate with patient survival and detected spatially associated genetic signatures that contribute to tumour-stroma interactions and which should be investigated as new targets in glioblastoma. The source codes and datasets used are available in GitHub: https://github.com/amin20/GBM_WSSM.

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Section: Resultsmentioning

confidence: 99%

A deep convolutional neural network for segmentation of whole-slide pathology images identifies novel tumour cell-perivascular niche interactions that are associated with poor survival in glioblastoma

et al. 2021

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“…A complete image classification model is a combination of convolutional and non-linearity layers, followed by several fully connected layers. With this architecture a number of models have been proposed, such as AlexNet (2012), ZF Net (2013), GoogLeNet (2014), VGGNet (2014), ResNet (2015), DenseNet (2016) (Khan et al, 2020 ).…”

Section: Methodsmentioning

confidence: 99%

A Database for Learning Numbers by Visual Finger Recognition in Developmental Neuro-Robotics

et al. 2021

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Numerical cognition is a fundamental component of human intelligence that has not been fully understood yet. Indeed, it is a subject of research in many disciplines, e.g., neuroscience, education, cognitive and developmental psychology, philosophy of mathematics, linguistics. In Artificial Intelligence, aspects of numerical cognition have been modelled through neural networks to replicate and analytically study children behaviours. However, artificial models need to incorporate realistic sensory-motor information from the body to fully mimic the children's learning behaviours, e.g., the use of fingers to learn and manipulate numbers. To this end, this article presents a database of images, focused on number representation with fingers using both human and robot hands, which can constitute the base for building new realistic models of numerical cognition in humanoid robots, enabling a grounded learning approach in developmental autonomous agents. The article provides a benchmark analysis of the datasets in the database that are used to train, validate, and test five state-of-the art deep neural networks, which are compared for classification accuracy together with an analysis of the computational requirements of each network. The discussion highlights the trade-off between speed and precision in the detection, which is required for realistic applications in robotics.

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“…Researchers and readers who are interested in further papers on brain tumor classification using CNN can examine the following review articles (Litjens et al 2017 ; Lotan et al 2019 ; Muhammad et al 2021 ; Shaver et al 2019 ; Shirazi et al 2020 ; Tandel et al 2019 ; Tiwari et al 2020 ), which are very rich resources on this topic.…”

Section: Related Workmentioning

confidence: 99%

Multi-Classification of Brain Tumor MRI Images Using Deep Convolutional Neural Network with Fully Optimized Framework

Irmak

2021

Iran J Sci Technol Trans Electr Eng

242

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The Application of Deep Convolutional Neural Networks to Brain Cancer Images: A Survey

Cited by 40 publications

References 79 publications

A deep convolutional neural network for segmentation of whole-slide pathology images identifies novel tumour cell-perivascular niche interactions that are associated with poor survival in glioblastoma

A deep convolutional neural network for segmentation of whole-slide pathology images identifies novel tumour cell-perivascular niche interactions that are associated with poor survival in glioblastoma

A Database for Learning Numbers by Visual Finger Recognition in Developmental Neuro-Robotics

Multi-Classification of Brain Tumor MRI Images Using Deep Convolutional Neural Network with Fully Optimized Framework

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