Predicting Breast Tumor Malignancy Using Deep ConvNeXt Radiomics and Quality-Based Score Pooling in Ultrasound Sequences

Hassanien, Mohamed A. M.; Singh, Vivek Kumar; Puig, Domènec; Abdel-Nasser, Mohamed

doi:10.3390/diagnostics12051053

Cited by 33 publications

(14 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Hassanien et al presented a new DL-based radiomics method called ConvNeXt to endow the CAD to predict the malignancy score of a breast lesion. By using a vision transformer style, the ConvNeXt system is able to perform the malignant score analysis of breast ultrasound sequences and present visual interpretations for its decision [ 65 ]. Jabeen and colleagues optimized feature extraction and improved breast cancer categorization accuracy to 99.1% by modifying and retraining the deep model named DarkNet53.…”

Section: Resultsmentioning

confidence: 99%

Overview of Artificial Intelligence in Breast Cancer Medical Imaging

Zheng

Jing

2023

JCM

View full text Add to dashboard Cite

The heavy global burden and mortality of breast cancer emphasize the importance of early diagnosis and treatment. Imaging detection is one of the main tools used in clinical practice for screening, diagnosis, and treatment efficacy evaluation, and can visualize changes in tumor size and texture before and after treatment. The overwhelming number of images, which lead to a heavy workload for radiologists and a sluggish reporting period, suggests the need for computer-aid detection techniques and platform. In addition, complex and changeable image features, heterogeneous quality of images, and inconsistent interpretation by different radiologists and medical institutions constitute the primary difficulties in breast cancer screening and imaging diagnosis. The advancement of imaging-based artificial intelligence (AI)-assisted tumor diagnosis is an ideal strategy for improving imaging diagnosis efficient and accuracy. By learning from image data input and constructing algorithm models, AI is able to recognize, segment, and diagnose tumor lesion automatically, showing promising application prospects. Furthermore, the rapid advancement of “omics” promotes a deeper and more comprehensive recognition of the nature of cancer. The fascinating relationship between tumor image and molecular characteristics has attracted attention to the radiomic and radiogenomics, which allow us to perform analysis and detection on the molecular level with no need for invasive operations. In this review, we integrate the current developments in AI-assisted imaging diagnosis and discuss the advances of AI-based breast cancer precise diagnosis from a clinical point of view. Although AI-assisted imaging breast cancer screening and detection is an emerging field and draws much attention, the clinical application of AI in tumor lesion recognition, segmentation, and diagnosis is still limited to research or in limited patients’ cohort. Randomized clinical trials based on large and high-quality cohort are lacking. This review aims to describe the progress of the imaging-based AI application in breast cancer screening and diagnosis for clinicians.

show abstract

Section: Resultsmentioning

confidence: 99%

Overview of Artificial Intelligence in Breast Cancer Medical Imaging

Zheng

Jing

2023

JCM

View full text Add to dashboard Cite

show abstract

“…Path enhancement structure is used to mine multi-scale features in fine segmentation. In Paper [3], a deep learning-based radiomics method for breast ultrasound sequences was mainly introduced.…”

Section: Related Workmentioning

confidence: 99%

Image segmentation of gastroscopy based on ConvNeXt 2.5D UNet

Xing,

Kang,

et al. 2023

International Conference on Computer, Artificial Intelligence, and Control Engineering (CAICE 2023)

View full text Add to dashboard Cite

Image segmentation as a crucial step in image processing and analysis, has important applications in video surveillance, medical detection and wafer detection, etc. Accurate and efficient image segmentation can bring great advantages and convenience to the realization of related tasks in these fields. In this paper, a 2.5D UNet network based on ConvNeXt is proposed to realize the image segmentation task based on the gastroscopy image dataset. The experimental results show that the proposed method has better segmentation performance than the UNet model based on ResNet50, UNet model based on EfficientNetB0, and UNET2.5D model based on EfficientNetB1.

show abstract

“…ConvNeXt also has many applications in medicine. The study proposes to use ConvNeXt to predict the malignant degree of breast tumors 21 . The study offers to use 3D ConvNeXt to detect COVID and predict its severity 22 .…”

Section: Related Workmentioning

confidence: 99%

“…The study proposes to use ConvNeXt to predict the malignant degree of breast tumors. 21 The study offers to use 3D ConvNeXt to detect COVID and predict its severity. 22 The study uses variants of ConvNeXt to classify colorectal polyps from histopathological images.…”

Section: Introductionmentioning

confidence: 99%

Cerebral stroke classification based on fusion model of 3D EmbedConvNext and 3D Bi‐LSTM network

Wang

Jiang

2023

Int J Imaging Syst Tech

View full text Add to dashboard Cite

Acute stroke can be effectively treated within 4.5 h. To help doctors judge the onset time of this disease as soon as possible, a fusion model of 3D EmbedConvNext and 3D Bi‐LSTM network was proposed. It uses DWI brain images to distinguish between cases where the stroke onset time is within 4.5 h and beyond. 3D EmbedConvNeXt replaces 2D convolution with 3D convolution based on the original ConvNeXt, and the downsample layer uses the self‐attention module. 3D features of EmbedConvNeXt were output to 3D Bi‐LSTM for learning. 3D Bi‐LSTM is mainly used to obtain the spatial relationship of multiple planes (axial, coronal, and sagittal), to effectively learn the 3D time series information in the depth, length, and width directions of the feature maps. The classification experiments on stroke data sets provided by cooperative hospitals show that our model achieves an accuracy of 0.83.

show abstract

Predicting Breast Tumor Malignancy Using Deep ConvNeXt Radiomics and Quality-Based Score Pooling in Ultrasound Sequences

Cited by 33 publications

References 38 publications

Overview of Artificial Intelligence in Breast Cancer Medical Imaging

Overview of Artificial Intelligence in Breast Cancer Medical Imaging

Image segmentation of gastroscopy based on ConvNeXt 2.5D UNet

Cerebral stroke classification based on fusion model of 3D EmbedConvNext and 3D Bi‐LSTM network

Contact Info

Product

Resources

About