5 research outputs found
Case Studies on X-Ray Imaging, MRI and Nuclear Imaging
The field of medical imaging is an essential aspect of the medical sciences,
involving various forms of radiation to capture images of the internal tissues
and organs of the body. These images provide vital information for clinical
diagnosis, and in this chapter, we will explore the use of X-ray, MRI, and
nuclear imaging in detecting severe illnesses. However, manual evaluation and
storage of these images can be a challenging and time-consuming process. To
address this issue, artificial intelligence (AI)-based techniques, particularly
deep learning (DL), have become increasingly popular for systematic feature
extraction and classification from imaging modalities, thereby aiding doctors
in making rapid and accurate diagnoses. In this review study, we will focus on
how AI-based approaches, particularly the use of Convolutional Neural Networks
(CNN), can assist in disease detection through medical imaging technology. CNN
is a commonly used approach for image analysis due to its ability to extract
features from raw input images, and as such, will be the primary area of
discussion in this study. Therefore, we have considered CNN as our discussion
area in this study to diagnose ailments using medical imaging technology.Comment: 14 pages, 3 figures, 4 tables; Acceptance of the chapter for the
Springer book "Data-driven approaches to medical imaging
Invariant Scattering Transform for Medical Imaging
Invariant scattering transform introduces new area of research that merges
the signal processing with deep learning for computer vision. Nowadays, Deep
Learning algorithms are able to solve a variety of problems in medical sector.
Medical images are used to detect diseases brain cancer or tumor, Alzheimer's
disease, breast cancer, Parkinson's disease and many others. During pandemic
back in 2020, machine learning and deep learning has played a critical role to
detect COVID-19 which included mutation analysis, prediction, diagnosis and
decision making. Medical images like X-ray, MRI known as magnetic resonance
imaging, CT scans are used for detecting diseases. There is another method in
deep learning for medical imaging which is scattering transform. It builds
useful signal representation for image classification. It is a wavelet
technique; which is impactful for medical image classification problems. This
research article discusses scattering transform as the efficient system for
medical image analysis where it's figured by scattering the signal information
implemented in a deep convolutional network. A step by step case study is
manifested at this research work.Comment: 11 pages, 8 figures and 1 tabl
Generative Adversarial Networks for Data Augmentation
One way to expand the available dataset for training AI models in the medical
field is through the use of Generative Adversarial Networks (GANs) for data
augmentation. GANs work by employing a generator network to create new data
samples that are then assessed by a discriminator network to determine their
similarity to real samples. The discriminator network is taught to
differentiate between actual and synthetic samples, while the generator system
is trained to generate data that closely resemble real ones. The process is
repeated until the generator network can produce synthetic data that is
indistinguishable from genuine data. GANs have been utilized in medical image
analysis for various tasks, including data augmentation, image creation, and
domain adaptation. They can generate synthetic samples that can be used to
increase the available dataset, especially in cases where obtaining large
amounts of genuine data is difficult or unethical. However, it is essential to
note that the use of GANs in medical imaging is still an active area of
research to ensure that the produced images are of high quality and suitable
for use in clinical settings.Comment: 13 pages, 6 figures, 1 table; Acceptance of the chapter for the
Springer book "Data-driven approaches to medical imaging
Active Learning on Medical Image
The development of medical science greatly depends on the increased
utilization of machine learning algorithms. By incorporating machine learning,
the medical imaging field can significantly improve in terms of the speed and
accuracy of the diagnostic process. Computed tomography (CT), magnetic
resonance imaging (MRI), X-ray imaging, ultrasound imaging, and positron
emission tomography (PET) are the most commonly used types of imaging data in
the diagnosis process, and machine learning can aid in detecting diseases at an
early stage. However, training machine learning models with limited annotated
medical image data poses a challenge. The majority of medical image datasets
have limited data, which can impede the pattern-learning process of
machine-learning algorithms. Additionally, the lack of labeled data is another
critical issue for machine learning. In this context, active learning
techniques can be employed to address the challenge of limited annotated
medical image data. Active learning involves iteratively selecting the most
informative samples from a large pool of unlabeled data for annotation by
experts. By actively selecting the most relevant and informative samples,
active learning reduces the reliance on large amounts of labeled data and
maximizes the model's learning capacity with minimal human labeling effort. By
incorporating active learning into the training process, medical imaging
machine learning models can make more efficient use of the available labeled
data, improving their accuracy and performance. This approach allows medical
professionals to focus their efforts on annotating the most critical cases,
while the machine learning model actively learns from these annotated samples
to improve its diagnostic capabilities.Comment: 12 pages, 8 figures; Acceptance of the chapter for the Springer book
"Data-driven approaches to medical imaging
AutoML Systems For Medical Imaging
The integration of machine learning in medical image analysis can greatly
enhance the quality of healthcare provided by physicians. The combination of
human expertise and computerized systems can result in improved diagnostic
accuracy. An automated machine learning approach simplifies the creation of
custom image recognition models by utilizing neural architecture search and
transfer learning techniques. Medical imaging techniques are used to
non-invasively create images of internal organs and body parts for diagnostic
and procedural purposes. This article aims to highlight the potential
applications, strategies, and techniques of AutoML in medical imaging through
theoretical and empirical evidence.Comment: 11 pages, 4 figures; Acceptance of the chapter for the Springer book
"Data-driven approaches to medical imaging