661 research outputs found
A Survey on Deep Learning in Medical Image Analysis
Deep learning algorithms, in particular convolutional networks, have rapidly
become a methodology of choice for analyzing medical images. This paper reviews
the major deep learning concepts pertinent to medical image analysis and
summarizes over 300 contributions to the field, most of which appeared in the
last year. We survey the use of deep learning for image classification, object
detection, segmentation, registration, and other tasks and provide concise
overviews of studies per application area. Open challenges and directions for
future research are discussed.Comment: Revised survey includes expanded discussion section and reworked
introductory section on common deep architectures. Added missed papers from
before Feb 1st 201
Histopathological image analysis : a review
Over the past decade, dramatic increases in computational power and improvement in image analysis algorithms have allowed the development of powerful computer-assisted analytical approaches to radiological data. With the recent advent of whole slide digital scanners, tissue histopathology slides can now be digitized and stored in digital image form. Consequently, digitized tissue histopathology has now become amenable to the application of computerized image analysis and machine learning techniques. Analogous to the role of computer-assisted diagnosis (CAD) algorithms in medical imaging to complement the opinion of a radiologist, CAD algorithms have begun to be developed for disease detection, diagnosis, and prognosis prediction to complement the opinion of the pathologist. In this paper, we review the recent state of the art CAD technology for digitized histopathology. This paper also briefly describes the development and application of novel image analysis technology for a few specific histopathology related problems being pursued in the United States and Europe
Brain Tumor Detection and Segmentation in Multisequence MRI
Tato prĂĄce se zabĂœvĂĄ detekcĂ a segmentacĂ mozkovĂ©ho nĂĄdoru v multisekvenÄnĂch MR obrazech se zamÄĆenĂm na gliomy vysokĂ©ho a nĂzkĂ©ho stupnÄ malignity. Jsou zde pro tento ĂșÄel navrĆŸeny tĆi metody. PrvnĂ metoda se zabĂœvĂĄ detekcĂ prezence ÄĂĄstĂ mozkovĂ©ho nĂĄdoru v axiĂĄlnĂch a koronĂĄrnĂch Ćezech. JednĂĄ se o algoritmus zaloĆŸenĂœ na analĂœze symetrie pĆi rĆŻznĂœch rozliĆĄenĂch obrazu, kterĂœ byl otestovĂĄn na T1, T2, T1C a FLAIR obrazech. DruhĂĄ metoda se zabĂœvĂĄ extrakcĂ oblasti celĂ©ho mozkovĂ©ho nĂĄdoru, zahrnujĂcĂ oblast jĂĄdra tumoru a edĂ©mu, ve FLAIR a T2 obrazech. Metoda je schopna extrahovat mozkovĂœ nĂĄdor z 2D i 3D obrazĆŻ. Je zde opÄt vyuĆŸita analĂœza symetrie, kterĂĄ je nĂĄsledovĂĄna automatickĂœm stanovenĂm intenzitnĂho prahu z nejvĂce asymetrickĂœch ÄĂĄstĂ. TĆetĂ metoda je zaloĆŸena na predikci lokĂĄlnĂ struktury a je schopna segmentovat celou oblast nĂĄdoru, jeho jĂĄdro i jeho aktivnĂ ÄĂĄst. Metoda vyuĆŸĂvĂĄ faktu, ĆŸe vÄtĆĄina lĂ©kaĆskĂœch obrazĆŻ vykazuje vysokou podobnost intenzit sousednĂch pixelĆŻ a silnou korelaci mezi intenzitami v rĆŻznĂœch obrazovĂœch modalitĂĄch. JednĂm ze zpĆŻsobĆŻ, jak s touto korelacĂ pracovat a pouĆŸĂvat ji, je vyuĆŸitĂ lokĂĄlnĂch obrazovĂœch polĂ. PodobnĂĄ korelace existuje takĂ© mezi sousednĂmi pixely v anotaci obrazu. Tento pĆĂznak byl vyuĆŸit v predikci lokĂĄlnĂ struktury pĆi lokĂĄlnĂ anotaci polĂ. Jako klasifikaÄnĂ algoritmus je v tĂ©to metodÄ pouĆŸita konvoluÄnĂ neuronovĂĄ sĂĆ„ vzhledem k jejĂ znĂĄme schopnosti zachĂĄzet s korelacĂ mezi pĆĂznaky. VĆĄechny tĆi metody byly otestovĂĄny na veĆejnĂ© databĂĄzi 254 multisekvenÄnĂch MR obrazech a byla dosĂĄhnuta pĆesnost srovnatelnĂĄ s nejmodernÄjĆĄĂmi metodami v mnohem kratĆĄĂm vĂœpoÄetnĂm Äase (v ĆĂĄdu sekund pĆi pouĆŸitĂœ CPU), coĆŸ poskytuje moĆŸnost manuĂĄlnĂch Ășprav pĆi interaktivnĂ segmetaci.This work deals with the brain tumor detection and segmentation in multisequence MR images with particular focus on high- and low-grade gliomas. Three methods are propose for this purpose. The first method deals with the presence detection of brain tumor structures in axial and coronal slices. This method is based on multi-resolution symmetry analysis and it was tested for T1, T2, T1C and FLAIR images. The second method deals with extraction of the whole brain tumor region, including tumor core and edema, in FLAIR and T2 images and is suitable to extract the whole brain tumor region from both 2D and 3D. It also uses the symmetry analysis approach which is followed by automatic determination of the intensity threshold from the most asymmetric parts. The third method is based on local structure prediction and it is able to segment the whole tumor region as well as tumor core and active tumor. This method takes the advantage of a fact that most medical images feature a high similarity in intensities of nearby pixels and a strong correlation of intensity profiles across different image modalities. One way of dealing with -- and even exploiting -- this correlation is the use of local image patches. In the same way, there is a high correlation between nearby labels in image annotation, a feature that has been used in the ``local structure prediction'' of local label patches. Convolutional neural network is chosen as a learning algorithm, as it is known to be suited for dealing with correlation between features. All three methods were evaluated on a public data set of 254 multisequence MR volumes being able to reach comparable results to state-of-the-art methods in much shorter computing time (order of seconds running on CPU) providing means, for example, to do online updates when aiming at an interactive segmentation.
A compressive survey on different image processing techniques to identify the brain tumor.
Medical imaging technology has revolutionized health care over the past three decades, allowing doctors to detect, cure and improve patient outcomes. Medicinal imaging involves pictures - of internal organs, parts, tissues and bones - for therapeutic examination and research purposes. X-ray and CT scanners are the two greatest results of progress in imaging methods supplanting 2D procedures. Magnetic resonance imaging (MRI) is an imaging procedure that is utilized in radiology to visualize interior structures of the body and better understand how they work. X-ray provides a 3D image of the body's interior; as well as being critical for tumor discovery, this also enables surgeons to more easily dissect infections or tumors than was possible with older X-beam technology, which provided a 2D image. This paper provides an overview of different systems that can be used for distinguishing and preparing medical images
Surface loss for medical image segmentation
Last decades have witnessed an unprecedented expansion of medical data in various largescale and complex systems. While achieving a lot of successes in many complex medical problems, there are still some challenges to deal with. Class imbalance is one of the common problems of medical image segmentation. It occurs mostly when there is a severely unequal class distribution, for instance, when the size of target foreground region is several orders of magnitude less that the background region size. In such problems, typical loss functions used for convolutional neural networks (CNN) segmentation fail to deliver good performances.
Widely used losses,e.g., Dice or cross-entropy, are based on regional terms. They assume that all classes are equally distributed. Thus, they tend to favor the majority class and misclassify the target class. To address this issue, the main objective of this work is to build a boundary loss, a distance based measure on the space of contours and not regions. We argue that a boundary loss can mitigate the problems of regional losses via introducing a complementary distance-based information. Our loss is inspired by discrete (graph-based) optimization techniques for computing gradient flows of curve evolution.
Following an integral approach for computing boundary variations, we express a non-symmetric L2 distance on the space of shapes as a regional integral, which avoids completely local differential computations. Our boundary loss is the sum of linear functions of the regional softmax probability outputs of the network. Therefore, it can easily be combined with standard regional losses and implemented with any existing deep network architecture for N-dimensional segmentation (N-D).
Experiments were carried on three benchmark datasets corresponding to increasingly unbalanced segmentation problems: Multi modal brain tumor segmentation (BRATS17), the ischemic stroke lesion (ISLES) and white matter hyperintensities (WMH). Used in conjunction with the region-based generalized Dice loss (GDL), our boundary loss improves performance significantly compared to GDL alone, reaching up to 8% improvement in Dice score and 10% improvement in Hausdorff score. It also yielded a more stable learning process
Rapid Segmentation Techniques for Cardiac and Neuroimage Analysis
Recent technological advances in medical imaging have allowed for the quick acquisition of highly resolved data to aid in diagnosis and characterization of diseases or to guide interventions. In order to to be integrated into a clinical work flow, accurate and robust methods of analysis must be developed which manage this increase in data. Recent improvements in in- expensive commercially available graphics hardware and General-Purpose Programming on Graphics Processing Units (GPGPU) have allowed for many large scale data analysis problems to be addressed in meaningful time and will continue to as parallel computing technology improves. In this thesis we propose methods to tackle two clinically relevant image segmentation problems: a user-guided segmentation of myocardial scar from Late-Enhancement Magnetic Resonance Images (LE-MRI) and a multi-atlas segmentation pipeline to automatically segment and partition brain tissue from multi-channel MRI. Both methods are based on recent advances in computer vision, in particular max-flow optimization that aims at solving the segmentation problem in continuous space. This allows for (approximately) globally optimal solvers to be employed in multi-region segmentation problems, without the particular drawbacks of their discrete counterparts, graph cuts, which typically present with metrication artefacts. Max-flow solvers are generally able to produce robust results, but are known for being computationally expensive, especially with large datasets, such as volume images. Additionally, we propose two new deformable registration methods based on Gauss-Newton optimization and smooth the resulting deformation fields via total-variation regularization to guarantee the problem is mathematically well-posed. We compare the performance of these two methods against four highly ranked and well-known deformable registration methods on four publicly available databases and are able to demonstrate a highly accurate performance with low run times. The best performing variant is subsequently used in a multi-atlas segmentation pipeline for the segmentation of brain tissue and facilitates fast run times for this computationally expensive approach. All proposed methods are implemented using GPGPU for a substantial increase in computational performance and so facilitate deployment into clinical work flows. We evaluate all proposed algorithms in terms of run times, accuracy, repeatability and errors arising from user interactions and we demonstrate that these methods are able to outperform established methods. The presented approaches demonstrate high performance in comparison with established methods in terms of accuracy and repeatability while largely reducing run times due to the employment of GPU hardware
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