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

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

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

Sparse feature learning for image analysis in segmentation, classification, and disease diagnosis.

The success of machine learning algorithms generally depends on intermediate data representation, called features that disentangle the hidden factors of variation in data. Moreover, machine learning models are required to be generalized, in order to reduce the specificity or bias toward the training dataset. Unsupervised feature learning is useful in taking advantage of large amount of unlabeled data, which is available to capture these variations. However, learned features are required to capture variational patterns in data space. In this dissertation, unsupervised feature learning with sparsity is investigated for sparse and local feature extraction with application to lung segmentation, interpretable deep models, and Alzheimer\u27s disease classification. Nonnegative Matrix Factorization, Autoencoder and 3D Convolutional Autoencoder are used as architectures or models for unsupervised feature learning. They are investigated along with nonnegativity, sparsity and part-based representation constraints for generalized and transferable feature extraction

Cancer diagnosis using deep learning: A bibliographic review

In this paper, we first describe the basics of the field of cancer diagnosis, which includes steps of cancer diagnosis followed by the typical classification methods used by doctors, providing a historical idea of cancer classification techniques to the readers. These methods include Asymmetry, Border, Color and Diameter (ABCD) method, seven-point detection method, Menzies method, and pattern analysis. They are used regularly by doctors for cancer diagnosis, although they are not considered very efficient for obtaining better performance. Moreover, considering all types of audience, the basic evaluation criteria are also discussed. The criteria include the receiver operating characteristic curve (ROC curve), Area under the ROC curve (AUC), F1 score, accuracy, specificity, sensitivity, precision, dice-coefficient, average accuracy, and Jaccard index. Previously used methods are considered inefficient, asking for better and smarter methods for cancer diagnosis. Artificial intelligence and cancer diagnosis are gaining attention as a way to define better diagnostic tools. In particular, deep neural networks can be successfully used for intelligent image analysis. The basic framework of how this machine learning works on medical imaging is provided in this study, i.e., pre-processing, image segmentation and post-processing. The second part of this manuscript describes the different deep learning techniques, such as convolutional neural networks (CNNs), generative adversarial models (GANs), deep autoencoders (DANs), restricted Boltzmann’s machine (RBM), stacked autoencoders (SAE), convolutional autoencoders (CAE), recurrent neural networks (RNNs), long short-term memory (LTSM), multi-scale convolutional neural network (M-CNN), multi-instance learning convolutional neural network (MIL-CNN). For each technique, we provide Python codes, to allow interested readers to experiment with the cited algorithms on their own diagnostic problems. The third part of this manuscript compiles the successfully applied deep learning models for different types of cancers. Considering the length of the manuscript, we restrict ourselves to the discussion of breast cancer, lung cancer, brain cancer, and skin cancer. The purpose of this bibliographic review is to provide researchers opting to work in implementing deep learning and artificial neural networks for cancer diagnosis a knowledge from scratch of the state-of-the-art achievements

Segmentation of pelvic structures from preoperative images for surgical planning and guidance

Prostate cancer is one of the most frequently diagnosed malignancies globally and the second leading cause of cancer-related mortality in males in the developed world. In recent decades, many techniques have been proposed for prostate cancer diagnosis and treatment. With the development of imaging technologies such as CT and MRI, image-guided procedures have become increasingly important as a means to improve clinical outcomes. Analysis of the preoperative images and construction of 3D models prior to treatment would help doctors to better localize and visualize the structures of interest, plan the procedure, diagnose disease and guide the surgery or therapy. This requires efficient and robust medical image analysis and segmentation technologies to be developed. The thesis mainly focuses on the development of segmentation techniques in pelvic MRI for image-guided robotic-assisted laparoscopic radical prostatectomy and external-beam radiation therapy. A fully automated multi-atlas framework is proposed for bony pelvis segmentation in MRI, using the guidance of MRI AE-SDM. With the guidance of the AE-SDM, a multi-atlas segmentation algorithm is used to delineate the bony pelvis in a new \ac{MRI} where there is no CT available. The proposed technique outperforms state-of-the-art algorithms for MRI bony pelvis segmentation. With the SDM of pelvis and its segmented surface, an accurate 3D pelvimetry system is designed and implemented to measure a comprehensive set of pelvic geometric parameters for the examination of the relationship between these parameters and the difficulty of robotic-assisted laparoscopic radical prostatectomy. This system can be used in both manual and automated manner with a user-friendly interface. A fully automated and robust multi-atlas based segmentation has also been developed to delineate the prostate in diagnostic MR scans, which have large variation in both intensity and shape of prostate. Two image analysis techniques are proposed, including patch-based label fusion with local appearance-specific atlases and multi-atlas propagation via a manifold graph on a database of both labeled and unlabeled images when limited labeled atlases are available. The proposed techniques can achieve more robust and accurate segmentation results than other multi-atlas based methods. The seminal vesicles are also an interesting structure for therapy planning, particularly for external-beam radiation therapy. As existing methods fail for the very onerous task of segmenting the seminal vesicles, a multi-atlas learning framework via random decision forests with graph cuts refinement has further been proposed to solve this difficult problem. Motivated by the performance of this technique, I further extend the multi-atlas learning to segment the prostate fully automatically using multispectral (T1 and T2-weighted) MR images via hybrid \ac{RF} classifiers and a multi-image graph cuts technique. The proposed method compares favorably to the previously proposed multi-atlas based prostate segmentation. The work in this thesis covers different techniques for pelvic image segmentation in MRI. These techniques have been continually developed and refined, and their application to different specific problems shows ever more promising results.Open Acces

Semantic Segmentation of Ambiguous Images

Medizinische Bilder können schwer zu interpretieren sein. Nicht nur weil das Erkennen von Strukturen und möglichen Veränderungen Erfahrung und jahrelanges Training bedarf, sondern auch weil die dargestellten Messungen oft im Kern mehrdeutig sind. Fundamental ist dies eine Konsequenz dessen, dass medizinische Bild-Modalitäten, wie bespielsweise MRT oder CT, nur indirekte Messungen der zu Grunde liegenden molekularen Identitäten bereithalten. Die semantische Bedeutung eines Bildes kann deshalb im Allgemeinen nur gegeben einem größeren Bild-Kontext erfasst werden, welcher es oft allerdings nur unzureichend erlaubt eine eindeutige Interpretation in Form einer einzelnen Hypothese vorzunehmen. Ähnliche Szenarien existieren in natürlichen Bildern, in welchen die Kontextinformation, die es braucht um Mehrdeutigkeiten aufzulösen, limitiert sein kann, beispielsweise aufgrund von Verdeckungen oder Rauschen in der Aufnahme. Zusätzlich können überlappende oder vage Klassen-Definitionen zu schlecht gestellten oder diversen Lösungsräumen führen. Die Präsenz solcher Mehrdeutigkeiten kann auch das Training und die Leistung von maschinellen Lernverfahren beeinträchtigen. Darüber hinaus sind aktuelle Modelle ueberwiegend unfähig komplex strukturierte und diverse Vorhersagen bereitzustellen und stattdessen dazu gezwungen sich auf sub-optimale, einzelne Lösungen oder ununterscheidbare Mixturen zu beschränken. Dies kann besonders problematisch sein wenn Klassifikationsverfahren zu pixel-weisen Vorhersagen wie in der semantischen Segmentierung skaliert werden. Die semantische Segmentierung befasst sich damit jedem Pixel in einem Bild eine Klassen-Kategorie zuzuweisen. Diese Art des detailierten Bild-Verständnisses spielt auch eine wichtige Rolle in der Diagnose und der Behandlung von Krankheiten wie Krebs: Tumore werden häufig in MRT oder CT Bildern entdeckt und deren präzise Lokalisierung und Segmentierung ist von grosser Bedeutung in deren Bewertung, der Vorbereitung möglicher Biopsien oder der Planung von Fokal-Therapien. Diese klinischen Bildverarbeitungen, aber auch die optische Wahrnehmung unserer Umgebung im Rahmen von täglichen Aufgaben wie dem Autofahren, werden momentan von Menschen durchgeführt. Als Teil des zunehmenden Einbindens von maschinellen Lernverfahren in unsere Entscheidungsfindungsprozesse, ist es wichtig diese Aufgaben adequat zu modellieren. Dies schliesst Unsicherheitsabschätzungen der Modellvorhersagen mit ein, mitunter solche Unsicherheiten die den Bild-Mehrdeutigkeiten zugeschrieben werden können. Die vorliegende Thesis schlägt mehrere Art und Weisen vor mit denen mit einer mehrdeutigen Bild-Evidenz umgegangen werden kann. Zunächst untersuchen wir den momentanen klinischen Standard der im Falle von Prostata Läsionen darin besteht, die MRT-sichtbaren Läsionen subjektiv auf ihre Aggressivität hin zu bewerten, was mit einer hohen Variabilität zwischen Bewertern einhergeht. Unseren Studien zufolge können bereits einfache machinelle Lernverfahren und sogar simple quantitative MRT-basierte Parameter besser abschneiden als ein individueller, subjektiver Experte, was ein vielversprechendes Potential der Quantifizerung des Prozesses nahelegt. Desweiteren stellen wir die derzeit erfolgreichste Segmentierungsarchitektur auf einem stark mehrdeutigen Datensatz zur Probe der während klinischer Routine erhoben und annotiert wurde. Unsere Experimente zeigen, dass die standard Segmentierungsverlustfuntion in Szenarien mit starkem Annotationsrauschen sub-optimal sein kann. Als eine Alternative erproben wir die Möglichkeit ein Modell der Verlustunktion zu lernen mit dem Ziel die Koexistenz von plausiblen Lösungen während des Trainings zuzulassen. Wir beobachten gesteigerte Performanz unter Verwendung dieser Trainingsmethode für ansonsten unveränderte neuronale Netzarchitekturen und finden weiter gesteigerte relative Verbesserungen im Limit weniger Daten. Mangel an Daten und Annotationen, hohe Maße an Bild- und Annotationsrauschen sowie mehrdeutige Bild-Evidenz finden sich besonders häufig in Datensätzen medizinischer Bilder wieder. Dieser Teil der Thesis exponiert daher einige der Schwächen die standard Techniken des maschinellen Lernens im Lichte dieser Besonderheiten aufweisen können. Derzeitige Segmentierungsmodelle, wie die zuvor Herangezogenen, sind dahingehend eingeschränkt, dass sie nur eine einzige Vorhersage abgeben können. Dies kontrastiert die Beobachtung dass eine Gruppe von Annotierern, gegeben mehrdeutiger Bilddaten, typischer Weise eine Menge an diverser aber plausibler Annotationen produziert. Um die vorgenannte Modell-Einschränkung zu beheben und die angemessen probabilistische Behandlung der Aufgabe zu ermöglichen, entwickeln wir zwei Modelle, die eine Verteilung über plausible Annotationen vorhersagen statt nur einer einzigen, deterministischen Annotation. Das erste der beiden Modelle kombiniert ein `encoder-decoder\u27 Modell mit dem Verfahren der `variational inference\u27 und verwendet einen globalen `latent vector\u27, der den Raum der möglichen Annotationen für ein gegebenes Bild kodiert. Wir zeigen, dass dieses Modell deutlich besser als die Referenzmethoden abschneidet und gut kalibrierte Unsicherheiten aufweist. Das zweite Modell verbessert diesen Ansatz indem es eine flexiblere und hierarchische Formulierung verwendet, die es erlaubt die Variabilität der Segmentierungen auf verschiedenden Skalen zu erfassen. Dies erhöht die Granularität der Segmentierungsdetails die das Modell produzieren kann und erlaubt es unabhängig variierende Bildregionen und Skalen zu modellieren. Beide dieser neuartigen generativen Segmentierungs-Modelle ermöglichen es, falls angebracht, diverse und kohärente Bild Segmentierungen zu erstellen, was im Kontrast zu früheren Arbeiten steht, welche entweder deterministisch sind, die Modellunsicherheiten auf der Pixelebene modellieren oder darunter leiden eine unangemessen geringe Diversität abzubilden. Im Ergebnis befasst sich die vorliegende Thesis mit der Anwendung von maschinellem Lernen für die Interpretation medizinischer Bilder: Wir zeigen die Möglichkeit auf den klinischen Standard mit Hilfe einer quantitativen Verwendung von Bildparametern, die momentan nur subjektiv in Diagnosen einfliessen, zu verbessern, wir zeigen den möglichen Nutzen eines neuen Trainingsverfahrens um die scheinbare Verletzlichkeit der standard Segmentierungsverlustfunktion gegenüber starkem Annotationsrauschen abzumildern und wir schlagen zwei neue probabilistische Segmentierungsmodelle vor, die die Verteilung über angemessene Annotationen akkurat erlernen können. Diese Beiträge können als Schritte hin zu einer quantitativeren, verstärkt Prinzipien-gestützten und unsicherheitsbewussten Analyse von medizinischen Bildern gesehen werden -ein wichtiges Ziel mit Blick auf die fortschreitende Integration von lernbasierten Systemen in klinischen Arbeitsabläufen

Medical imaging analysis with artificial neural networks

Given that neural networks have been widely reported in the research community of medical imaging, we provide a focused literature survey on recent neural network developments in computer-aided diagnosis, medical image segmentation and edge detection towards visual content analysis, and medical image registration for its pre-processing and post-processing, with the aims of increasing awareness of how neural networks can be applied to these areas and to provide a foundation for further research and practical development. Representative techniques and algorithms are explained in detail to provide inspiring examples illustrating: (i) how a known neural network with fixed structure and training procedure could be applied to resolve a medical imaging problem; (ii) how medical images could be analysed, processed, and characterised by neural networks; and (iii) how neural networks could be expanded further to resolve problems relevant to medical imaging. In the concluding section, a highlight of comparisons among many neural network applications is included to provide a global view on computational intelligence with neural networks in medical imaging