Randomized Tree Ensembles for Object Detection in Computational Pathology

Fuchs, Thomas J.; Haybaeck, Johannes; Wild, Peter J.; Heikenwälder, Mathias; Moch, Holger; Aguzzi, Adriano; Buhmann, Joachim M.

doi:10.1007/978-3-642-10331-5_35

Cited by 6 publications

(9 citation statements)

References 14 publications

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“…It is an ongoing project in kidney cancer research conducted at the University Hospital Zurich and ETH Zurich. Parts of it were published in [100] and [42], where also algorithmic details of the computational approach can be found. Figure 8 depicts a schematic overview of the project subdivided into the three main parts which are discussed in the following:…”

Section: The Computational Pathology Pipeline: a Holistic Viewmentioning

confidence: 41%

“…Relational Detection Forests [42] provide one possibility to overcome this problem of information loss. Especially designed for detection of cell nuclei in histological slides, they are based on the concept of randomized trees [43].…”

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

“…The feature base proposed in [42] is defined as follows: The coordinates of two rectangles R 1 and R 2 are sampled uniformly within a predefined window size w:…”

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

“…Approaches like AdaBoost [46] which yield very good results for up to hundreds of thousands of features are not applicable any more. These problems can be overcome by employing randomized algorithms [42,47] where features are sampled randomly for learning classifiers on these random projections.…”

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

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Computational pathology: Challenges and promises for tissue analysis

Fuchs

Buhmann

2011

Computerized Medical Imaging and Graphics

Self Cite

231

127

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The histological assessment of human tissue has emerged as the key challenge for detection and treatment of cancer. A plethora of different data sources ranging from tissue microarray data to gene expression, proteomics or metabolomics data provide a detailed overview of the health status of a patient. Medical doctors need to assess these information sources and they rely on data driven automatic analysis tools. Methods for classification, grouping and segmentation of heterogeneous data sources as well as regression of noisy dependencies and estimation of survival probabilities enter the processing workflow of a pathology diagnosis system at various stages. This paper reports on state-of-the-art of the design and effectiveness of computational pathology workflows and it discusses future research directions in this emergent field of medical informatics and diagnostic machine learning.

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Section: The Computational Pathology Pipeline: a Holistic Viewmentioning

confidence: 41%

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

“…The feature base proposed in [42] is defined as follows: The coordinates of two rectangles R 1 and R 2 are sampled uniformly within a predefined window size w:…”

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

Section: Preprocessing Vs Algorithmic Invariancementioning

confidence: 99%

See 2 more Smart Citations

Computational pathology: Challenges and promises for tissue analysis

Fuchs

Buhmann

2011

Computerized Medical Imaging and Graphics

Self Cite

231

127

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“…As corresponding examples, we can mention neural networks [2], [3], decision trees [4], sets of rules [5] and other models [6], [7], [8]. As a specific application field, now we will focus on object detection in digital images which is a vivid field [9], [10], [11], as well.…”

Section: Introductionsupporting

confidence: 46%

Generalizing the Majority Voting Scheme to Spatially Constrained Voting

Hajdú

Hajdu

Jónás

et al. 2013

IEEE Trans. on Image Process.

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Abstract-Generating ensembles from multiple individual classifiers is a usual appraoch to raise the accuracy of the decision. For decision majority voting is a popular rule. In this paper, we generalize classic majority voting by letting a further constraint to decide whether a correct or false decision is made if k correct votes is present among the total n ones. This generalization is motivated by object detection problems, where the members of the ensemble are image processing algorithms giving their votes as pixels in the image domain. The shape of the desired object define a geometric constraint the votes should obey to be able to decide together. Namely, the votes in this scenarion should fall inside a region matching the shape of the object. We give several theoretical result in this new model for both dependent/indipendent classifiers, whose individual accuracies may also differ. As a real world example we present our ensemble-based system developed for the detection of the optic disc in retinal images. For this problem experimental results are shown on how our model is capable to characterize such a system and how the model can give a helping hand on the further improvability of the system, as well.

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Seeing Is Believing: Quantifying Is Convincing: Computational Image Analysis in Biology

Sbalzarini

2016

Advances in Anatomy, Embryology and Cell Biology

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Imaging is center stage in biology. Advances in microscopy and labeling techniques have enabled unprecedented observations and continue to inspire new developments. Efficient and accurate quantification and computational analysis of the acquired images, however, are becoming the bottleneck. We review different paradigms of computational image analysis for intracellular, single-cell, and tissue-level imaging, providing pointers to the specialized literature and listing available software tools. We place particular emphasis on clear categorization of image-analysis frameworks and on identifying current trends and challenges in the field. We further outline some of the methodological advances that are required in order to use images as quantitative scientific measurements.

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Randomized Tree Ensembles for Object Detection in Computational Pathology

Cited by 6 publications

References 14 publications

Computational pathology: Challenges and promises for tissue analysis

Computational pathology: Challenges and promises for tissue analysis

Generalizing the Majority Voting Scheme to Spatially Constrained Voting

Seeing Is Believing: Quantifying Is Convincing: Computational Image Analysis in Biology

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