Computer Aided Diagnosis Using Multilevel Image Features on Large-Scale Evaluation

Lü, Le; Devarakota, Pandu; Vikal, Siddharth; Wu, Dijia; Zheng, Yefeng; Wolf, Matthias

doi:10.1007/978-3-319-05530-5_16

Cited by 11 publications

(9 citation statements)

References 26 publications

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“…highly tuned CADe systems for colonic polyp detection in CTC, such as [37], [40], [38]. Note that our system achieves significantly higher sensitivities of 95%, 98% at 1 or 3 FP/vol.…”

Section: H Detection Of Colonic Polypsmentioning

confidence: 86%

“…There exist two types of cascaded CADe classification architectures for false positive reduction are two types: 1) extraction of new image features followed by retraining of a classifier on all candidates [39], [38], [6], [20], [40] (from Sec. II-D) or 2) design of application dependent post-filtering components [41], [42], [43].…”

Section: E Cascaded Cade Architectures For False Positive Reductionmentioning

confidence: 99%

“…For all imaging data sets used in this study, the image patches were centered at each CADe coordinate (of candidate VOI centroid from pre-existing CADe systems [4], [26], [25], [27]) with 32 × 32 pixels in resolution. All patches were sampled at 4 scales of s = [30,35,40,45] mm ROI edge length in physical image space, after isotropic resampling of the input CT images (see Fig. 4).…”

Section: A Imaging Data Sets and Implementationmentioning

confidence: 99%

“…Each three-channel image patch (as a 2.5D view) is centered at a CADe coordinate with 32 × 32 pixels. Again, all patches are sampled at 4 scales: s = [30,35,40,45] mm for the VOI edge length in the physical image space, after isotropic resampling of the CT images (see Fig. 4).…”

Section: E Detection Of Thoracoabdominal Lymph Nodesmentioning

confidence: 99%

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Improving Computer-Aided Detection UsingConvolutional Neural Networks and Random View Aggregation

Roth

Lü

Liu

et al. 2016

IEEE Trans. Med. Imaging

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526

347

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Automated computer-aided detection (CADe) has been an important tool in clinical practice and research. State-of-the-art methods often show high sensitivities at the cost of high false-positives (FP) per patient rates. We design a two-tiered coarse-to-fine cascade framework that first operates a candidate generation system at sensitivities ∼ 100% of but at high FP levels. By leveraging existing CADe systems, coordinates of regions or volumes of interest (ROI or VOI) are generated and function as input for a second tier, which is our focus in this study. In this second stage, we generate 2D (two-dimensional) or 2.5D views via sampling through scale transformations, random translations and rotations. These random views are used to train deep convolutional neural network (ConvNet) classifiers. In testing, the ConvNets assign class (e.g., lesion, pathology) probabilities for a new set of random views that are then averaged to compute a final per-candidate classification probability. This second tier behaves as a highly selective process to reject difficult false positives while preserving high sensitivities. The methods are evaluated on three data sets: 59 patients for sclerotic metastasis detection, 176 patients for lymph node detection, and 1,186 patients for colonic polyp detection. Experimental results show the ability of ConvNets to generalize well to different medical imaging CADe applications and scale elegantly to various data sets. Our proposed methods improve performance markedly in all cases. Sensitivities improved from 57% to 70%, 43% to 77%, and 58% to 75% at 3 FPs per patient for sclerotic metastases, lymph nodes and colonic polyps, respectively.

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“…highly tuned CADe systems for colonic polyp detection in CTC, such as [37], [40], [38]. Note that our system achieves significantly higher sensitivities of 95%, 98% at 1 or 3 FP/vol.…”

Section: H Detection Of Colonic Polypsmentioning

confidence: 86%

Section: E Cascaded Cade Architectures For False Positive Reductionmentioning

confidence: 99%

Section: A Imaging Data Sets and Implementationmentioning

confidence: 99%

Section: E Detection Of Thoracoabdominal Lymph Nodesmentioning

confidence: 99%

See 2 more Smart Citations

Improving Computer-Aided Detection UsingConvolutional Neural Networks and Random View Aggregation

Roth

Lü

Liu

et al. 2016

IEEE Trans. Med. Imaging

Self Cite

526

347

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show abstract

“…However, none of these methods could robustly handle touching cell segmentation challenges exhibited in lung cancer images. Lu et al [23] has proposed a supervised learning-based segmentation algorithm to support new image features extraction and polyp detection on CT images, and a flexible, hierarchical feature learning framework integrating different levels of discriminative and descriptive information is presented in [24]. Supervised learning is a potential approach to tackle these challenges, but it requires a lot of labeled training data provided by experienced pathologists.…”

Section: Introductionmentioning

confidence: 99%

Novel image markers for non-small cell lung cancer classification and survival prediction

Wang

Xing

et al. 2014

BMC Bioinformatics

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BackgroundNon-small cell lung cancer (NSCLC), the most common type of lung cancer, is one of serious diseases causing death for both men and women. Computer-aided diagnosis and survival prediction of NSCLC, is of great importance in providing assistance to diagnosis and personalize therapy planning for lung cancer patients.ResultsIn this paper we have proposed an integrated framework for NSCLC computer-aided diagnosis and survival analysis using novel image markers. The entire biomedical imaging informatics framework consists of cell detection, segmentation, classification, discovery of image markers, and survival analysis. A robust seed detection-guided cell segmentation algorithm is proposed to accurately segment each individual cell in digital images. Based on cell segmentation results, a set of extensive cellular morphological features are extracted using efficient feature descriptors. Next, eight different classification techniques that can handle high-dimensional data have been evaluated and then compared for computer-aided diagnosis. The results show that the random forest and adaboost offer the best classification performance for NSCLC. Finally, a Cox proportional hazards model is fitted by component-wise likelihood based boosting. Significant image markers have been discovered using the bootstrap analysis and the survival prediction performance of the model is also evaluated.ConclusionsThe proposed model have been applied to a lung cancer dataset that contains 122 cases with complete clinical information. The classification performance exhibits high correlations between the discovered image markers and the subtypes of NSCLC. The survival analysis demonstrates strong prediction power of the statistical model built from the discovered image markers.

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Overview of the 2013 Workshop on Medical Computer Vision (MCV 2013)

Müller

Menze

Montillo

et al. 2014

Medical Computer Vision. Large Data in Medical Imaging

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Computer Aided Diagnosis Using Multilevel Image Features on Large-Scale Evaluation

Cited by 11 publications

References 26 publications

Improving Computer-Aided Detection UsingConvolutional Neural Networks and Random View Aggregation

Improving Computer-Aided Detection UsingConvolutional Neural Networks and Random View Aggregation

Novel image markers for non-small cell lung cancer classification and survival prediction

Overview of the 2013 Workshop on Medical Computer Vision (MCV 2013)

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