Christopher Tai-Yi Lee’s research while affiliated with National Institutes of Health and other places

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Publications (1)


Fig. 1 . Example key-images of 5 classes of anatomy in our data set: neck, lungs, liver, pelvis and legs. 
Fig. 2 . The first layer of learned convolutional kernels of a ConvNet trained on medical CT images. 
Fig. 3 . ConvNet applied to an axial CT image. The number of convolutional filters and neural network connections for each layer are as shown. 
Fig. 4 . Data augmentation using varying random transforma- tions, rotations and non-rigid deformations using thin-plate- spline (TPS) interpolations on an example image grid. 
Fig. 5 . Confusion matrices on the original test images before 1 

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Anatomy-specific classification of medical images using deep convolutional nets
  • Conference Paper
  • Full-text available

April 2015

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1,783 Reads

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205 Citations

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Christopher Tai-Yi Lee

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Hoo-Chang Shin

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Automated classification of human anatomy is an important prerequisite for many computer-aided diagnosis systems. The spatial complexity and variability of anatomy throughout the human body makes classification difficult. “Deep learning” methods such as convolutional networks (ConvNets) outperform other state-of-the-art methods in image classification tasks. In this work, we present a method for organ- or body-part-specific anatomical classification of medical images acquired using computed tomography (CT) with ConvNets. We train a ConvNet, using 4,298 separate axial 2D key-images to learn 5 anatomical classes. Key-images were mined from a hospital PACS archive, using a set of 1,675 patients. We show that a data augmentation approach can help to enrich the data set and improve classification performance. Using ConvNets and data augmentation, we achieve anatomy-specific classification error of 5.9 % and area-under-the-curve (AUC) values of an average of 0.998 in testing. We demonstrate that deep learning can be used to train very reliable and accurate classifiers that could initialize further computer-aided diagnosis.

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Citations (1)


... In the field of medical imaging, CNNs have found significant applications, including tasks such as classifying interstitial lung diseases based on computed tomography (CT) images, as highlighted byAnthimopoulos et al. (2016). They have also been used for classifying tuberculosis manifestations using X-ray images(Cao et al., 2016), distinguishing neural progenitor cells from somatic cell sources(Jiang et al., 2015), identifying hemorrhages in color fundus images (Van Grinsven et al., 2016), and anatomically classifying organs or body parts in CT images(Roth et al., 2015). While CNNs are primarily designed for 2-D images, tasks involving MRI and CT segmentation inherently require the processing of 3-D data. ...

Reference:

ADVANCEMENTS AND CHALLENGES IN HEALTH INFORMATICS: A COMPREHENSIVE OVERVIEW OF DATA MANAGEMENT, INTEROPERABILITY, AI APPLICATIONS, AND PRIVACY CONCERNS
Anatomy-specific classification of medical images using deep convolutional nets