Your search keyword '"WANG Yunfu"' showing total 3 results

1. When machine vision meets histology: A comparative evaluation of model architecture for classification of histology sections

Author

Zhong, Cheng, Han, Ju, Borowsky, Alexander, Parvin, Bahram, Wang, Yunfu, and Chang, Hang

Subjects

Biomedical and Clinical Sciences, Engineering, Rare Diseases, Brain Cancer, Cancer, Brain Disorders, Color, Histological Techniques, Humans, Pattern Recognition, Automated, Unsupervised Machine Learning, Computational histopathology, Classification, Unsupervised feature learning, Sparse feature encoder, Medical and Health Sciences, Nuclear Medicine & Medical Imaging, Biomedical and clinical sciences

Abstract

Classification of histology sections in large cohorts, in terms of distinct regions of microanatomy (e.g., stromal) and histopathology (e.g., tumor, necrosis), enables the quantification of tumor composition, and the construction of predictive models of genomics and clinical outcome. To tackle the large technical variations and biological heterogeneities, which are intrinsic in large cohorts, emerging systems utilize either prior knowledge from pathologists or unsupervised feature learning for invariant representation of the underlying properties in the data. However, to a large degree, the architecture for tissue histology classification remains unexplored and requires urgent systematical investigation. This paper is the first attempt to provide insights into three fundamental questions in tissue histology classification: I. Is unsupervised feature learning preferable to human engineered features? II. Does cellular saliency help? III. Does the sparse feature encoder contribute to recognition? We show that (a) in I, both Cellular Morphometric Feature and features from unsupervised feature learning lead to superior performance when compared to SIFT and [Color, Texture]; (b) in II, cellular saliency incorporation impairs the performance for systems built upon pixel-/patch-level features; and (c) in III, the effect of the sparse feature encoder is correlated with the robustness of features, and the performance can be consistently improved by the multi-stage extension of systems built upon both Cellular Morphmetric Feature and features from unsupervised feature learning. These insights are validated with two cohorts of Glioblastoma Multiforme (GBM) and Kidney Clear Cell Carcinoma (KIRC).

Published

2017

2. Integrative Analysis of Cellular Morphometric Context Reveals Clinically Relevant Signatures in Lower Grade Glioma.

Author

Han, Ju, Wang, Yunfu, Cai, Weidong, Borowsky, Alexander, Parvin, Bahram, and Chang, Hang

Subjects

cellular morphometric context, cellular morphometric type, consensus clustering, gene set enrichment analysis, lower grade glioma, spatial pyramid matching, survival analysis, Rare Diseases, Genetics, Brain Disorders, Cancer, Brain Cancer, Human Genome, Artificial Intelligence & Image Processing

Abstract

Integrative analysis based on quantitative representation of whole slide images (WSIs) in a large histology cohort may provide predictive models of clinical outcome. On one hand, the efficiency and effectiveness of such representation is hindered as a result of large technical variations (e.g., fixation, staining) and biological heterogeneities (e.g., cell type, cell state) that are always present in a large cohort. On the other hand, perceptual interpretation/validation of important multivariate phenotypic signatures are often difficult due to the loss of visual information during feature transformation in hyperspace. To address these issues, we propose a novel approach for integrative analysis based on cellular morphometric context, which is a robust representation of WSI, with the emphasis on tumor architecture and tumor heterogeneity, built upon cellular level morphometric features within the spatial pyramid matching (SPM) framework. The proposed approach is applied to The Cancer Genome Atlas (TCGA) lower grade glioma (LGG) cohort, where experimental results (i) reveal several clinically relevant cellular morphometric types, which enables both perceptual interpretation/validation and further investigation through gene set enrichment analysis; and (ii) indicate the significantly increased survival rates in one of the cellular morphometric context subtypes derived from the cellular morphometric context.

Published

2016

3. Phenotypic Characterization of Breast Invasive Carcinoma via Transferable Tissue Morphometric Patterns Learned from Glioblastoma Multiforme

Author

Han, Ju, Fontenay, Gerald V, Wang, Yunfu, Mao, Jian-Hua, and Chang, Hang

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Breast Cancer, Genetics, Cancer, Rare Diseases, Brain Cancer, Brain Disorders, Neurosciences, Human Genome, Breast invasive carcinoma, unsupervised feature learning, knowledge sharing, predictive sparse decomposition, consensus clustering, survival analysis, enrichment analysis

Abstract

Quantitative analysis of whole slide images (WSIs) in a large cohort may provide predictive models of clinical outcome. However, the performance of the existing techniques is hindered as a result of large technical variations (e.g., fixation, staining) and biological heterogeneities (e.g., cell type, cell state) that are always present in a large cohort. Although unsupervised feature learning provides a promising way in learning pertinent features without human intervention, its capability can be greatly limited due to the lack of well-curated examples. In this paper, we explored the transferability of knowledge acquired from a well-curated Glioblastoma Multiforme (GBM) dataset through its application to the representation and characterization of tissue histology from the Cancer Genome Atlas (TCGA) Breast Invasive Carcinoma (BRCA) cohort. Our experimental results reveals two major phenotypic subtypes with statistically significantly different survival curves. Further differential expression analysis of these two subtypes indicates enrichment of genes regulated by NF-kB in response to TNF and genes up-regulated in response to IFNG.

Published

2016