TY - JOUR
T1 - Differential diagnosis of lung carcinoma with three-dimensional quantitative molecular vibrational imaging
AU - Gao, Liang
AU - Hammoudi, Ahmad A.
AU - Li, Fuhai
AU - Thrall, Michael J.
AU - Cagle, Philip T.
AU - Chen, Yuanxin
AU - Yang, Jian
AU - Xia, Xiaofeng
AU - Fan, Yubo
AU - Massoud, Yehia
AU - Wang, Zhiyong
AU - Wong, Stephen T C
N1 - Funding Information:
We would like to thank Drs. Kelvin K. Wong, Hong Zhao, Kemi Cui and Zhong Xue from Department of Systems Medicine and Bioengineering, The Methodist Hospital Research Institute for helpful discussions. The funding of this research was initiated and supported by the Department of Systems Medicine and Bioengineering, TMHRI, Weill Cornell Medical College, and the TT & WF Chao Foundation and John S. Dunn Research Foundation to STCW. Provisional patent filed.
PY - 2012/6
Y1 - 2012/6
N2 - The advent of molecularly targeted therapies requires effective identification of the various cell types of non-small cell lung carcinomas (NSCLC). Currently, cell type diagnosis is performed using small biopsies or cytology specimens that are often insufficient for molecular testing after morphologic analysis. Thus, the ability to rapidly recognize different cancer cell types, with minimal tissue consumption, would accelerate diagnosis and preserve tissue samples for subsequent molecular testing in targeted therapy. We report a label-free molecular vibrational imaging framework enabling three-dimensional (3-D) image acquisition and quantitative analysis of cellular structures for identification of NSCLC cell types. This diagnostic imaging system employs superpixel-based 3-D nuclear segmentation for extracting such disease-related features as nuclear shape, volume, and cell-cell distance. These features are used to characterize cancer cell types using machine learning. Using fresh unstained tissue samples derived from cell lines grown in a mouse model, the platform showed greater than 97% accuracy for diagnosis of NSCLC cell types within a few minutes. As an adjunct to subsequent histology tests, our novel system would allow fast delineation of cancer cell types with minimum tissue consumption, potentially facilitating onthe- spot diagnosis, while preserving specimens for additional tests. Furthermore, 3-D measurements of cellular structure permit evaluation closer to the native state of cells, creating an alternative to traditional 2-D histology specimen evaluation, potentially increasing accuracy in diagnosing cell type of lung carcinomas.
AB - The advent of molecularly targeted therapies requires effective identification of the various cell types of non-small cell lung carcinomas (NSCLC). Currently, cell type diagnosis is performed using small biopsies or cytology specimens that are often insufficient for molecular testing after morphologic analysis. Thus, the ability to rapidly recognize different cancer cell types, with minimal tissue consumption, would accelerate diagnosis and preserve tissue samples for subsequent molecular testing in targeted therapy. We report a label-free molecular vibrational imaging framework enabling three-dimensional (3-D) image acquisition and quantitative analysis of cellular structures for identification of NSCLC cell types. This diagnostic imaging system employs superpixel-based 3-D nuclear segmentation for extracting such disease-related features as nuclear shape, volume, and cell-cell distance. These features are used to characterize cancer cell types using machine learning. Using fresh unstained tissue samples derived from cell lines grown in a mouse model, the platform showed greater than 97% accuracy for diagnosis of NSCLC cell types within a few minutes. As an adjunct to subsequent histology tests, our novel system would allow fast delineation of cancer cell types with minimum tissue consumption, potentially facilitating onthe- spot diagnosis, while preserving specimens for additional tests. Furthermore, 3-D measurements of cellular structure permit evaluation closer to the native state of cells, creating an alternative to traditional 2-D histology specimen evaluation, potentially increasing accuracy in diagnosing cell type of lung carcinomas.
KW - Artificial intelligence
KW - Lung cancer
KW - Microscopy
KW - Non-linear diagnostic imaging
KW - Non-near optics
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U2 - 10.1117/1.JBO.17.6.066017
DO - 10.1117/1.JBO.17.6.066017
M3 - Article
C2 - 22734773
AN - SCOPUS:84868661010
SN - 1083-3668
VL - 17
JO - Journal of Biomedical Optics
JF - Journal of Biomedical Optics
IS - 6
M1 - 066017
ER -