Published in J Biomed Opt on March 01, 2017
Spectral-domain phase microscopy. Opt Lett (2005) 3.15
Spectral-domain optical coherence phase microscopy for quantitative phase-contrast imaging. Opt Lett (2005) 2.76
Confocal light absorption and scattering spectroscopic microscopy monitors organelles in live cells with no exogenous labels. Proc Natl Acad Sci U S A (2007) 2.56
Optical methodology for detecting histologically unapparent nanoscale consequences of genetic alterations in biological cells. Proc Natl Acad Sci U S A (2008) 2.33
Alterations of the extracellular matrix in ovarian cancer studied by Second Harmonic Generation imaging microscopy. BMC Cancer (2010) 2.09
Partial-wave microscopic spectroscopy detects subwavelength refractive index fluctuations: an application to cancer diagnosis. Opt Lett (2009) 2.04
Quantitative phase imaging of nanoscale cell structure and dynamics. Methods Cell Biol (2008) 1.97
Optical detection of buccal epithelial nanoarchitectural alterations in patients harboring lung cancer: implications for screening. Cancer Res (2010) 1.94
Nanoscale cellular changes in field carcinogenesis detected by partial wave spectroscopy. Cancer Res (2009) 1.91
Investigation of depth-resolved nanoscale structural changes in regulated cell proliferation and chromatin decondensation. Biomed Opt Express (2013) 1.56
Association between rectal optical signatures and colonic neoplasia: potential applications for screening. Cancer Res (2009) 1.53
Nanocytology of rectal colonocytes to assess risk of colon cancer based on field cancerization. Cancer Res (2012) 1.53
Interferometric spectroscopy of scattered light can quantify the statistics of subdiffractional refractive-index fluctuations. Phys Rev Lett (2013) 1.51
Imaging a full set of optical scattering properties of biological tissue by inverse spectroscopic optical coherence tomography. Opt Lett (2012) 1.38
Spatial-domain low-coherence quantitative phase microscopy for cancer diagnosis. Opt Lett (2010) 1.30
Nanoscale changes in chromatin organization represent the initial steps of tumorigenesis: a transmission electron microscopy study. BMC Cancer (2014) 1.29
Structural length-scale sensitivities of reflectance measurements in continuous random media under the Born approximation. Opt Lett (2012) 1.28
A fractal model for nuclear organization: current evidence and biological implications. Nucleic Acids Res (2012) 1.20
Mounting media for phase microscope specimens. Stain Technol (1949) 1.16
What structural length scales can be detected by the spectral variance of a microscope image? Opt Lett (2014) 1.09
Can OCT be sensitive to nanoscale structural alterations in biological tissue? Opt Express (2013) 1.00
Modeling Light Scattering in Tissue as Continuous Random Media Using a Versatile Refractive Index Correlation Function. IEEE J Sel Top Quantum Electron (2013) 0.99
Fractal nature of chromatin organization in interphase chicken erythrocyte nuclei: DNA structure exhibits biphasic fractal properties. FEBS Lett (2005) 0.99
Insights into the field carcinogenesis of ovarian cancer based on the nanocytology of endocervical and endometrial epithelial cells. Int J Cancer (2013) 0.97
Spectral encoding of spatial frequency approach for characterization of nanoscale structures. Appl Phys Lett (2012) 0.95
Nanocytological field carcinogenesis detection to mitigate overdiagnosis of prostate cancer: a proof of concept study. PLoS One (2015) 0.94
Nanoscale markers of esophageal field carcinogenesis: potential implications for esophageal cancer screening. Endoscopy (2013) 0.91
Quantitative phase microscopy with off-axis optical coherence tomography. Opt Lett (2014) 0.83
Subdiffusion reflectance spectroscopy to measure tissue ultrastructure and microvasculature: model and inverse algorithm. J Biomed Opt (2015) 0.82
Spectroscopic microscopy can quantify the statistics of subdiffractional refractive-index fluctuations in media with random rough surfaces. Opt Lett (2015) 0.81
Nanoscale refractive index fluctuations detected via sparse spectral microscopy. Biomed Opt Express (2016) 0.81
Early Prediction of Cancer Progression by Depth-Resolved Nanoscale Mapping of Nuclear Architecture from Unstained Tissue Specimens. Cancer Res (2015) 0.79
Novel approach for label free super-resolution imaging in far field. Sci Rep (2015) 0.79
Label-free imaging of the native, living cellular nanoarchitecture using partial-wave spectroscopic microscopy. Proc Natl Acad Sci U S A (2016) 0.78
Reconstruction of explicit structural properties at the nanoscale via spectroscopic microscopy. J Biomed Opt (2016) 0.77
Procedures for risk-stratification of lung cancer using buccal nanocytology. Biomed Opt Express (2016) 0.76
Surface profile measurement with a scanning differential ac interferometer. Appl Opt (1984) 0.76
The Global Relationship between Chromatin Physical Topology, Fractal Structure, and Gene Expression. Sci Rep (2017) 0.76