Publications

Schlichenmeyer, T. C., Wang, M., Elfer, K. N. & Brown, Q. Video-rate structured illumination microscopy for high-throughput imaging of large tissue areas. Biomedical optics express 5, 366–377 (2014).

Goel, U. O. et al. Feasibility of quantitative diffuse reflectance spectroscopy for targeted measurement of renal ischemia during laparoscopic partial nephrectomy. Journal of biomedical optics 19, 107001–107001 (2014).

Lo, J. Y. et al. Wavelength optimization for quantitative spectral imaging of breast tumor margins. PLoS One 8, e61767 (2013).

Mueller, J. L. et al. Quantitative segmentation of fluorescence microscopy images of heterogeneous tissue: application to the detection of residual disease in tumor margins. PloS one 8, e66198 (2013).

Brown, Q. et al. Optical spectral surveillance of breast tissue landscapes for detection of residual disease in breast tumor margins. PloS one 8, e69906 (2013).

Fu, H. L. et al. Optimization of a widefield structured illumination microscope for non-destructive assessment and quantification of nuclear features in tumor margins of a primary mouse model of sarcoma. PloS one 8, e68868 (2013).

K, V., GM, P., JQ, B. & N, R. Non-invasive and quantitative sensing of tumor physiology and function via steady-state diffuse optical spectroscopy,” in Biosensors and Molecular Technologies for Cancer Diagnostics. in (CRC Press, 2012).

JQ, B., K, V., , GM, P. & N, R. Clinical applications of UV-VIS spectroscopy in head and neck, cervical, and breast cancers,” in In Vivo Clinical Imaging and Diagnosis. in (McGraw-Hill, 2011).

Millon, S. R. et al. Uptake of 2-NBDG as a method to monitor therapy response in breast cancer cell lines. Breast cancer research and treatment 126, 55–62 (2011).

Millon, S. R. et al. Preferential accumulation of 5-aminolevulinic acid-induced protoporphyrin IX in breast cancer: a comprehensive study on six breast cell lines with varying phenotypes. Journal of biomedical optics 15, 018002–018002 (2010).