Welge, W. A., DeMarco, A. T., Watson, J. M., Rice, P. S., Barton, J. K., & Kupinski, M. A. (2014). Objective assessment of multimodality optical coherence tomography and second-harmonic generation image quality of ex vivo mouse ovaries using human observers. DESIGN AND QUALITY FOR BIOMEDICAL TECHNOLOGIES VII, 8936.
Luo, Y., de, L. E., Castro, J., Lee, J., Barton, J. K., Kostuk, R. K., & Barbastathis, G. (2011). Phase-contrast volume holographic imaging system. OPTICS LETTERS, 36(7), 1290-1292.
Lee, M., Nammalvar, V., Gobin, A., Barton, J., West, J., & Drezek, R. (2006). Nanoshells as contrast agents for scatter-based optical imaging. 2006 3RD IEEE INTERNATIONAL SYMPOSIUM ON BIOMEDICAL IMAGING: MACRO TO NANO, VOLS 1-3, 371-+.
Wall, R. A., Bonnema, G. T., & Barton, J. K. (2010). Focused OCT and LIF Endoscope. ENDOSCOPIC MICROSCOPY V, 7558.
Castro, J. M., de Leon, E., Barton, J. K., & Kostuk, R. K. (2011). Analysis of diffracted image patterns from volume holographic imaging systems and applications to image processing. Applied optics, 50(2), 170-6.
Diffracted image patterns from volume holograms that are used in volume holographic imaging systems (VHISs) are investigated. It is shown that, in VHISs, prior information about the shape and spectral properties of the diffracted patterns is important not only to determine the curvature and field of view of the image, but also for image registration and noise removal. A new methodology to study numerically and analytically the dependence of VHIS diffraction patterns with the hologram construction parameters and the readout wavelength is described. Modeling and experimental results demonstrate that, in most cases, VHIS diffracted shapes can be accurately represented by hyperbolas.