1 July 2004 Physical basis of holographic optical coherence imaging of living tissue
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Abstract
This paper reviews the physical basis of holographic optical coherence imaging (OCI) applied in image-domain holography (IDH) and Fourier-domain holography (FDH). Holographic OCI is a multi-spatial-channel direct imaging approach that is closely related to short-coherence speckle interferometry and speckle holography, drawing in addition from laser-ranging concepts and techniques of optical coherence tomography (OCT). It produces a series of en face images at successive depths that can be presented in a so-called video "fly-through". Interchannel cross-talk is described as multichannel spatial heterodyne that produces image-bearing speckle. The speckle holograms are proposed to relate to specific structure in the tissue and may be useful as a clinical diagnostic. For instance, sub-cellular motility (a metric of the vitality of a cell and a means to quantify the response to inter-cellular signaling) can be detected with wide field of view without the need for cellular-scale optical resolution. This can be applied across biologically significant areas of tissue with potential for intraoperative applications to asses the state of health beneath the surface of broad areas of excised tissue.
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David D. Nolte, Kwan Jeong, Ping Yu, John J. Turek, "Physical basis of holographic optical coherence imaging of living tissue", Proc. SPIE 5316, Coherence Domain Optical Methods and Optical Coherence Tomography in Biomedicine VIII, (1 July 2004); doi: 10.1117/12.529299; https://doi.org/10.1117/12.529299
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