Spatial Frequency Domain Imaging (SFDI) is a powerful technique for non-contact tissue optical property and chromophore mapping over a large field of view. However, a major challenge that limits the clinical adoption of SFDI is that it requires carefully-controlled imaging geometry and the projection of known spatial frequencies. We present speckle-illumination SFDI (si-SFDI), a projector-free technique that measures tissue optical properties from structured illumination formed by randomized speckle patterns. We compute the local power spectral density of images under speckle illumination, from which a high-frequency and a low-frequency tissueresponse parameter can be characterized for each pixel. A lookup table generated by Monte-Carlo simulations is subsequently used to accurately determine optical absorption and reduced scattering coefficients. Compared to conventional SFDI, si-SFDI may be particularly useful for endoscopic applications due to its utilization of simple coherent illumination, which makes it more easily incorporated into existing endoscopic systems. Moreover, speckle illumination offers a large depth of focus compared to projector-based illumination. In this study, we explore wide-field optical property mapping with an endoscope camera and fiber-coupled laser speckle illumination. We apply this technique to tissue-mimicking silicone phantoms and biological tissues. The accuracy of si-SFDI is evaluated by comparing to optical properties measured by conventional SFDI. Future work could accelerate si-SFDI reconstruction by using parallel computing or machine learning algorithms.
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