13 May 2019The application of a unified Monte Carlo model in the training of artificial neural networks for the purpose of real-time in-vivo sensing of tissue optical properties
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Current report consider development of a unified MC-based simulation platform for needs of Biomedical Optics and its practical use in the creation of novel Optical Diagnostics, Imaging and Sensing modalities aided by the Artificial Intelligence (AI) methods. It will be demonstrated how the developed MC platform can be utilized in the generation of validated lookup tables/labeled data sets and subsequent training of several configurations of Artificial Intelligence (AI) based methods for the purpose of real-time estimation of certain specific tissue properties of interest such as distributions of melanin, blood, oxygenation, etc. The prototypes of lightweight AI-empowered sensing solutions that could potentially be shrank onto a smartphone/wearable device form-factor will be presented and their performance will be compared with traditional spectroscopy-based methods using phantom and in vivo experimental data obtained during clinical studies.
Alexander Doronin andIgor Meglinski
"The application of a unified Monte Carlo model in the training of artificial neural networks for the purpose of real-time in-vivo sensing of tissue optical properties", Proc. SPIE 10982, Micro- and Nanotechnology Sensors, Systems, and Applications XI, 109820N (13 May 2019); https://doi.org/10.1117/12.2518566
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Alexander Doronin, Igor Meglinski, "The application of a unified Monte Carlo model in the training of artificial neural networks for the purpose of real-time in-vivo sensing of tissue optical properties," Proc. SPIE 10982, Micro- and Nanotechnology Sensors, Systems, and Applications XI, 109820N (13 May 2019); https://doi.org/10.1117/12.2518566