Abstract
Bioimaging devices use the optical properties of hemoglobin (Hb) have become widespread in medical care. The aim of the present study was to develop a device that noninvasively and quantitatively images the Hb amount and oxygen saturation of tissues remotely and in real time, in addition to providing color imaging and to examine its applicability. While detecting the RGB color, the reflected light of two narrow bands (671 ± 10 and 830 ± 10 nm) was detected simultaneously and used as a correlated value of Hb oxygen saturation. The sum of the reflected luminance at 671 and 830 nm was set as the value correlated with the tissue Hb amount. Therefore, by quantitatively imaging the tissue Hb oxygen saturation and Hb amount associated with the status of tissue oxygen metabolism, it is possible to noninvasively determine in real time not only the status of the blood flow but also the presence and condition of tumors and the degree and the process of inflammation, which can be used for the surgical navigation.
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Haruta, Y., Tsutsumi, R., Naotaka, K., Nagahara, H., Ikeda, T. (2021). Novel Multispectral Device for Quantitative Imaging of Tissue Oxygen Saturation and Hemoglobin as Surgical Navigation Device. In: Takenoshita, S., Yasuhara, H. (eds) Surgery and Operating Room Innovation. Springer, Singapore. https://doi.org/10.1007/978-981-15-8979-9_10
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