Hokkaido University, Graduate School of Information Science and Technology, Division of Bioengineering and Bioinformatics, Sapporo, Hokkaido, Japan.
Fukuoka Institute of Technology, Information and Systems Engineering, Graduate School of Engineering, Fukuoka, Japan.
J Biomed Opt. 2017 Jun 1;22(6):67001. doi: 10.1117/1.JBO.22.6.067001.
The aim of this study was to discover a simple/convenient geometrical arrangement of radiation sources and detector to acquire finger-photoplethysmograms (PPGs) with wavelength regions of blood glucose (BGL) absorption, toward practical noninvasive BGL measurement. First, we compared PPGs with three wavelengths: 808 nm (without water absorption), 1160 nm (with weak water absorption), and 1600 nm (with nearly peak BGL absorption and strong water absorption), while the source-detector spacing was successively increased circumferentially around a fingertip. In 10 healthy subjects, we observed clear cardiac-related pulsatile components of PPG signals at 808 and 1160 nm in any incident positions with more than 15 dB of signal-to-noise ratio ( S / N ), but reliable PPG detections at 1600 nm with more than 10 dB of S / N was only possible when the source-detector distance was less than 3 mm around the fingertip circumference. Second, with this arrangement, an experiment was performed using six wavelengths to cover glucose absorption bands (from 1550 to 1749 nm), obtaining pulsatile PPG signals with more or less 15 dB of S / N . Through the present experiments, this orthogonal arrangement of the source and detector to detect forward- and side-scattered radiation through the tissue is appropriate for PPG measurements with wavelength regions where there is potential for BGL measurement.
本研究旨在寻找一种简单/便捷的辐射源和探测器的几何排列方式,以获取具有血糖(BGL)吸收波长的指端光体积描记图(PPG),从而实现实用的非侵入性 BGL 测量。首先,我们比较了三种波长的 PPG:808nm(无水分吸收)、1160nm(弱水分吸收)和 1600nm(近乎峰值 BGL 吸收且强水分吸收),同时逐步增加源-探测器在指尖周围的圆周间隔。在 10 位健康受试者中,我们观察到在任何入射位置,808nm 和 1160nm 的 PPG 信号都有明显的与心脏相关的脉动成分,其信噪比(S/N)超过 15dB,但在 1600nm 时,只有当源-探测器距离小于指尖圆周 3mm 时,才能获得超过 10dB 的 S/N 的可靠 PPG 检测。其次,使用这种排列方式,我们在六个波长下进行了实验,覆盖了葡萄糖吸收带(1550nm 至 1749nm),获得了具有或多或少 15dB 的 S/N 的脉动 PPG 信号。通过本实验,这种源和探测器的正交排列方式适合用于检测组织中前向和侧向散射辐射的 PPG 测量,这些波长区域具有进行 BGL 测量的潜力。
