Author Affiliations
Abstract
Key Laboratory of Optoelectronic Devices, and Systems of Ministry of Education and Guangdong Province, College of Physics and Optoelectronic Engineering, Shenzhen University, Shenzhen 518060 P. R. China
Measurement of blood flow velocity is key to understanding physiology and pathology in vivo. While most measurements are performed at the middle of the blood vessel, little research has been done on characterizing the instantaneous blood flow velocity distribution. This is mainly due to the lack of measurement technology with high spatial and temporal resolution. Here, we tackle this problem with our recently developed dual-wavelength line-scan third-harmonic generation (THG) imaging technology. Simultaneous acquisition of dual-wavelength THG line-scanning signals enables measurement of blood flow velocities at two radially symmetric positions in both venules and arterioles in mouse brain in vivo. Our results clearly show that the instantaneous blood flow velocity is not symmetric under general conditions.
1700nm-Window third-harmonic generation imaging blood flow velocity Journal of Innovative Optical Health Sciences
2024, 17(1): 2350011
1 杭州电子科技大学 电子信息学院, 杭州 310018
2 杭州电子科技大学 浙江省装备电子研究重点实验室, 杭州 310018
基于光学多普勒效应的无创血流测量技术具有实时性、无需介质、非侵入式等性质, 在临床医疗等领域存在着极大价值与应用前景。目前光学无创血流测量技术主要有激光多普勒血流测量技术、光学相干层析多普勒成像技术和光声多普勒血流测量技术。对这3种技术进行了原理分析, 简述了其研究现状, 并对这些新型技术的未来和发展进行了展望。
医用光学 生物技术 激光多普勒 相干层析多普勒 光声多普勒 无创血流测量 血流速率 medical optics biotechnology laser Doppler coherence tomography Doppler photo-acoustic Doppler non-invasive blood flow measurement blood flow velocity
1 天津工业大学生命科学学院,天津 300387
2 天津市光电检测技术与系统重点实验室,天津 300387
3 天津工业大学电子与信息工程学院,天津 300387
将扩散干涉光谱(iDWS)技术与光外差检测方法和扩散散斑衬比分析方法相结合,提出了一种扩散相干散斑成像检测方法,并搭建了实验系统。该系统能有效地提高无创检测局部脑血流量(rCBF)的信噪比和检测精度,仿体流速实验结果表明,其相对血流指数与实际流速具有较好的线性度,在源-探距离为6~12 mm范围内线性相关系数均值为0.9881±0.0005。该检测方法可以区分不同目标区域的流速变化,管径为4.8 mm时相对误差为2.04%,结合血管管径测量方法可实现流速和流量的有效监测。通过在体实验和袖带加压实验,证明系统可以检测到活体rCBF的流速信息,且在有效测量流速范围内有较好的检测准确度。
医用光学 散斑光谱学 无创局部脑血流检测 扩散干涉光谱 光外差检测 扩散相干散斑衬比分析
1 新疆医科大学 公共卫生学院,乌鲁木齐 830011
2 新疆医科大学 医学工程技术学院,乌鲁木齐 830011
激光散斑对比成像(LSCI)是一种以宽视场方式监测血流速度的非扫描光学成像技术。LSCI技术具有高时间-空间分辨率、快速实时成像、非接触式、仪器结构简单、无需造影剂等优势。本文简要介绍了LSCI的基本原理,概述了反射式LSCI和透射式LSCI两种结构,综述了LSCI在皮肤血流、大脑皮层和视网膜血流等生物医学应用中的最新研究进展,并对其发展前景做了进一步展望,为血流监测提供理论依据和实践指导。
激光散斑对比成像 组织灌注 血流速度 血流监测 血流微循环 laser speckle contrast imaging tissue perfusion blood flow velocity blood flow monitoring blood microcirculation
1 华侨大学生物医学学院,福建 泉州 362021
2 华侨大学工学院,福建 泉州 362021
激光散斑衬比血流成像(LSCI)是一种利用激光散斑强度的时空统计特性来实现活体组织血流监测的全场光学成像技术,在临床诊断和生命科学等研究领域具有重要的应用价值。本文在介绍LSCI基本原理的基础上,重点对高信噪比LSCI、高分辨率LSCI、高精度LSCI、大成像深度LSCI和新型LSCI系统等关键技术及其应用的研究进展进行综述。首先,综述了各向异性滤波、特征值分解和变换域滤波的高信噪比LSCI技术,并总结了以运动伪影校正、失焦模糊校正和非均匀光强校正为目标的高分辨率LSCI技术的研究现状;然后,以实现高精度LSCI为目标,从静态散射光校正、定量LSCI技术和新型散斑衬比成像算法等方面阐述了高精度LSCI技术的研究进展;最后,总结大成像深度LSCI技术的发展现状与进展,介绍新型LSCI系统及其应用的最新研究成果,并对LSCI技术未来的发展方向和应用功能拓展进行总结和展望。
医用光学 生物医学光学成像 激光散斑成像 血流成像 关键技术 应用进展
1 中国科学院苏州生物医学工程技术研究所, 江苏 苏州 215163
2 上海大学机电工程与自动化学院, 上海 200444
3 中国科学技术大学生物医学工程学院, 安徽 合肥 230026
激光散斑衬比成像(LSCI)技术广泛应用于大视场的组织表层血流成像,当需要实时在体监测生物体深层组织或腔内组织的血流分布及变化时,将LSCI与内镜成像技术结合是解决LSCI成像深度问题的有效途径。为此,搭建了商用腹腔镜LSCI成像系统,并对微流体仿体和兔子大肠进行成像。实验结果表明,所搭建的系统可以校正静态散射以及消除系统噪声对散斑衬比度的影响,利用单次曝光下的散斑衬比测量值可以实现血流的定量监测,该商用腹腔镜LSCI成像系统将具有重要的临床应用潜力。
医用光学 散斑衬比 血流监测 内窥成像 静态散射
1 北京工业大学信息学部,北京 100124
2 先进信息网络北京实验室,北京 100124
3 北京工业大学计算智能与智能系统北京市重点实验室,北京 100124
扩散相关光谱(DCS)技术是一种新兴的组织血流无创检测技术。该技术将近红外光照射到组织表面,通过计算组织表面散射光斑的光强自相关函数推算组织中红细胞的运动状态,以实现组织血流变化的定量检测。相比于其他血流检测技术,如激光多普勒(LDF)、核磁共振成像(MRI)、正电子发射断层成像技术(PET)等,该技术具有无创、无辐射、可长时间连续实时检测、适用范围广、检测要求低等优势,适宜床边监测。分别从DCS技术的基本原理、系统与方法、临床应用等方面对其进行简要综述,并对DCS技术的未来发展趋势进行展望。
激光与光电子学进展
2022, 59(6): 0617006
Author Affiliations
Abstract
1 Saratov State University, Saratov, Russia
2 Laboratories of Biophotonics and Laser Molecular, Imaging and Machine Learning, National Research Tomsk State University, Tomsk, Russia
3 Saratov State Medical University, Saratov, Russia
4 Institute of Precision Mechanics and Control, Russian Academy of Sciences, Russia
5 A.N. Bach Institute of Biochemistry, Research Center of Biotechnology of the Russian Academy of Sciences, Moscow, Russia
The influence of ischemia–reperfusion (I/R) action on pancreatic blood flow (PBF) and the development of acute pancreatitis (AP) in laboratory rats is evaluated in vivo by using the laser speckle contrast imaging (LSCI). Additionally, the optical properties in norm and under condition of AP in rats were assessed using a modified integrating sphere spectrometer and inverse Monte Carlo (IMC) software. The results of the experimental study of microcirculation of the pancreas in 82 rats in the ischemic model are presented. The data obtained confirm the fact that local ischemia and changes in the blood flow velocity of the main vessels cause and provoke acute pancreatitis.
Laser speckles contrast of speckle images adaptive algorithm microcirculation blood flow acute pancreatitis pancreas rats optical properties integrating sphere spectroscopy. Journal of Innovative Optical Health Sciences
2022, 15(1): 2242002
Author Affiliations
Abstract
1 Department of Biomedical Science & Engineering, Institute of Integrated Technology, Gwangju Institute of Science and Technology (GIST), Gwangju 61005, Republic of Korea
2 Center for Bionics, Biomedical Research Institute, Korea Institute of Science and Technology (KIST), Seoul 02792, Republic of Korea
Laser speckle imaging is a common technique to monitor blood flow. The fluctuations in speckle intensity can be related to the blood flow by calculating the speckle contrast, the ratio between the standard deviation of speckle fluctuations and the average intensity. However, this simple statistic calculation is easily affected by motion artifacts. In this study, we applied sample entropy analysis instead of calculating standard deviations of the speckle fluctuations. Similar to the traditional method, sample entropy-based speckle contrast increases linearly with flow rate but was shown to be more immune to sudden movements during an upper arm occlusion test.
laser speckle imaging sample entropy speckle contrast blood flow monitoring motion artifact Chinese Optics Letters
2022, 20(1): 011702
