@inproceedings{21c403718307460ba17c312a6f929354,
title = "Photoacoustic correlation technique for low-speed flow measurement",
abstract = "A photoacoustic correlation spectroscopy (PACS) technique was proposed for the first time. This technique is inspired by its optical counterpart-the fluorescence correlation spectroscopy (FCS), which is widely used in the characterization of the dynamics of fluorescent species. The fluorescence intensity is measured in FCS while the acoustic signals are detected in PACS. To proof of concept, we demonstrated the flow measurement of light-absorbing beads probed by a pulsed laser. A PACS system with temporal resolution of 0.8 sec was built. Polymer microring resonators were used to detect the photoacoustic signals, which were then signal processed and used to obtain the autocorrelation curves. Flow speeds ranging from 249 to 15.1 μm/s with corresponding flow time from 4.42 to 72.5 sec were measured. The capability of low-speed flow measurement can potentially be used for detecting blood flow in relatively deep capillaries in biological tissues. Moreover, similar to FCS, PACS may have many potential applications in studying the dynamics of photoacoustic beads.",
keywords = "Blood flow, Flow measurement, Fluorescence correlation spectroscopy, Functional imaging, Imaging depth, Photoacoustic correlation spectroscopy, Photoacoustic imaging, Polymer microring resonators",
author = "Chen, \{Sung Liang\} and Tao Ling and Huang, \{Sheng Wen\} and Baac, \{Hyoung Won\} and Chang, \{Yu Chung\} and Guo, \{L. Jay\}",
year = "2010",
doi = "10.1117/12.840123",
language = "English",
isbn = "9780819479600",
series = "Progress in Biomedical Optics and Imaging - Proceedings of SPIE",
booktitle = "Photons Plus Ultrasound",
note = "Photons Plus Ultrasound: Imaging and Sensing 2010 ; Conference date: 24-01-2010 Through 26-01-2010",
}