Super-resolution photoacoustic microscopy finds clogged blood vessels
- Date:
- December 16, 2019
- Source:
- Pohang University of Science & Technology (POSTECH)
- Summary:
- 200 years ago, a doctor from France used a stethoscope for the first time and countless efforts to observe human body have been made since then. Up to now, the best tool that provides anatomical, functional, and molecular information of human and animal is the photoacoustic microscopy. Super-resolution localization photoacoustic microscopy which is 500 times faster than the conventional photoacoustic microscopy system has now been developed.
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200 years ago, a doctor from France used a stethoscope for the first time and countless efforts to observe human body have been made since then. Up to now, the best tool that provides anatomical, functional, and molecular information of human and animal is the photoacoustic microscopy. Super-resolution localization photoacoustic microscopy which is 500 times faster than the conventional photoacoustic microscopy system is developed by the research team from POSTECH in Korea.
Professor Chulhong Kim of Creative IT Engineering from POSTECH with Jinyoung Kim, a research professor and Jongbeom Kim, a PhD student presented a fast photoacoustic microscopy system with custom-made scanning mirror in the international journal published by Nature, Light: Science and Applications. This newly developed microscopy uses a stable and commercial galvanometer scanner with a custom-made scanning mirror and can find blocked or burst blood vessels by monitoring the flow of red blood cells without using a contrast absorber.
The photoacoustic microscopy images cells, blood vessels, and tissues by inducing vibrations when the optic energy is converted to heat after an object absorbs light from the laser beam fired. The conventional photoacoustic microscopy systems using a galvanometer scanner have a narrow field of view because they do not scan photoacoustic waves but only the optical beam. The conventional photoacoustic microscopy systems using a linear motorized stage also have temporal limitation in making images.
The research team developed a new photoacoustic microscopy system with improved performances. It can scan both photoacoustic waves and optical beams simultaneously as they implemented the custom-made scanning mirror in the existing photoacoustic microscopy system. Also, it can monitor very small vessels using intrinsic red blood cells without a contrast absorber which helps the system to image blood vessels well. Furthermore, the new system is 500 times faster than that of the conventional ones. With this improvement, it can demonstrate super-resolution image by localizing photoacoustic signals and the spatial resolution is enhanced by 2.5 times.
Their research accomplishment is meaningful in many ways. Especially, this system is expected to be very promising in diagnosis and treatment of stroke and cardiovascular disease. Because it can monitor and image the blood vessels with the flow of blood cells in real time, it can also be used in vascular disease which needs urgent diagnosis and treatment. Moreover, it allows direct monitoring of hemodynamics in the microvessels. It is anticipated to be applied in various fields including hemodynamic response, contrast agent dynamics in blood vessels and transient microcirculatory abnormalities.
Professor Chulhong Kim said, "We successfully imaged microvessels in the ears, eyes, and brains of mice and a human fingertip with this new photoacoustic microscopy system. What we have developed can be a complimentary tool to the conventional brain imaging system and it can also be a promising tool for future preclinical and clinical studies."
Story Source:
Materials provided by Pohang University of Science & Technology (POSTECH). Note: Content may be edited for style and length.
Journal Reference:
- Jongbeom Kim, Jin Young Kim, Seungwan Jeon, Jin Woo BAIK, Seong Hee Cho, Chulhong Kim. Super-resolution localization photoacoustic microscopy using intrinsic red blood cells as contrast absorbers. Light: Science & Applications, 2019; 8 (1) DOI: 10.1038/s41377-019-0220-4
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