Korea University: Optical Microscope Capable Of High-Resolution 3D Imaging At Ultra-High Speeds Developed
Korea University: Optical Microscope Capable Of High-Resolution 3D Imaging At Ultra-High Speeds Developed
The research
team led by prof. Choi Won-shik (vice-director of the Center for Molecular
Spectroscopy and Dynamics at the Institute for Basic Science) developed an
optical microscope technology that significantly reduces the number of
measurements needed for ultra-high speed imaging, and succeeded in
reconstructing high-resolution 3D images of the thin neural network structure
in a mouse brain.
In general, high-resolution imaging of deep layers in biological tissues has
proven challenging due to the noise induced by the strong scattering and
extremely complex optical aberrations. Although recently many studies have
attempted to address such issues, extensive measurements have been needed to
obtain high-resolution images, and the process has also been highly
time-consuming. Consequently, such approaches were considered impractical for
3D imaging, which involves imaging at various depths.
To determine the optical characteristics of a linear medium, such as biological
tissue, electric field measurements are obtained by exposing the medium to
light at various points or angles. The matrix that stores the relative
positions or angles of incident and scattered light is known as the reflection
or transmission matrix depending on the system structure, and measuring this
matrix gives the most information on interactions between light and the medium.
The Center for Molecular Spectroscopy and Dynamics applied a novel algorithm to
the reflection matrix, and obtained high-resolution images of biological
tissues by reducing scattering noise and correcting for optical aberrations.
The process of measuring the reflection matrix is conventionally relatively
time-consuming as measurements have to be obtained for multiple images using
each incident wave corresponding to the diffraction limit,. This has made the
approach less practical for biodynamics and 3D imaging.
The microscopic imaging technology developed by the research team significantly
improves the speed of reflection matrix measurement. A reflection matrix was
obtained through sparse sampling with random patterns instead of point or
parallel beam illumination, and the complex optical aberrations were corrected
through a time-reversal matrix. As a result, the team succeeded in obtaining
high-resolution images using only 2% of the number of measurement images used
in conventional imaging.
Based on the above, the team achieved ultra-high-speed visualization of
myelinated axons in a mouse brain. A diffuser was used to produce random
speckle illumination patterns, and scattering images were retrieved by shifting
the brain tissues for each depth section. While the conventional reflection
matrix imaging method takes several hours to measure images for the entire
volume (128×128×125 μm3), the team’s technique significantly reduced the number
of measurement images, taking only 3.58 seconds for the same volume. Moreover,
the resulting high-resolution images had a lateral resolution of 0.45μm and an
axial resolution of 2μm.
Prof. Yoon Seok-chan and IBS researcher Lee Ho-jun said, “Using random pattern
illuminations and a time-reversal matrix, we managed to obtain high-resolution
images while significantly reducing the number of measurements. We expect to
see more related developments in ultra-high speed 3D imaging and neuroscience
research.” Prof. Choi Won-shik, the corresponding author of this study, said,
“We plan to further develop reflection matrix imaging methods to broaden the
scope of the applications in healthcare and medicine.”
The team is preparing to miniaturize microscopes for real-world medical
settings, and to apply their technique to the real-time early diagnosis of
illnesses.