AI Article Synopsis
- Birefringence is a key property of certain materials, allowing for advanced imaging techniques like polarized light microscopy, which traditionally requires complex setups.
- A new lens-less microscopy method has been developed that captures complex and birefringence images without optical lenses or moving parts, using an optical mask and LED light.
- This innovative technique has demonstrated impressive resolution and a wide field of view, successfully imaging various anisotropic samples, including biological tissues and crystals.
Article Abstract
Birefringence, an inherent characteristic of optically anisotropic materials, is widely utilized in various imaging applications ranging from material characterizations to clinical diagnosis. Polarized light microscopy enables high-resolution, high-contrast imaging of optically anisotropic specimens, but it is associated with mechanical rotations of polarizer/analyzer and relatively complex optical designs. Here, we present a form of lens-less polarization-sensitive microscopy capable of complex and birefringence imaging of transparent objects without an optical lens and any moving parts. Our method exploits an optical mask-modulated polarization image sensor and single-input-state LED illumination design to obtain complex and birefringence images of the object via ptychographic phase retrieval. Using a camera with a pixel size of 3.45 μm, the method achieves birefringence imaging with a half-pitch resolution of 2.46 μm over a 59.74 mm field-of-view, which corresponds to a space-bandwidth product of 9.9 megapixels. We demonstrate the high-resolution, large-area, phase and birefringence imaging capability of our method by presenting the phase and birefringence images of various anisotropic objects, including a monosodium urate crystal, and excised mouse eye and heart tissues.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10630341 | PMC |
| http://dx.doi.org/10.1038/s41598-023-46496-z | DOI Listing |
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