Abstract
We present a live-to-cryo correlative imaging workflow for multiscale structural and chemical analysis of biological tissues in their near-native state. The method integrates live super-resolution fluorescence microscopy, live and cryogenic Raman spectroscopy, and targeted cryogenic focused ion beam/scanning electron microscopy, transmission electron microscopy, electron tomography, energy dispersive X-ray spectroscopy, and electron diffraction. This approach enables precise 3D targeting and nanoscale imaging of selected regions across four orders of magnitude in spatial resolution, while preserving ultrastructure and chemical composition. Using regenerating zebrafish scales as a benchmark, we visualize collagen fibril orientation, local matrix density, and mineral composition within the extracellular matrix. We identify a plywood-like architecture of unmineralized collagen with orientation-independent density variation, and reveal curved, acidic phosphate-rich mineral platelets aligned with collagen fibrils. This workflow establishes a generalizable strategy for comprehensive 3D correlative analysis of hybrid tissues, and opens new opportunities for studying native structure–function relationships at the interface of biology and materials science.
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Abstract
We present a live-to-cryo correlative imaging workflow for multiscale structural and chemical analysis of biological tissues in their near-native state. The method integrates live super-resolution fluorescence microscopy, live and cryogenic Raman spectroscopy, and targeted cryogenic focused ion beam/scanning electron microscopy, transmission electron microscopy, electron tomography, energy dispersive X-ray spectroscopy, and electron diffraction. This approach enables precise 3D targeting and nanoscale imaging of selected regions across four orders of magnitude in spatial resolution, while preserving ultrastructure and chemical composition. Using regenerating zebrafish scales as a benchmark, we visualize collagen fibril orientation, local matrix density, and mineral composition within the extracellular matrix. We identify a plywood-like architecture of unmineralized collagen with orientation-independent density variation, and reveal curved, acidic phosphate-rich mineral platelets aligned with collagen fibrils. This workflow establishes a generalizable strategy for comprehensive 3D correlative analysis of hybrid tissues, and opens new opportunities for studying native structure–function relationships at the interface of biology and materials science.
Competing Interest Statement
The authors have declared no competing interest.
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