Biomechanical mapping of porcine dentin and branches with Brillouin confocal VIPA-based microscopy.

IF 1.7

Annals of anatomy = Anatomischer Anzeiger : official organ of the Anatomische Gesellschaft Pub Date : 2025-10-04 DOI:10.1016/j.aanat.2025.152743

Richard Younes, Frédéric Cuisinier, Benoit Rufflé, Rémy Vialla, Shahid Ali Shah, Pierre-Yves Collart-Dutilleul, Alban Desoutter

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Abstract

Objective: This study aimed to investigate the mechanical properties of porcine dentin using Brillouin confocal microscopy, focusing on its tubules and canaliculi. By mapping the Brillouin shift, we aimed to gain deeper insight into dentin biomechanics and assess how porcine dentin compares to human dentin as a model for dental research.

Design: Porcine molars were prepared by dehydration, precision cutting and polishing. A Brillouin microscope with a dual-VIPA configuration was used for spectral acquisition at 0.3 µm steps. Brillouin frequency shift, full width at half maximum (FWHM) and intensity were analyzed.

Results: Brillouin microscopy identified three distinct zones in porcine dentin: tubules, intertubular regions and branching areas, similar to human dentin. The Brillouin shifts ranged from 17 to 21.5 GHz, with an average around 19 GHz, lower than the 20-25 GHz typically found in human dentin. Mapping revealed branching tubules resembling tree trunks, with intricate branch-like structures in the intertubular regions. Peritubular areas exhibited higher frequency shifts, reaching around 21 GHz, distinguishing them from the more uniform intertubular zones. The dense branch networks surrounded by harder material provided insights into dentin's microstructure. However, challenges in refractive index and density measurements hindered direct conversion of frequency shifts to precise elastic longitudinal modulus values.

Conclusion: This study demonstrated that Brillouin VIPA-based microscopy can effectively map the mechanical properties of porcine dentin. The results show its potential for non-contact, high-resolution mechanical histology in biological tissues, offering promise for studying healthy and diseased mineralized tissues. Further optimization is needed to adapt the technique for human samples, considering differences in optical and mechanical properties.

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基于布里渊共聚焦vipa显微镜的猪牙本质和分支的生物力学制图。

目的：利用布里渊共聚焦显微镜研究猪牙本质的力学特性，重点观察其小管和小管。通过绘制布里渊位移，我们旨在更深入地了解牙本质生物力学，并评估猪牙本质与人类牙本质的比较，作为牙科研究的模型。设计：猪磨牙经脱水、精密切割、抛光加工而成。采用双vipa结构的布里渊显微镜在0.3µm步长处进行光谱采集。分析了布里渊频移、半峰全宽和强度。结果：布里渊显微镜在猪牙本质中发现了三个不同的区域：小管、管间区和分支区，与人类牙本质相似。布里渊频移的范围从17 ghz到21.5GHz，平均约为19GHz，低于人类牙本质中通常发现的20-25GHz。地图显示了类似树干的分枝小管，在管间区域具有复杂的枝状结构。管周区域表现出更高的频率偏移，达到21GHz左右，与更均匀的管间区域区分开来。被较硬材料包围的密集分支网络提供了对牙本质微观结构的深入了解。然而，折射率和密度测量方面的挑战阻碍了频移直接转换为精确的弹性纵向模量值。结论：基于布里渊vipa的显微技术可以有效地绘制猪牙本质的力学性质。结果表明，该方法具有在生物组织中进行非接触、高分辨率机械组织学研究的潜力，为研究健康和患病的矿化组织提供了希望。考虑到光学和机械性能的差异，需要进一步优化以适应人类样品的技术。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Annals of anatomy = Anatomischer Anzeiger : official organ of the Anatomische Gesellschaft

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