Abstract

Scanning Electron Microscope/Focused Ion Beam (SEM/FIB) system has become valuable and popular tool for the analysis of biological materials such as dentine structures. According to physiological and anatomical studies, dentine structures are a complicated system containing collagen fibers, nanocrystalline hydroxyapatite, and numerous networks of tubular pores. During a routine FIB milling process, collagen fibers and other organic structures are vaporized, which increases the number of pores on the milled surface of the dentine. This causes the final cross-section to be more porous than the pristine sample. Unfortunately, little attention has been paid to the collagen fiber loss and how to preserve them during a FIB milling process. In this work, we present a novel and simple approach to preserve the organic portions of the dentine structure through metal staining. By using this method, the porosity of the dentine structure after the FIB milling process is significantly reduced similar to the pristine sample. This indicates that the organic portion of the dentine structure is well protected by the metal staining. This approach enables the SEM/FIB system to generate super-high quality SEM images with less ion beam damage; and the SEM images can better reflect the original condition of the dentine structure. Further, serial energy-dispersive X-ray spectroscopy (EDS) mapping of the stained dentine structure is achieved without an additional metal coating; and three-dimensional (3-D) elemental mapping of an occluded dentine is achieved with a significantly reduced data acquisition time.

Highlights

  • Dentine, a complicated system containing macro, micro, and nano-features, is a part of the tooth which plays a critical role in responding to hypersensitivity, the mechanical strength of the tooth, and overall oral h­ ygiene[1,2,3]

  • Even though dentine structures have been widely studied by electron microscopy, to the best of our knowledge, there has been no report focusing on the damages to the organic portions of the dentine caused by the FIB, especially on collagen fiber loss, and how to stabilize the dentine structures during the milling process

  • After staining the occluded dentine structure using R­ uO4, energy-dispersive X-ray spectroscopy (EDS) mapping was performed without any additional metal coating; and elemental maps of serial slices were obtained without coating each slice, significantly simplifying the EDS mapping acquisition process and the total acquisition time

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Summary

Introduction

A complicated system containing macro, micro, and nano-features, is a part of the tooth which plays a critical role in responding to hypersensitivity, the mechanical strength of the tooth, and overall oral h­ ygiene[1,2,3]. When analyzing dentine structures using a FIB, either for structural analysis or a thin lamellar preparation for high-resolution TEM analysis, the high energy ion beam can cause severe damages to the organic portions and etch away collagen fibers, leaving holes and/or small channels in the dentine. Even though dentine structures have been widely studied by electron microscopy, to the best of our knowledge, there has been no report focusing on the damages to the organic portions of the dentine caused by the FIB, especially on collagen fiber loss, and how to stabilize the dentine structures during the milling process. By staining the dentine structure in R­ uO4 vapor, the collagen fibers were well preserved during the FIB milling process, and the number of pores generated by the damage from the ion beam was significantly reduced. After staining the occluded dentine structure using R­ uO4, energy-dispersive X-ray spectroscopy (EDS) mapping was performed without any additional metal coating; and elemental maps of serial slices were obtained without coating each slice, significantly simplifying the EDS mapping acquisition process and the total acquisition time

Methods
Results
Conclusion

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