Advanced Time-Stepping Interpretation of Fly-Scan Continuous Rotation Synchrotron Tomography of Dental Enamel Demineralization

Cyril Besnard; Ali Marie; Sisini Sasidharan; Shashidhara Marathe; Kaz Wanelik; Robert Harper; Christoph Rau; Richard Shelton; Gabriel Landini; Alexander M. Korsunsky

doi:10.1021/cbmi.3c00121

Advanced Time-Stepping Interpretation of Fly-Scan Continuous Rotation Synchrotron Tomography of Dental Enamel Demineralization

Cyril Besnard, Ali Marie, Sisini Sasidharan, Shashidhara Marathe, Kaz Wanelik, Robert Harper, Christoph Rau, Richard Shelton, Gabriel Landini, Alexander M. Korsunsky^*

^*Corresponding author for this work

Dentistry

Research output: Contribution to journal › Article › peer-review

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Abstract

High-resolution spatial and temporal analysis and 3D visualization of time-dependent processes, such as human dental enamel acid demineralization, often present a challenging task. Overcoming this challenge often requires the development of special methods. Dental caries remains one of the most important oral diseases that involves the demineralization of hard dental tissues as a consequence of acid production by oral bacteria. Enamel has a hierarchically organized architecture that extends down to the nanostructural level and requires high resolution to study its evolution in detail. Enamel demineralization is a dynamic process that is best investigated with the help of in situ experiments. In previous studies, synchrotron tomography was applied to study the 3D enamel structure at certain time points (time-lapse tomography). Here, another distinct approach to time-evolving tomography studies is presented, whereby the sample image is reconstructed as it undergoes continuous rotation over a virtually unlimited angular range. The resulting (single) data set contains the data for multiple (potentially overlapping) intermediate tomograms that can be extracted and analyzed as desired using time-stepping selection of data subsets from the continuous fly-scan recording. One of the advantages of this approach is that it reduces the amount of time required to collect an equivalent number of single tomograms. Another advantage is that the nominal time step between successive reconstructions can be significantly reduced. We applied this approach to the study of acidic enamel demineralization and observed the progression of demineralization over time steps significantly smaller than the total acquisition time of a single tomogram, with a voxel size smaller than 0.5 μm. It is expected that the approach presented in this paper can be useful for high-resolution studies of other dynamic processes and for assessing small structural modifications in evolving hierarchical materials.

Original language	English
Journal	Chemical & Biomedical Imaging
Early online date	8 Feb 2024
DOIs	https://doi.org/10.1021/cbmi.3c00121
Publication status	E-pub ahead of print - 8 Feb 2024

Bibliographical note

Acknowledgments:
This work was done as part of “Tackling human dental caries by multi-modal correlative microscopy and multi-physics modelling” (EP/P005381/1) and “Rich Nonlinear Tomography for advanced materials” (EP/V007785/1), with both projects funded by The Engineering and Physical Sciences Research Council (EPSRC). S.S. and A.M. express their gratitude for the support of the Health Research Bridging Salary Scheme (BRR00060-DF02 and BRR00060-DF03, respectively) by the Medical Science Divisions, University of Oxford. Synchrotron tomography data were collected on I13-2 beamline in Diamond Light Source (Diamond Light Source Ltd., Didcot, Oxfordshire, OX11 0DE, U.K.) under the proposal mg29256-1 and additional data beamtime facilitated by Dr. Andrew Bodey of Diamond Light Source. The authors wish to thank Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for the support in preparing the dental sample. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.

Keywords

Human carious enamel
Synchrotron
X-ray tomography
In situ demineralization
Microscopy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1021/cbmi.3c00121Licence: Creative Commons: Attribution (CC BY)

BesnardC2024AdvancedFinal published version, 11.1 MBLicence: Creative Commons: Attribution (CC BY)

Tackling human dental caries by multi-modal correlative microscopy and multi-physics modelling
Landini, G. & Shelton, R.
Engineering & Physical Science Research Council
1/01/17 → 30/09/21
Project: Research Councils

Cite this

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title = "Advanced Time-Stepping Interpretation of Fly-Scan Continuous Rotation Synchrotron Tomography of Dental Enamel Demineralization",

abstract = "High-resolution spatial and temporal analysis and 3D visualization of time-dependent processes, such as human dental enamel acid demineralization, often present a challenging task. Overcoming this challenge often requires the development of special methods. Dental caries remains one of the most important oral diseases that involves the demineralization of hard dental tissues as a consequence of acid production by oral bacteria. Enamel has a hierarchically organized architecture that extends down to the nanostructural level and requires high resolution to study its evolution in detail. Enamel demineralization is a dynamic process that is best investigated with the help of in situ experiments. In previous studies, synchrotron tomography was applied to study the 3D enamel structure at certain time points (time-lapse tomography). Here, another distinct approach to time-evolving tomography studies is presented, whereby the sample image is reconstructed as it undergoes continuous rotation over a virtually unlimited angular range. The resulting (single) data set contains the data for multiple (potentially overlapping) intermediate tomograms that can be extracted and analyzed as desired using time-stepping selection of data subsets from the continuous fly-scan recording. One of the advantages of this approach is that it reduces the amount of time required to collect an equivalent number of single tomograms. Another advantage is that the nominal time step between successive reconstructions can be significantly reduced. We applied this approach to the study of acidic enamel demineralization and observed the progression of demineralization over time steps significantly smaller than the total acquisition time of a single tomogram, with a voxel size smaller than 0.5 μm. It is expected that the approach presented in this paper can be useful for high-resolution studies of other dynamic processes and for assessing small structural modifications in evolving hierarchical materials.",

keywords = "Human carious enamel, Synchrotron, X-ray tomography, In situ demineralization, Microscopy",

author = "Cyril Besnard and Ali Marie and Sisini Sasidharan and Shashidhara Marathe and Kaz Wanelik and Robert Harper and Christoph Rau and Richard Shelton and Gabriel Landini and Korsunsky, {Alexander M.}",

note = "Acknowledgments: This work was done as part of “Tackling human dental caries by multi-modal correlative microscopy and multi-physics modelling” (EP/P005381/1) and “Rich Nonlinear Tomography for advanced materials” (EP/V007785/1), with both projects funded by The Engineering and Physical Sciences Research Council (EPSRC). S.S. and A.M. express their gratitude for the support of the Health Research Bridging Salary Scheme (BRR00060-DF02 and BRR00060-DF03, respectively) by the Medical Science Divisions, University of Oxford. Synchrotron tomography data were collected on I13-2 beamline in Diamond Light Source (Diamond Light Source Ltd., Didcot, Oxfordshire, OX11 0DE, U.K.) under the proposal mg29256-1 and additional data beamtime facilitated by Dr. Andrew Bodey of Diamond Light Source. The authors wish to thank Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for the support in preparing the dental sample. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.",

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AU - Besnard, Cyril

AU - Marie, Ali

AU - Sasidharan, Sisini

AU - Marathe, Shashidhara

AU - Wanelik, Kaz

AU - Harper, Robert

AU - Rau, Christoph

AU - Shelton, Richard

AU - Landini, Gabriel

AU - Korsunsky, Alexander M.

N1 - Acknowledgments: This work was done as part of “Tackling human dental caries by multi-modal correlative microscopy and multi-physics modelling” (EP/P005381/1) and “Rich Nonlinear Tomography for advanced materials” (EP/V007785/1), with both projects funded by The Engineering and Physical Sciences Research Council (EPSRC). S.S. and A.M. express their gratitude for the support of the Health Research Bridging Salary Scheme (BRR00060-DF02 and BRR00060-DF03, respectively) by the Medical Science Divisions, University of Oxford. Synchrotron tomography data were collected on I13-2 beamline in Diamond Light Source (Diamond Light Source Ltd., Didcot, Oxfordshire, OX11 0DE, U.K.) under the proposal mg29256-1 and additional data beamtime facilitated by Dr. Andrew Bodey of Diamond Light Source. The authors wish to thank Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for the support in preparing the dental sample. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.

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N2 - High-resolution spatial and temporal analysis and 3D visualization of time-dependent processes, such as human dental enamel acid demineralization, often present a challenging task. Overcoming this challenge often requires the development of special methods. Dental caries remains one of the most important oral diseases that involves the demineralization of hard dental tissues as a consequence of acid production by oral bacteria. Enamel has a hierarchically organized architecture that extends down to the nanostructural level and requires high resolution to study its evolution in detail. Enamel demineralization is a dynamic process that is best investigated with the help of in situ experiments. In previous studies, synchrotron tomography was applied to study the 3D enamel structure at certain time points (time-lapse tomography). Here, another distinct approach to time-evolving tomography studies is presented, whereby the sample image is reconstructed as it undergoes continuous rotation over a virtually unlimited angular range. The resulting (single) data set contains the data for multiple (potentially overlapping) intermediate tomograms that can be extracted and analyzed as desired using time-stepping selection of data subsets from the continuous fly-scan recording. One of the advantages of this approach is that it reduces the amount of time required to collect an equivalent number of single tomograms. Another advantage is that the nominal time step between successive reconstructions can be significantly reduced. We applied this approach to the study of acidic enamel demineralization and observed the progression of demineralization over time steps significantly smaller than the total acquisition time of a single tomogram, with a voxel size smaller than 0.5 μm. It is expected that the approach presented in this paper can be useful for high-resolution studies of other dynamic processes and for assessing small structural modifications in evolving hierarchical materials.

AB - High-resolution spatial and temporal analysis and 3D visualization of time-dependent processes, such as human dental enamel acid demineralization, often present a challenging task. Overcoming this challenge often requires the development of special methods. Dental caries remains one of the most important oral diseases that involves the demineralization of hard dental tissues as a consequence of acid production by oral bacteria. Enamel has a hierarchically organized architecture that extends down to the nanostructural level and requires high resolution to study its evolution in detail. Enamel demineralization is a dynamic process that is best investigated with the help of in situ experiments. In previous studies, synchrotron tomography was applied to study the 3D enamel structure at certain time points (time-lapse tomography). Here, another distinct approach to time-evolving tomography studies is presented, whereby the sample image is reconstructed as it undergoes continuous rotation over a virtually unlimited angular range. The resulting (single) data set contains the data for multiple (potentially overlapping) intermediate tomograms that can be extracted and analyzed as desired using time-stepping selection of data subsets from the continuous fly-scan recording. One of the advantages of this approach is that it reduces the amount of time required to collect an equivalent number of single tomograms. Another advantage is that the nominal time step between successive reconstructions can be significantly reduced. We applied this approach to the study of acidic enamel demineralization and observed the progression of demineralization over time steps significantly smaller than the total acquisition time of a single tomogram, with a voxel size smaller than 0.5 μm. It is expected that the approach presented in this paper can be useful for high-resolution studies of other dynamic processes and for assessing small structural modifications in evolving hierarchical materials.

KW - Human carious enamel

KW - Synchrotron

KW - X-ray tomography

KW - In situ demineralization

KW - Microscopy

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DO - 10.1021/cbmi.3c00121

M3 - Article

SN - 2832-3637

JO - Chemical & Biomedical Imaging

JF - Chemical & Biomedical Imaging

ER -

Advanced Time-Stepping Interpretation of Fly-Scan Continuous Rotation Synchrotron Tomography of Dental Enamel Demineralization

Abstract

Bibliographical note

Keywords

UN SDGs

Access to Document

Fingerprint

Projects

Tackling human dental caries by multi-modal correlative microscopy and multi-physics modelling

Cite this