The DIAD Approach to Correlative Synchrotron X‑ray Imaging and Diffraction Analysis of Human Enamel

Cyril Besnard; Ali Marie; Sisini Sasidharan; Hans Deyhle; Sharif I. Ahmed; Christina Reinhard; Robert Harper; Richard Shelton; Gabriel Landini; Alexander M. Korsunsky; Andrew M. James

doi:10.1021/cbmi.3c00122

The DIAD Approach to Correlative Synchrotron X‑ray Imaging and Diffraction Analysis of Human Enamel

Cyril Besnard^*, Ali Marie, Sisini Sasidharan, Hans Deyhle, Sharif I. Ahmed, Christina Reinhard, Robert Harper, Richard Shelton, Gabriel Landini, Alexander M. Korsunsky^*, Andrew M. James

^*Corresponding author for this work

Dentistry

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

10 Downloads (Pure)

Abstract

The Dual Imaging and Diffraction (DIAD) beamline at Diamond Light Source (Didcot, U.K.) implements a correlative approach to the dynamic study of materials based on concurrent analysis of identical sample locations using complementary X-ray modalities to reveal structural detail at various length scales. Namely, the underlying beamline principle and its practical implementation allow the collocation of chosen regions within the sample and their interrogation using real-space imaging (radiography and tomography) and reciprocal space scattering (diffraction). The switching between the two principal modes is made smooth and rapid by design, so that the data collected is interlaced to obtain near-simultaneous multimodal characterization. Different specific photon energies are used for each mode, and the interlacing of acquisition steps allows conducting static and dynamic experiments. Building on the demonstrated realization of this state-of-the-art approach requires further refining of the experimental practice, namely, the methods for gauge volume collocation under different modes of beam–sample interaction. To address this challenge, experiments were conducted at DIAD devoted to the study of human dental enamel, a hierarchical structure composed of hydroxyapatite mineral nanocrystals, as a static sample previously affected by dental caries (tooth decay) as well as under dynamic conditions simulating the process of acid demineralization. Collocation and correlation were achieved between WAXS (wide-angle X-ray scattering), 2D (radiographic), and 3D (tomographic) imaging. While X-ray imaging in 2D or 3D modes reveals real-space details of the sample microstructure, X-ray scattering data for each gauge volume provided statistical nanoscale and ultrastructural polycrystal reciprocal-space information such as phase and preferred orientation (texture). Careful registration of the gauge volume positions recorded during the scans allowed direct covisualization of the data from two modalities. Diffraction gauge volumes were identified and visualized within the tomographic data sets, revealing the underlying local information to support the interpretation of the diffraction patterns. The present implementation of the 4D microscopy paradigm allowed following the progression of demineralization and its correlation with time-dependent WAXS pattern evolution in an approach that is transferable to other material systems.

Original language	English
Journal	Chemical & Biomedical Imaging
Early online date	8 Mar 2024
DOIs	https://doi.org/10.1021/cbmi.3c00122
Publication status	E-pub ahead of print - 8 Mar 2024

Bibliographical note

Acknowledgments:
This work was funded by The Engineering and Physical Sciences Research Council (EPSRC) entitled “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). Thanks to Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for support with the preparation of the samples. Synchrotron tomography acquisitions were performed thanks to the DIAD beamline at Diamond Light Source under the proposal mg28054-1 in remote mode. Thanks to Dr. Michael Drakopoulos (Brookhaven National Laboratory, US) for the support on the development of the DIAD beamline. Thanks to Dr. Alberto Leonardi for the discussions on the DIAD data. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.

Keywords

Human enamel
Dental caries
correlative analysis
synchrotron
diffraction

Access to Document

10.1021/cbmi.3c00122Licence: Creative Commons: Attribution (CC BY)

BesnardC2024DIADFinal published version, 9.85 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

@article{06073c4df2a044538c56b3cbebe8eeab,

title = "The DIAD Approach to Correlative Synchrotron X‑ray Imaging and Diffraction Analysis of Human Enamel",

abstract = "The Dual Imaging and Diffraction (DIAD) beamline at Diamond Light Source (Didcot, U.K.) implements a correlative approach to the dynamic study of materials based on concurrent analysis of identical sample locations using complementary X-ray modalities to reveal structural detail at various length scales. Namely, the underlying beamline principle and its practical implementation allow the collocation of chosen regions within the sample and their interrogation using real-space imaging (radiography and tomography) and reciprocal space scattering (diffraction). The switching between the two principal modes is made smooth and rapid by design, so that the data collected is interlaced to obtain near-simultaneous multimodal characterization. Different specific photon energies are used for each mode, and the interlacing of acquisition steps allows conducting static and dynamic experiments. Building on the demonstrated realization of this state-of-the-art approach requires further refining of the experimental practice, namely, the methods for gauge volume collocation under different modes of beam–sample interaction. To address this challenge, experiments were conducted at DIAD devoted to the study of human dental enamel, a hierarchical structure composed of hydroxyapatite mineral nanocrystals, as a static sample previously affected by dental caries (tooth decay) as well as under dynamic conditions simulating the process of acid demineralization. Collocation and correlation were achieved between WAXS (wide-angle X-ray scattering), 2D (radiographic), and 3D (tomographic) imaging. While X-ray imaging in 2D or 3D modes reveals real-space details of the sample microstructure, X-ray scattering data for each gauge volume provided statistical nanoscale and ultrastructural polycrystal reciprocal-space information such as phase and preferred orientation (texture). Careful registration of the gauge volume positions recorded during the scans allowed direct covisualization of the data from two modalities. Diffraction gauge volumes were identified and visualized within the tomographic data sets, revealing the underlying local information to support the interpretation of the diffraction patterns. The present implementation of the 4D microscopy paradigm allowed following the progression of demineralization and its correlation with time-dependent WAXS pattern evolution in an approach that is transferable to other material systems.",

keywords = "Human enamel, Dental caries, correlative analysis, synchrotron, diffraction",

author = "Cyril Besnard and Ali Marie and Sisini Sasidharan and Hans Deyhle and Ahmed, {Sharif I.} and Christina Reinhard and Robert Harper and Richard Shelton and Gabriel Landini and Korsunsky, {Alexander M.} and James, {Andrew M.}",

note = "Acknowledgments: This work was funded by The Engineering and Physical Sciences Research Council (EPSRC) entitled “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). Thanks to Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for support with the preparation of the samples. Synchrotron tomography acquisitions were performed thanks to the DIAD beamline at Diamond Light Source under the proposal mg28054-1 in remote mode. Thanks to Dr. Michael Drakopoulos (Brookhaven National Laboratory, US) for the support on the development of the DIAD beamline. Thanks to Dr. Alberto Leonardi for the discussions on the DIAD data. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.",

year = "2024",

month = mar,

day = "8",

doi = "10.1021/cbmi.3c00122",

language = "English",

journal = "Chemical & Biomedical Imaging",

issn = "2832-3637",

publisher = "American Chemical Society",

}

TY - JOUR

T1 - The DIAD Approach to Correlative Synchrotron X‑ray Imaging and Diffraction Analysis of Human Enamel

AU - Besnard, Cyril

AU - Marie, Ali

AU - Sasidharan, Sisini

AU - Deyhle, Hans

AU - Ahmed, Sharif I.

AU - Reinhard, Christina

AU - Harper, Robert

AU - Shelton, Richard

AU - Landini, Gabriel

AU - Korsunsky, Alexander M.

AU - James, Andrew M.

N1 - Acknowledgments: This work was funded by The Engineering and Physical Sciences Research Council (EPSRC) entitled “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). Thanks to Dr. Jonathan D. James (School of Dentistry, University of Birmingham) for support with the preparation of the samples. Synchrotron tomography acquisitions were performed thanks to the DIAD beamline at Diamond Light Source under the proposal mg28054-1 in remote mode. Thanks to Dr. Michael Drakopoulos (Brookhaven National Laboratory, US) for the support on the development of the DIAD beamline. Thanks to Dr. Alberto Leonardi for the discussions on the DIAD data. Prof. Jin-Chong Tan (University of Oxford, U.K.) is thanked for the additional supervision of the study.

PY - 2024/3/8

Y1 - 2024/3/8

N2 - The Dual Imaging and Diffraction (DIAD) beamline at Diamond Light Source (Didcot, U.K.) implements a correlative approach to the dynamic study of materials based on concurrent analysis of identical sample locations using complementary X-ray modalities to reveal structural detail at various length scales. Namely, the underlying beamline principle and its practical implementation allow the collocation of chosen regions within the sample and their interrogation using real-space imaging (radiography and tomography) and reciprocal space scattering (diffraction). The switching between the two principal modes is made smooth and rapid by design, so that the data collected is interlaced to obtain near-simultaneous multimodal characterization. Different specific photon energies are used for each mode, and the interlacing of acquisition steps allows conducting static and dynamic experiments. Building on the demonstrated realization of this state-of-the-art approach requires further refining of the experimental practice, namely, the methods for gauge volume collocation under different modes of beam–sample interaction. To address this challenge, experiments were conducted at DIAD devoted to the study of human dental enamel, a hierarchical structure composed of hydroxyapatite mineral nanocrystals, as a static sample previously affected by dental caries (tooth decay) as well as under dynamic conditions simulating the process of acid demineralization. Collocation and correlation were achieved between WAXS (wide-angle X-ray scattering), 2D (radiographic), and 3D (tomographic) imaging. While X-ray imaging in 2D or 3D modes reveals real-space details of the sample microstructure, X-ray scattering data for each gauge volume provided statistical nanoscale and ultrastructural polycrystal reciprocal-space information such as phase and preferred orientation (texture). Careful registration of the gauge volume positions recorded during the scans allowed direct covisualization of the data from two modalities. Diffraction gauge volumes were identified and visualized within the tomographic data sets, revealing the underlying local information to support the interpretation of the diffraction patterns. The present implementation of the 4D microscopy paradigm allowed following the progression of demineralization and its correlation with time-dependent WAXS pattern evolution in an approach that is transferable to other material systems.

AB - The Dual Imaging and Diffraction (DIAD) beamline at Diamond Light Source (Didcot, U.K.) implements a correlative approach to the dynamic study of materials based on concurrent analysis of identical sample locations using complementary X-ray modalities to reveal structural detail at various length scales. Namely, the underlying beamline principle and its practical implementation allow the collocation of chosen regions within the sample and their interrogation using real-space imaging (radiography and tomography) and reciprocal space scattering (diffraction). The switching between the two principal modes is made smooth and rapid by design, so that the data collected is interlaced to obtain near-simultaneous multimodal characterization. Different specific photon energies are used for each mode, and the interlacing of acquisition steps allows conducting static and dynamic experiments. Building on the demonstrated realization of this state-of-the-art approach requires further refining of the experimental practice, namely, the methods for gauge volume collocation under different modes of beam–sample interaction. To address this challenge, experiments were conducted at DIAD devoted to the study of human dental enamel, a hierarchical structure composed of hydroxyapatite mineral nanocrystals, as a static sample previously affected by dental caries (tooth decay) as well as under dynamic conditions simulating the process of acid demineralization. Collocation and correlation were achieved between WAXS (wide-angle X-ray scattering), 2D (radiographic), and 3D (tomographic) imaging. While X-ray imaging in 2D or 3D modes reveals real-space details of the sample microstructure, X-ray scattering data for each gauge volume provided statistical nanoscale and ultrastructural polycrystal reciprocal-space information such as phase and preferred orientation (texture). Careful registration of the gauge volume positions recorded during the scans allowed direct covisualization of the data from two modalities. Diffraction gauge volumes were identified and visualized within the tomographic data sets, revealing the underlying local information to support the interpretation of the diffraction patterns. The present implementation of the 4D microscopy paradigm allowed following the progression of demineralization and its correlation with time-dependent WAXS pattern evolution in an approach that is transferable to other material systems.

KW - Human enamel

KW - Dental caries

KW - correlative analysis

KW - synchrotron

KW - diffraction

U2 - 10.1021/cbmi.3c00122

DO - 10.1021/cbmi.3c00122

M3 - Article

SN - 2832-3637

JO - Chemical & Biomedical Imaging

JF - Chemical & Biomedical Imaging

ER -

The DIAD Approach to Correlative Synchrotron X‑ray Imaging and Diffraction Analysis of Human Enamel

Abstract

Bibliographical note

Keywords

Access to Document

Fingerprint

Projects

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

Cite this