Imaging in vivo secondary caries and ex vivo dental biofilms using cross-polarization optical coherence tomography

Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth–composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Opti...

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Published inDental materials Vol. 28; no. 7; pp. 792 - 800
Main Authors Lenton, Pat, Rudney, Joel, Chen, Ruoqiong, Fok, Alex, Aparicio, Conrado, Jones, Robert S.
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.07.2012
Subjects
Advanced Basic Science
Bacteria
Biofilms
Biofilms - growth & development
Cavitation
Child
Child, Preschool
Composite resin
Composite Resins - chemistry
Demineralizing
Dental Caries - diagnosis
Dental Caries - etiology
Dental Enamel - chemistry
Dental Enamel - microbiology
Dental materials
Dentistry
Early caries detection
Female
Humans
Imaging
Male
Optical Coherence Tomography
Optical microelectromechanical devices
Polarization
Restoration
Tomography, Optical Coherence - instrumentation
Tomography, Optical Coherence - methods
Polarization
Optical coherence tomography
Optical microelectromechanical devices
Composite resin
Early caries detection
Online AccessGet full text
ISSN0109-5641
1879-0097
1879-0097
DOI10.1016/j.dental.2012.04.004

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Abstract Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth–composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe. A newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel–composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites. As a positive control, cavitated secondary carious interfaces showed a 18.2dB increase (p<0.001), or over 1–2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness. This paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.
AbstractList Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth–composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe. A newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel–composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites. As a positive control, cavitated secondary carious interfaces showed a 18.2dB increase (p<0.001), or over 1–2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness. This paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.
Abstract Objective Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth–composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe. Methods A newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel–composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites. Results As a positive control, cavitated secondary carious interfaces showed a 18.2 dB increase ( p < 0.001), or over 1–2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness. Significance This paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.
Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth-composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe.OBJECTIVEConventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth-composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe.A newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel-composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites.METHODSA newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel-composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites.As a positive control, cavitated secondary carious interfaces showed a 18.2dB increase (p<0.001), or over 1-2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness.RESULTSAs a positive control, cavitated secondary carious interfaces showed a 18.2dB increase (p<0.001), or over 1-2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness.This paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.SIGNIFICANCEThis paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.
Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to examine the subsurface tooth-composite interface and to assess for the presence of secondary caries in pediatric patients using a novel Optical Coherence Tomography System with an intraoral probe. A newly designed intraoral cross polarization swept source optical coherence tomography (CP-OCT) imaging system was used to examine the integrity of the enamel-composite interfaces in vivo. Twenty-two pediatric subjects were recruited with either recently placed or long standing composite restorations in their primary teeth. To better understand how bacterial biofilms cause demineralization at the interface, we also used the intraoral CP-OCT system to assess ex vivo bacterial biofilm growth on dental composites. As a positive control, cavitated secondary carious interfaces showed a 18.2dB increase (p<0.001), or over 1-2 orders of magnitude higher, scattering than interfaces associated with recently placed composite restorations. Several long standing composite restorations, which appeared clinically sound, had a marked increase in scattering than recently placed restorations. This suggests the ability of CP-OCT to assess interfacial degradation such as early secondary caries prior to cavitation. CP-OCT was also able to image ex vivo biofilms on dental composites and assess their thickness. This paper shows that CP-OCT imaging using a beam splitter based design can examine the subsurface interface of dental composites in human subjects. Furthermore, the probe dimensions and acquisition speed of the CP-OCT system allowed for analysis of caries development in children.
Author Rudney, Joel
Lenton, Pat
Jones, Robert S.
Chen, Ruoqiong
Fok, Alex
Aparicio, Conrado
AuthorAffiliation 2 Department of Diagnostic and Biological Sciences, University of Minnesota, 515 Delaware Street, Minneapolis, MN, 55455 USA
1 Department of Developmental and Surgical Sciences, University of Minnesota, 515 Delaware Street, Minneapolis, MN, 55455 USA
3 Department of Restorative Sciences, University of Minnesota, 515 Delaware Street, Minneapolis, MN, 55455 USA
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/22578989$$D View this record in MEDLINE/PubMed
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Issue 7
Keywords Polarization
Optical coherence tomography
Optical microelectromechanical devices
Composite resin
Early caries detection
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SSID ssj0004291
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Snippet Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective of this study is to...
Abstract Objective Conventional diagnostic methods frequently detect only late stage enamel demineralization under composite resin restorations. The objective...
SourceID pubmedcentral
proquest
pubmed
crossref
elsevier
SourceType Open Access Repository
Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 792
SubjectTerms Advanced Basic Science
Bacteria
Biofilms
Biofilms - growth & development
Cavitation
Child
Child, Preschool
Composite resin
Composite Resins - chemistry
Demineralizing
Dental Caries - diagnosis
Dental Caries - etiology
Dental Enamel - chemistry
Dental Enamel - microbiology
Dental materials
Dentistry
Early caries detection
Female
Humans
Imaging
Male
Optical Coherence Tomography
Optical microelectromechanical devices
Polarization
Restoration
Tomography, Optical Coherence - instrumentation
Tomography, Optical Coherence - methods
Title Imaging in vivo secondary caries and ex vivo dental biofilms using cross-polarization optical coherence tomography
URI https://www.clinicalkey.com/#!/content/1-s2.0-S0109564112000899
https://www.clinicalkey.es/playcontent/1-s2.0-S0109564112000899
https://dx.doi.org/10.1016/j.dental.2012.04.004
https://www.ncbi.nlm.nih.gov/pubmed/22578989
https://www.proquest.com/docview/1018634647
https://www.proquest.com/docview/1031321591
https://pubmed.ncbi.nlm.nih.gov/PMC3372533
Volume 28
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