Lateral ridge augmentation using a PCL‐TCP scaffold in a clinically relevant but challenging micropig model
Identifieur interne : 003997 ( Main/Exploration ); précédent : 003996; suivant : 003998Lateral ridge augmentation using a PCL‐TCP scaffold in a clinically relevant but challenging micropig model
Auteurs : A. Yeo [Singapour] ; C. Cheok [Singapour] ; S. H. Teoh [Singapour] ; Z. Y. Zhang [Singapour] ; D. Buser [Suisse] ; D. D. Bosshardt [Suisse]Source :
- Clinical Oral Implants Research [ 0905-7161 ] ; 2012-12.
Descripteurs français
- Wicri :
- geographic : Singapour.
- topic : Biomatériau.
English descriptors
- KwdEn :
- Augmentation, Autogenous, Autogenous block graft, Autogenous block grafts, Autograft, Autograft group, Barrier membranes, Biomaterials, Biomedical, Biomedical material research, Block grafts, Bone, Bone formation, Bone grafts, Bone ingrowth, Bone marrow, Bone matrix, Bone regeneration, Bone resorption, Bone substitutes, Bone tissue engineering applications, Buser, Clin, Cordaro, Defect, Defect margin, Defect sites, Dentistry, Direct contact, Early bone formation, Graft, Healing, Healing period, Histologic, Histologic study, Histomorphometric, Histomorphometric analyses, Histomorphometric study, Histomorphometry, Impl, Implant, Implantation, Implants research, Ingrowth, International journal, John wiley sons, Lateral, Lateral ridge augmentation, Mandible, Matrix, Maxillofacial, Maxillofacial surgery, Maximum amount, Micropig, Micropig model, Micropigs, Mineralized bone, Multinucleated giant cells, Novel scaffold, Oral cavity, Oral impl, Oral maxillofacial implants, Overview micrographs, Pcltcp scaffolds, Phosphate scaffolds, Pierre fabre, Present study, Promising results, Regeneration, Resorption, Ridge augmentation, Scaffold, Scaffold group, Scaffold groups, Scatter plot analysis, Schenk, Singapore, Single dose, Soft diet, Soft tissue, Surgical, Surgical procedures, Teoh, Tissue engineering, Vertical ridge augmentation, Xation, Xation screw.
- Teeft :
- Augmentation, Autogenous, Autogenous block graft, Autogenous block grafts, Autograft, Autograft group, Barrier membranes, Biomaterials, Biomedical, Biomedical material research, Block grafts, Bone, Bone formation, Bone grafts, Bone ingrowth, Bone marrow, Bone matrix, Bone regeneration, Bone resorption, Bone substitutes, Bone tissue engineering applications, Buser, Clin, Cordaro, Defect, Defect margin, Defect sites, Dentistry, Direct contact, Early bone formation, Graft, Healing, Healing period, Histologic, Histologic study, Histomorphometric, Histomorphometric analyses, Histomorphometric study, Histomorphometry, Impl, Implant, Implantation, Implants research, Ingrowth, International journal, John wiley sons, Lateral, Lateral ridge augmentation, Mandible, Matrix, Maxillofacial, Maxillofacial surgery, Maximum amount, Micropig, Micropig model, Micropigs, Mineralized bone, Multinucleated giant cells, Novel scaffold, Oral cavity, Oral impl, Oral maxillofacial implants, Overview micrographs, Pcltcp scaffolds, Phosphate scaffolds, Pierre fabre, Present study, Promising results, Regeneration, Resorption, Ridge augmentation, Scaffold, Scaffold group, Scaffold groups, Scatter plot analysis, Schenk, Singapore, Single dose, Soft diet, Soft tissue, Surgical, Surgical procedures, Teoh, Tissue engineering, Vertical ridge augmentation, Xation, Xation screw.
Abstract
In implant dentistry, there is a need for synthetic bone substitute blocks to support ridge augmentation in situations where large bone volumes are missing. Polycaprolactone‐based scaffolds demonstrated excellent results in bone tissue engineering applications. The use of customized polycaprolactone‐tricalcium phosphate (PCL‐TCP) displayed promising results from recent rat femur and rabbit calvaria studies. However, data from clinically representative models in larger animals do not exist.
Url:
DOI: 10.1111/j.1600-0501.2011.02366.x
Affiliations:
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Le document en format XML
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Bosshardt</name><affiliation wicri:level="4"><country xml:lang="fr">Suisse</country><wicri:regionArea>Department of Oral Surgery and Stomatology, School of Dental Medicine, University of Bern, Bern</wicri:regionArea><placeName><settlement type="city">Berne</settlement><region type="région" nuts="3">Canton de Berne</region><settlement type="city">Berne</settlement></placeName><orgName type="university">Université de Berne</orgName></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Clinical Oral Implants Research</title><title level="j" type="alt">CLINICAL ORAL IMPLANTS RESEARCH</title><idno type="ISSN">0905-7161</idno><idno type="eISSN">1600-0501</idno><imprint><biblScope unit="vol">23</biblScope><biblScope unit="issue">12</biblScope><biblScope unit="page" from="1322">1322</biblScope><biblScope unit="page" to="1332">1332</biblScope><biblScope unit="page-count">11</biblScope><date type="published" when="2012-12">2012-12</date></imprint><idno type="ISSN">0905-7161</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0905-7161</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Augmentation</term><term>Autogenous</term><term>Autogenous block graft</term><term>Autogenous block grafts</term><term>Autograft</term><term>Autograft group</term><term>Barrier membranes</term><term>Biomaterials</term><term>Biomedical</term><term>Biomedical material research</term><term>Block grafts</term><term>Bone</term><term>Bone formation</term><term>Bone grafts</term><term>Bone ingrowth</term><term>Bone marrow</term><term>Bone matrix</term><term>Bone regeneration</term><term>Bone resorption</term><term>Bone substitutes</term><term>Bone tissue engineering applications</term><term>Buser</term><term>Clin</term><term>Cordaro</term><term>Defect</term><term>Defect margin</term><term>Defect sites</term><term>Dentistry</term><term>Direct contact</term><term>Early bone formation</term><term>Graft</term><term>Healing</term><term>Healing period</term><term>Histologic</term><term>Histologic study</term><term>Histomorphometric</term><term>Histomorphometric analyses</term><term>Histomorphometric study</term><term>Histomorphometry</term><term>Impl</term><term>Implant</term><term>Implantation</term><term>Implants research</term><term>Ingrowth</term><term>International journal</term><term>John wiley sons</term><term>Lateral</term><term>Lateral ridge augmentation</term><term>Mandible</term><term>Matrix</term><term>Maxillofacial</term><term>Maxillofacial surgery</term><term>Maximum amount</term><term>Micropig</term><term>Micropig model</term><term>Micropigs</term><term>Mineralized bone</term><term>Multinucleated giant cells</term><term>Novel scaffold</term><term>Oral cavity</term><term>Oral impl</term><term>Oral maxillofacial implants</term><term>Overview micrographs</term><term>Pcltcp scaffolds</term><term>Phosphate scaffolds</term><term>Pierre fabre</term><term>Present study</term><term>Promising results</term><term>Regeneration</term><term>Resorption</term><term>Ridge augmentation</term><term>Scaffold</term><term>Scaffold group</term><term>Scaffold groups</term><term>Scatter plot analysis</term><term>Schenk</term><term>Singapore</term><term>Single dose</term><term>Soft diet</term><term>Soft tissue</term><term>Surgical</term><term>Surgical procedures</term><term>Teoh</term><term>Tissue engineering</term><term>Vertical ridge augmentation</term><term>Xation</term><term>Xation screw</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Augmentation</term><term>Autogenous</term><term>Autogenous block graft</term><term>Autogenous block grafts</term><term>Autograft</term><term>Autograft group</term><term>Barrier membranes</term><term>Biomaterials</term><term>Biomedical</term><term>Biomedical material research</term><term>Block grafts</term><term>Bone</term><term>Bone formation</term><term>Bone grafts</term><term>Bone ingrowth</term><term>Bone marrow</term><term>Bone matrix</term><term>Bone regeneration</term><term>Bone resorption</term><term>Bone substitutes</term><term>Bone tissue engineering applications</term><term>Buser</term><term>Clin</term><term>Cordaro</term><term>Defect</term><term>Defect margin</term><term>Defect sites</term><term>Dentistry</term><term>Direct contact</term><term>Early bone formation</term><term>Graft</term><term>Healing</term><term>Healing period</term><term>Histologic</term><term>Histologic study</term><term>Histomorphometric</term><term>Histomorphometric analyses</term><term>Histomorphometric study</term><term>Histomorphometry</term><term>Impl</term><term>Implant</term><term>Implantation</term><term>Implants research</term><term>Ingrowth</term><term>International journal</term><term>John wiley sons</term><term>Lateral</term><term>Lateral ridge augmentation</term><term>Mandible</term><term>Matrix</term><term>Maxillofacial</term><term>Maxillofacial surgery</term><term>Maximum amount</term><term>Micropig</term><term>Micropig model</term><term>Micropigs</term><term>Mineralized bone</term><term>Multinucleated giant cells</term><term>Novel scaffold</term><term>Oral cavity</term><term>Oral impl</term><term>Oral maxillofacial implants</term><term>Overview micrographs</term><term>Pcltcp scaffolds</term><term>Phosphate scaffolds</term><term>Pierre fabre</term><term>Present study</term><term>Promising results</term><term>Regeneration</term><term>Resorption</term><term>Ridge augmentation</term><term>Scaffold</term><term>Scaffold group</term><term>Scaffold groups</term><term>Scatter plot analysis</term><term>Schenk</term><term>Singapore</term><term>Single dose</term><term>Soft diet</term><term>Soft tissue</term><term>Surgical</term><term>Surgical procedures</term><term>Teoh</term><term>Tissue engineering</term><term>Vertical ridge augmentation</term><term>Xation</term><term>Xation screw</term></keywords><keywords scheme="Wicri" type="geographic" xml:lang="fr"><term>Singapour</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Biomatériau</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">In implant dentistry, there is a need for synthetic bone substitute blocks to support ridge augmentation in situations where large bone volumes are missing. Polycaprolactone‐based scaffolds demonstrated excellent results in bone tissue engineering applications. The use of customized polycaprolactone‐tricalcium phosphate (PCL‐TCP) displayed promising results from recent rat femur and rabbit calvaria studies. However, data from clinically representative models in larger animals do not exist.</div></front></TEI><affiliations><list><country><li>Singapour</li><li>Suisse</li></country><region><li>Canton de Berne</li></region><settlement><li>Berne</li></settlement><orgName><li>Université de Berne</li><li>Université nationale de Singapour</li></orgName></list><tree><country name="Singapour"><noRegion><name sortKey="Yeo, A" sort="Yeo, A" uniqKey="Yeo A" first="A." last="Yeo">A. Yeo</name></noRegion><name sortKey="Cheok, C" sort="Cheok, C" uniqKey="Cheok C" first="C." last="Cheok">C. Cheok</name><name sortKey="Teoh, S H" sort="Teoh, S H" uniqKey="Teoh S" first="S. H." last="Teoh">S. H. Teoh</name><name sortKey="Teoh, S H" sort="Teoh, S H" uniqKey="Teoh S" first="S. H." last="Teoh">S. H. Teoh</name><name sortKey="Zhang, Z Y" sort="Zhang, Z Y" uniqKey="Zhang Z" first="Z. Y." last="Zhang">Z. Y. Zhang</name></country><country name="Suisse"><region name="Canton de Berne"><name sortKey="Buser, D" sort="Buser, D" uniqKey="Buser D" first="D." last="Buser">D. Buser</name></region><name sortKey="Bosshardt, D D" sort="Bosshardt, D D" uniqKey="Bosshardt D" first="D. D." last="Bosshardt">D. D. Bosshardt</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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