Effect of intermittent loading and surface roughness on peri‐implant bone formation in a bone chamber model
Identifieur interne : 006A23 ( Main/Exploration ); précédent : 006A22; suivant : 006A24Effect of intermittent loading and surface roughness on peri‐implant bone formation in a bone chamber model
Auteurs : Joke Duyck ; Elke Slaets [Belgique] ; Kenichi Sasaguri [Japon] ; Katleen Vandamme [Belgique] ; Ignace NaertSource :
- Journal of Clinical Periodontology [ 0303-6979 ] ; 2007-11.
Descripteurs français
- Wicri :
- topic : Titane.
English descriptors
- KwdEn :
- Acid phosphatase, Active bone apposition, Additional experiment, Biomechanical, Blackwell munksgaard, Blood vessels, Body weight, Bone, Bone area, Bone area fraction, Bone chamber, Bone chamber model, Bone chambers, Bone formation, Bone fraction, Bone healing, Bone marrow, Bone tissue, Bone trabeculae, Bonestimulating effect, Brous tissue, Cell differentiation, Central cavity, Central lumina, Clin periodontol, Clinical implant dentistry, Clinical periodontology, Dense tissue, Dental implants, Dentsply friadent, Duyck, Edentulous mandibles, Endothelial cells, Experimental condition, Experimental conditions, Experimental implant, Experimental study, Force transfer, Good biomechanical, Histological, Histological sections, Histomorphometrical analyses, Host bone, Immediate implant loading, Immediate loading, Immunopositive, Immunopositive cells, Implant, Implant axis, Implant cavity, Implant design, Implant healing, Implant installation, Implant loading, Implant osseointegration, Implant removal, Implant roughening, Implant stability, Implant surface roughness, Implant surfaces, Implants research, Individual bone trabeculae, Inner bone chamber, Interfacial micromotion, Intermittent loading, International journal, Journal compilation, Load application, Load transfer, Loading, Loading sessions, Maxillofacial implants, Mechanical conditions, Mechanical implant loading, Mechanical loading, Mechanical stability, Mechanical stimuli, Munksgaard, Naert, Next experiment, Osseointegration, Osteoblast, Osteoblast differentiation, Osteoclast, Other hand, Other studies, Outer bone chamber, Posterior mandible, Primary stability, Reference area, Representative sections, Rough implant, Rough implants, Rough surface, Roughening, Roughness, Same animal, Sampling bone chamber methodology, Several experiments, Similar bone chamber study, Small clusters, Smooth implants, Sole effect, Surface roughening, Surface roughness, Test conditions, Test implants, Tissue area, Tissue blocks, Tissue differentiation, Tissue formation, Tissue growth, Tissue response, Tissue sample, Titanium, Titanium implants, Trabecula, Vandamme, Vander sloten, Vascularization, Vessel fraction, Wiskott belser.
- Teeft :
- Acid phosphatase, Active bone apposition, Additional experiment, Biomechanical, Blackwell munksgaard, Blood vessels, Body weight, Bone, Bone area, Bone area fraction, Bone chamber, Bone chamber model, Bone chambers, Bone formation, Bone fraction, Bone healing, Bone marrow, Bone tissue, Bone trabeculae, Bonestimulating effect, Brous tissue, Cell differentiation, Central cavity, Central lumina, Clin periodontol, Clinical implant dentistry, Clinical periodontology, Dense tissue, Dental implants, Dentsply friadent, Duyck, Edentulous mandibles, Endothelial cells, Experimental condition, Experimental conditions, Experimental implant, Experimental study, Force transfer, Good biomechanical, Histological, Histological sections, Histomorphometrical analyses, Host bone, Immediate implant loading, Immediate loading, Immunopositive, Immunopositive cells, Implant, Implant axis, Implant cavity, Implant design, Implant healing, Implant installation, Implant loading, Implant osseointegration, Implant removal, Implant roughening, Implant stability, Implant surface roughness, Implant surfaces, Implants research, Individual bone trabeculae, Inner bone chamber, Interfacial micromotion, Intermittent loading, International journal, Journal compilation, Load application, Load transfer, Loading, Loading sessions, Maxillofacial implants, Mechanical conditions, Mechanical implant loading, Mechanical loading, Mechanical stability, Mechanical stimuli, Munksgaard, Naert, Next experiment, Osseointegration, Osteoblast, Osteoblast differentiation, Osteoclast, Other hand, Other studies, Outer bone chamber, Posterior mandible, Primary stability, Reference area, Representative sections, Rough implant, Rough implants, Rough surface, Roughening, Roughness, Same animal, Sampling bone chamber methodology, Several experiments, Similar bone chamber study, Small clusters, Smooth implants, Sole effect, Surface roughening, Surface roughness, Test conditions, Test implants, Tissue area, Tissue blocks, Tissue differentiation, Tissue formation, Tissue growth, Tissue response, Tissue sample, Titanium, Titanium implants, Trabecula, Vandamme, Vander sloten, Vascularization, Vessel fraction, Wiskott belser.
Abstract
Both implant surface characteristics and mechanical loading are known to affect implant osseointegration. Their interaction and the underlying mechanisms by which they affect peri‐implant healing processes are still unknown. The aim of this study is therefore to investigate the influence of a turned versus a rough (Plus®, Dentsply Friadent) implant surface on peri‐implant bone formation in case of unloaded or loaded implant healing.
Url:
DOI: 10.1111/j.1600-051X.2007.01135.x
Affiliations:
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Dentistry, Kanagawa Dental College, Yokosuka City, Kanagawa</wicri:regionArea><wicri:noRegion>Kanagawa</wicri:noRegion></affiliation></author><author><name sortKey="Vandamme, Katleen" sort="Vandamme, Katleen" uniqKey="Vandamme K" first="Katleen" last="Vandamme">Katleen Vandamme</name><affiliation wicri:level="1"><country xml:lang="fr">Belgique</country><wicri:regionArea>BIOMAT Research Group, School of Dentistry, Oral Pathology and Maxillofacial Surgery, Faculty of Medicine, K.U.Leuven, Leuven</wicri:regionArea><wicri:noRegion>Leuven</wicri:noRegion></affiliation></author><author><name sortKey="Naert, Ignace" sort="Naert, Ignace" uniqKey="Naert I" first="Ignace" last="Naert">Ignace Naert</name><affiliation><wicri:noCountry code="no comma">Department of Prosthetic Dentistry/BIOMAT Research Group</wicri:noCountry></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Journal of Clinical Periodontology</title><title level="j" type="alt">JOURNAL OF CLINICAL PERIODONTOLOGY</title><idno type="ISSN">0303-6979</idno><idno type="eISSN">1600-051X</idno><imprint><biblScope unit="vol">34</biblScope><biblScope unit="issue">11</biblScope><biblScope unit="page" from="998">998</biblScope><biblScope unit="page" to="1006">1006</biblScope><biblScope unit="page-count">9</biblScope><publisher>Blackwell Publishing Ltd</publisher><pubPlace>Oxford, UK</pubPlace><date type="published" when="2007-11">2007-11</date></imprint><idno type="ISSN">0303-6979</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0303-6979</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Acid phosphatase</term><term>Active bone apposition</term><term>Additional experiment</term><term>Biomechanical</term><term>Blackwell munksgaard</term><term>Blood vessels</term><term>Body weight</term><term>Bone</term><term>Bone area</term><term>Bone area fraction</term><term>Bone chamber</term><term>Bone chamber model</term><term>Bone chambers</term><term>Bone formation</term><term>Bone fraction</term><term>Bone healing</term><term>Bone marrow</term><term>Bone tissue</term><term>Bone trabeculae</term><term>Bonestimulating effect</term><term>Brous tissue</term><term>Cell differentiation</term><term>Central cavity</term><term>Central lumina</term><term>Clin periodontol</term><term>Clinical implant dentistry</term><term>Clinical periodontology</term><term>Dense tissue</term><term>Dental implants</term><term>Dentsply friadent</term><term>Duyck</term><term>Edentulous mandibles</term><term>Endothelial cells</term><term>Experimental condition</term><term>Experimental conditions</term><term>Experimental implant</term><term>Experimental study</term><term>Force transfer</term><term>Good biomechanical</term><term>Histological</term><term>Histological sections</term><term>Histomorphometrical analyses</term><term>Host bone</term><term>Immediate implant loading</term><term>Immediate loading</term><term>Immunopositive</term><term>Immunopositive cells</term><term>Implant</term><term>Implant axis</term><term>Implant cavity</term><term>Implant design</term><term>Implant healing</term><term>Implant installation</term><term>Implant loading</term><term>Implant osseointegration</term><term>Implant removal</term><term>Implant roughening</term><term>Implant stability</term><term>Implant surface roughness</term><term>Implant surfaces</term><term>Implants research</term><term>Individual bone trabeculae</term><term>Inner bone chamber</term><term>Interfacial micromotion</term><term>Intermittent loading</term><term>International journal</term><term>Journal compilation</term><term>Load application</term><term>Load transfer</term><term>Loading</term><term>Loading sessions</term><term>Maxillofacial implants</term><term>Mechanical conditions</term><term>Mechanical implant loading</term><term>Mechanical loading</term><term>Mechanical stability</term><term>Mechanical stimuli</term><term>Munksgaard</term><term>Naert</term><term>Next experiment</term><term>Osseointegration</term><term>Osteoblast</term><term>Osteoblast differentiation</term><term>Osteoclast</term><term>Other hand</term><term>Other studies</term><term>Outer bone chamber</term><term>Posterior mandible</term><term>Primary stability</term><term>Reference area</term><term>Representative sections</term><term>Rough implant</term><term>Rough implants</term><term>Rough surface</term><term>Roughening</term><term>Roughness</term><term>Same animal</term><term>Sampling bone chamber methodology</term><term>Several experiments</term><term>Similar bone chamber study</term><term>Small clusters</term><term>Smooth implants</term><term>Sole effect</term><term>Surface roughening</term><term>Surface roughness</term><term>Test conditions</term><term>Test implants</term><term>Tissue area</term><term>Tissue blocks</term><term>Tissue differentiation</term><term>Tissue formation</term><term>Tissue growth</term><term>Tissue response</term><term>Tissue sample</term><term>Titanium</term><term>Titanium implants</term><term>Trabecula</term><term>Vandamme</term><term>Vander sloten</term><term>Vascularization</term><term>Vessel fraction</term><term>Wiskott belser</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Acid phosphatase</term><term>Active bone apposition</term><term>Additional experiment</term><term>Biomechanical</term><term>Blackwell munksgaard</term><term>Blood vessels</term><term>Body weight</term><term>Bone</term><term>Bone area</term><term>Bone area fraction</term><term>Bone chamber</term><term>Bone chamber model</term><term>Bone chambers</term><term>Bone formation</term><term>Bone fraction</term><term>Bone healing</term><term>Bone marrow</term><term>Bone tissue</term><term>Bone trabeculae</term><term>Bonestimulating effect</term><term>Brous tissue</term><term>Cell differentiation</term><term>Central cavity</term><term>Central lumina</term><term>Clin periodontol</term><term>Clinical implant dentistry</term><term>Clinical periodontology</term><term>Dense tissue</term><term>Dental implants</term><term>Dentsply friadent</term><term>Duyck</term><term>Edentulous mandibles</term><term>Endothelial cells</term><term>Experimental condition</term><term>Experimental conditions</term><term>Experimental implant</term><term>Experimental study</term><term>Force transfer</term><term>Good biomechanical</term><term>Histological</term><term>Histological sections</term><term>Histomorphometrical analyses</term><term>Host bone</term><term>Immediate implant loading</term><term>Immediate loading</term><term>Immunopositive</term><term>Immunopositive cells</term><term>Implant</term><term>Implant axis</term><term>Implant cavity</term><term>Implant design</term><term>Implant healing</term><term>Implant installation</term><term>Implant loading</term><term>Implant osseointegration</term><term>Implant removal</term><term>Implant roughening</term><term>Implant stability</term><term>Implant surface roughness</term><term>Implant surfaces</term><term>Implants research</term><term>Individual bone trabeculae</term><term>Inner bone chamber</term><term>Interfacial micromotion</term><term>Intermittent loading</term><term>International journal</term><term>Journal compilation</term><term>Load application</term><term>Load transfer</term><term>Loading</term><term>Loading sessions</term><term>Maxillofacial implants</term><term>Mechanical conditions</term><term>Mechanical implant loading</term><term>Mechanical loading</term><term>Mechanical stability</term><term>Mechanical stimuli</term><term>Munksgaard</term><term>Naert</term><term>Next experiment</term><term>Osseointegration</term><term>Osteoblast</term><term>Osteoblast differentiation</term><term>Osteoclast</term><term>Other hand</term><term>Other studies</term><term>Outer bone chamber</term><term>Posterior mandible</term><term>Primary stability</term><term>Reference area</term><term>Representative sections</term><term>Rough implant</term><term>Rough implants</term><term>Rough surface</term><term>Roughening</term><term>Roughness</term><term>Same animal</term><term>Sampling bone chamber methodology</term><term>Several experiments</term><term>Similar bone chamber study</term><term>Small clusters</term><term>Smooth implants</term><term>Sole effect</term><term>Surface roughening</term><term>Surface roughness</term><term>Test conditions</term><term>Test implants</term><term>Tissue area</term><term>Tissue blocks</term><term>Tissue differentiation</term><term>Tissue formation</term><term>Tissue growth</term><term>Tissue response</term><term>Tissue sample</term><term>Titanium</term><term>Titanium implants</term><term>Trabecula</term><term>Vandamme</term><term>Vander sloten</term><term>Vascularization</term><term>Vessel fraction</term><term>Wiskott belser</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Titane</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">Both implant surface characteristics and mechanical loading are known to affect implant osseointegration. Their interaction and the underlying mechanisms by which they affect peri‐implant healing processes are still unknown. The aim of this study is therefore to investigate the influence of a turned versus a rough (Plus®, Dentsply Friadent) implant surface on peri‐implant bone formation in case of unloaded or loaded implant healing.</div></front></TEI><affiliations><list><country><li>Belgique</li><li>Japon</li></country></list><tree><noCountry><name sortKey="Duyck, Joke" sort="Duyck, Joke" uniqKey="Duyck J" first="Joke" last="Duyck">Joke Duyck</name><name sortKey="Naert, Ignace" sort="Naert, Ignace" uniqKey="Naert I" first="Ignace" last="Naert">Ignace Naert</name></noCountry><country name="Belgique"><noRegion><name sortKey="Slaets, Elke" sort="Slaets, Elke" uniqKey="Slaets E" first="Elke" last="Slaets">Elke Slaets</name></noRegion><name sortKey="Vandamme, Katleen" sort="Vandamme, Katleen" uniqKey="Vandamme K" first="Katleen" last="Vandamme">Katleen Vandamme</name></country><country name="Japon"><noRegion><name sortKey="Sasaguri, Kenichi" sort="Sasaguri, Kenichi" uniqKey="Sasaguri K" first="Kenichi" last="Sasaguri">Kenichi Sasaguri</name></noRegion></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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