Histodynamics of bone tissue formation around immediately loaded cylindrical implants in the rabbit
Identifieur interne : 006999 ( Main/Exploration ); précédent : 006998; suivant : 006A00Histodynamics of bone tissue formation around immediately loaded cylindrical implants in the rabbit
Auteurs : Katleen Vandamme [Belgique] ; Ignace Naert [Belgique] ; Liesbet Geris [Belgique] ; Jozef Vander Sloten [Belgique] ; Robert Puers [Belgique] ; Joke Duyck [Belgique]Source :
- Clinical Oral Implants Research [ 0905-7161 ] ; 2007-08.
Descripteurs français
English descriptors
- KwdEn :
- Amin area, Belgium, Biomechanics, Biomedical materials research, Blackwell munksgaard, Blackwell munksgaard vandamme, Blood vessels, Body weight, Bone, Bone area, Bone area fraction, Bone cells, Bone chamber, Bone chamber model, Bone chambers, Bone contact, Bone formation, Bone fraction, Bone marrow, Bone response, Bone tissue, Bone tissue area, Bone tissue formation, Bone trabeculae, Brous, Brous encapsulation, Brous tissue, Brous tissue formation, Clin, Clinical orthopaedics, Cylindrical implants, Dental implants, Different experiments, Different loading conditions, Duyck, Early loading, Experimental literature, Extraction sites, Fracture, Fracture healing, Healing phase, Highest values, Histological, Histological section, Histological sections, Histomorphometric parameters, Immediate implant placement, Immediate loading, Impl, Implant, Implant area, Implant displacement, Implant loading, Implant perimeter, Implant surface, Implants research, Initial vascularization, Inner bone chamber, Inner bone chamber area, Interface, Interfragmentary movements, International journal, Joke duyck, Journal compilation, Knothe tate, Leuven, Load cycles, Loading, Loading condition, Loading conditions, Loading experiment, Loading experiments, Loading implants, Loading session, Loading state, Loading state table, Locomotor apparatus, Maxillofacial implants, Mechanical conditions, Mechanical loading history, Mechanical stability, Mechanical stimulation, Mechanical stimuli, Medial side, Mineral research, Mineralized, Mineralized bone, Mineralized bone area, Mineralized bone fraction, Mineralized bone trabecula, Mineralized bone trabeculae, Munksgaard, Oral impl, Oral implantology, Oral implants, Orthopaedic research, Osseointegrated implants, Osseointegration, Outer bone chamber, Parent bone, Percentage area, Perforation, Positive effect, Present study, Proximal tibia, Research flanders, Scar formation, Shear stresses, Skeletal tissue regeneration, Space maintainer, Surgical procedure, Tibia, Tissue area fraction, Tissue differentiation, Tissue formation, Tissue growth, Tissue repair, Tissue response, Titanium, Titanium implant, Titanium implants, Titanium interface, Total tissue area, Trabecula, Vandamme, Vander sloten, Xator, Xator group.
- Teeft :
- Amin area, Belgium, Biomechanics, Biomedical materials research, Blackwell munksgaard, Blackwell munksgaard vandamme, Blood vessels, Body weight, Bone, Bone area, Bone area fraction, Bone cells, Bone chamber, Bone chamber model, Bone chambers, Bone contact, Bone formation, Bone fraction, Bone marrow, Bone response, Bone tissue, Bone tissue area, Bone tissue formation, Bone trabeculae, Brous, Brous encapsulation, Brous tissue, Brous tissue formation, Clin, Clinical orthopaedics, Cylindrical implants, Dental implants, Different experiments, Different loading conditions, Duyck, Early loading, Experimental literature, Extraction sites, Fracture, Fracture healing, Healing phase, Highest values, Histological, Histological section, Histological sections, Histomorphometric parameters, Immediate implant placement, Immediate loading, Impl, Implant, Implant area, Implant displacement, Implant loading, Implant perimeter, Implant surface, Implants research, Initial vascularization, Inner bone chamber, Inner bone chamber area, Interface, Interfragmentary movements, International journal, Joke duyck, Journal compilation, Knothe tate, Leuven, Load cycles, Loading, Loading condition, Loading conditions, Loading experiment, Loading experiments, Loading implants, Loading session, Loading state, Loading state table, Locomotor apparatus, Maxillofacial implants, Mechanical conditions, Mechanical loading history, Mechanical stability, Mechanical stimulation, Mechanical stimuli, Medial side, Mineral research, Mineralized, Mineralized bone, Mineralized bone area, Mineralized bone fraction, Mineralized bone trabecula, Mineralized bone trabeculae, Munksgaard, Oral impl, Oral implantology, Oral implants, Orthopaedic research, Osseointegrated implants, Osseointegration, Outer bone chamber, Parent bone, Percentage area, Perforation, Positive effect, Present study, Proximal tibia, Research flanders, Scar formation, Shear stresses, Skeletal tissue regeneration, Space maintainer, Surgical procedure, Tibia, Tissue area fraction, Tissue differentiation, Tissue formation, Tissue growth, Tissue repair, Tissue response, Titanium, Titanium implant, Titanium implants, Titanium interface, Total tissue area, Trabecula, Vandamme, Vander sloten, Xator, Xator group.
Abstract
Objectives: The local mechanical environment influences early peri‐implant tissue formation. It is still unclear whether immediate loading limits or promotes peri‐implant osteogenesis and which mechanical parameters are important herein. The present study evaluated the influence of well‐controlled mechanical stimuli on the tissue response around immediately loaded cylindrical turned titanium implants at two different observation periods.
Url:
DOI: 10.1111/j.1600-0501.2007.01339.x
Affiliations:
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Leuven, Leuven</wicri:regionArea><wicri:noRegion>Leuven</wicri:noRegion></affiliation></author><author><name sortKey="Duyck, Joke" sort="Duyck, Joke" uniqKey="Duyck J" first="Joke" last="Duyck">Joke Duyck</name><affiliation wicri:level="1"><country xml:lang="fr">Belgique</country><wicri:regionArea>Department of Prosthetic Dentistry/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></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">18</biblScope><biblScope unit="issue">4</biblScope><biblScope unit="page" from="471">471</biblScope><biblScope unit="page" to="480">480</biblScope><biblScope unit="page-count">10</biblScope><publisher>Blackwell Publishing Ltd</publisher><pubPlace>Oxford, UK</pubPlace><date type="published" when="2007-08">2007-08</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>Amin area</term><term>Belgium</term><term>Biomechanics</term><term>Biomedical materials research</term><term>Blackwell munksgaard</term><term>Blackwell munksgaard vandamme</term><term>Blood vessels</term><term>Body weight</term><term>Bone</term><term>Bone area</term><term>Bone area fraction</term><term>Bone cells</term><term>Bone chamber</term><term>Bone chamber model</term><term>Bone chambers</term><term>Bone contact</term><term>Bone formation</term><term>Bone fraction</term><term>Bone marrow</term><term>Bone response</term><term>Bone tissue</term><term>Bone tissue area</term><term>Bone tissue formation</term><term>Bone trabeculae</term><term>Brous</term><term>Brous encapsulation</term><term>Brous tissue</term><term>Brous tissue formation</term><term>Clin</term><term>Clinical orthopaedics</term><term>Cylindrical implants</term><term>Dental implants</term><term>Different experiments</term><term>Different loading conditions</term><term>Duyck</term><term>Early loading</term><term>Experimental literature</term><term>Extraction sites</term><term>Fracture</term><term>Fracture healing</term><term>Healing phase</term><term>Highest values</term><term>Histological</term><term>Histological section</term><term>Histological sections</term><term>Histomorphometric parameters</term><term>Immediate implant placement</term><term>Immediate loading</term><term>Impl</term><term>Implant</term><term>Implant area</term><term>Implant displacement</term><term>Implant loading</term><term>Implant perimeter</term><term>Implant surface</term><term>Implants research</term><term>Initial vascularization</term><term>Inner bone chamber</term><term>Inner bone chamber area</term><term>Interface</term><term>Interfragmentary movements</term><term>International journal</term><term>Joke duyck</term><term>Journal compilation</term><term>Knothe tate</term><term>Leuven</term><term>Load cycles</term><term>Loading</term><term>Loading condition</term><term>Loading conditions</term><term>Loading experiment</term><term>Loading experiments</term><term>Loading implants</term><term>Loading session</term><term>Loading state</term><term>Loading state table</term><term>Locomotor apparatus</term><term>Maxillofacial implants</term><term>Mechanical conditions</term><term>Mechanical loading history</term><term>Mechanical stability</term><term>Mechanical stimulation</term><term>Mechanical stimuli</term><term>Medial side</term><term>Mineral research</term><term>Mineralized</term><term>Mineralized bone</term><term>Mineralized bone area</term><term>Mineralized bone fraction</term><term>Mineralized bone trabecula</term><term>Mineralized bone trabeculae</term><term>Munksgaard</term><term>Oral impl</term><term>Oral implantology</term><term>Oral implants</term><term>Orthopaedic research</term><term>Osseointegrated implants</term><term>Osseointegration</term><term>Outer bone chamber</term><term>Parent bone</term><term>Percentage area</term><term>Perforation</term><term>Positive effect</term><term>Present study</term><term>Proximal tibia</term><term>Research flanders</term><term>Scar formation</term><term>Shear stresses</term><term>Skeletal tissue regeneration</term><term>Space maintainer</term><term>Surgical procedure</term><term>Tibia</term><term>Tissue area fraction</term><term>Tissue differentiation</term><term>Tissue formation</term><term>Tissue growth</term><term>Tissue repair</term><term>Tissue response</term><term>Titanium</term><term>Titanium implant</term><term>Titanium implants</term><term>Titanium interface</term><term>Total tissue area</term><term>Trabecula</term><term>Vandamme</term><term>Vander sloten</term><term>Xator</term><term>Xator group</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Amin area</term><term>Belgium</term><term>Biomechanics</term><term>Biomedical materials research</term><term>Blackwell munksgaard</term><term>Blackwell munksgaard vandamme</term><term>Blood vessels</term><term>Body weight</term><term>Bone</term><term>Bone area</term><term>Bone area fraction</term><term>Bone cells</term><term>Bone chamber</term><term>Bone chamber model</term><term>Bone chambers</term><term>Bone contact</term><term>Bone formation</term><term>Bone fraction</term><term>Bone marrow</term><term>Bone response</term><term>Bone tissue</term><term>Bone tissue area</term><term>Bone tissue formation</term><term>Bone trabeculae</term><term>Brous</term><term>Brous encapsulation</term><term>Brous tissue</term><term>Brous tissue formation</term><term>Clin</term><term>Clinical orthopaedics</term><term>Cylindrical implants</term><term>Dental implants</term><term>Different experiments</term><term>Different loading conditions</term><term>Duyck</term><term>Early loading</term><term>Experimental literature</term><term>Extraction sites</term><term>Fracture</term><term>Fracture healing</term><term>Healing phase</term><term>Highest values</term><term>Histological</term><term>Histological section</term><term>Histological sections</term><term>Histomorphometric parameters</term><term>Immediate implant placement</term><term>Immediate loading</term><term>Impl</term><term>Implant</term><term>Implant area</term><term>Implant displacement</term><term>Implant loading</term><term>Implant perimeter</term><term>Implant surface</term><term>Implants research</term><term>Initial vascularization</term><term>Inner bone chamber</term><term>Inner bone chamber area</term><term>Interface</term><term>Interfragmentary movements</term><term>International journal</term><term>Joke duyck</term><term>Journal compilation</term><term>Knothe tate</term><term>Leuven</term><term>Load cycles</term><term>Loading</term><term>Loading condition</term><term>Loading conditions</term><term>Loading experiment</term><term>Loading experiments</term><term>Loading implants</term><term>Loading session</term><term>Loading state</term><term>Loading state table</term><term>Locomotor apparatus</term><term>Maxillofacial implants</term><term>Mechanical conditions</term><term>Mechanical loading history</term><term>Mechanical stability</term><term>Mechanical stimulation</term><term>Mechanical stimuli</term><term>Medial side</term><term>Mineral research</term><term>Mineralized</term><term>Mineralized bone</term><term>Mineralized bone area</term><term>Mineralized bone fraction</term><term>Mineralized bone trabecula</term><term>Mineralized bone trabeculae</term><term>Munksgaard</term><term>Oral impl</term><term>Oral implantology</term><term>Oral implants</term><term>Orthopaedic research</term><term>Osseointegrated implants</term><term>Osseointegration</term><term>Outer bone chamber</term><term>Parent bone</term><term>Percentage area</term><term>Perforation</term><term>Positive effect</term><term>Present study</term><term>Proximal tibia</term><term>Research flanders</term><term>Scar formation</term><term>Shear stresses</term><term>Skeletal tissue regeneration</term><term>Space maintainer</term><term>Surgical procedure</term><term>Tibia</term><term>Tissue area fraction</term><term>Tissue differentiation</term><term>Tissue formation</term><term>Tissue growth</term><term>Tissue repair</term><term>Tissue response</term><term>Titanium</term><term>Titanium implant</term><term>Titanium implants</term><term>Titanium interface</term><term>Total tissue area</term><term>Trabecula</term><term>Vandamme</term><term>Vander sloten</term><term>Xator</term><term>Xator group</term></keywords><keywords scheme="Wicri" type="geographic" xml:lang="fr"><term>Belgique</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Titane</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">Objectives: The local mechanical environment influences early peri‐implant tissue formation. It is still unclear whether immediate loading limits or promotes peri‐implant osteogenesis and which mechanical parameters are important herein. The present study evaluated the influence of well‐controlled mechanical stimuli on the tissue response around immediately loaded cylindrical turned titanium implants at two different observation periods.</div></front></TEI><affiliations><list><country><li>Belgique</li></country></list><tree><country name="Belgique"><noRegion><name sortKey="Vandamme, Katleen" sort="Vandamme, Katleen" uniqKey="Vandamme K" first="Katleen" last="Vandamme">Katleen Vandamme</name></noRegion><name sortKey="Duyck, Joke" sort="Duyck, Joke" uniqKey="Duyck J" first="Joke" last="Duyck">Joke Duyck</name><name sortKey="Geris, Liesbet" sort="Geris, Liesbet" uniqKey="Geris L" first="Liesbet" last="Geris">Liesbet Geris</name><name sortKey="Naert, Ignace" sort="Naert, Ignace" uniqKey="Naert I" first="Ignace" last="Naert">Ignace Naert</name><name sortKey="Puers, Robert" sort="Puers, Robert" uniqKey="Puers R" first="Robert" last="Puers">Robert Puers</name><name sortKey="Sloten, Jozef Vander" sort="Sloten, Jozef Vander" uniqKey="Sloten J" first="Jozef Vander" last="Sloten">Jozef Vander Sloten</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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