History of bioceramics
Identifieur interne : 00D493 ( Main/Exploration ); précédent : 00D492; suivant : 00D494History of bioceramics
Auteurs : S. F. Hulbert [États-Unis] ; L. L. Hench [États-Unis] ; D. Forbers [États-Unis] ; L. S. Bowman [États-Unis]Source :
- Ceramics International [ 0272-8842 ] ; 1982.
Descripteurs français
- Wicri :
- topic : Biomatériau, Calcium, Céramique, Phosphate.
English descriptors
- KwdEn :
- Acetabular components, Acta odontol, Adjacent alveolar bone, Adverse tissue reaction, Alumina, Alumina bioceramics, Alumina ceramics, Alumina implants, Aluminate, Basic calcium phosphate, Bioceramics, Biocompatibility, Bioglass, Bioglass coatings, Biomaterials, Biomed, Bone, Bone cement, Bone formation, Bone growth, Bone ingrowth, Bone marrow, Bony defect, Bony defects, Bony deposition, Calcium, Calcium aluminate, Calcium aluminate implants, Calcium aluminate mixture, Calcium ceramics, Calcium hydroxide, Calcium phosphate, Calcium phosphates, Calcium salts, Cancellous bone, Ceramic, Ceramic implants, Ceramic materials, Ceramics, Cerosium, Chemical reactivity, Clinical studies, Connective tissue, Connective tissue ingrowth, Cutright, Defect, Dent, Dicalcium phosphate, Epoxy resin, Femoral component, Femur, Fibroblastic proliferation, Fibrous membrane, Fibrous tissue, Flexural strength, Foreign body reaction, Good biocompatibility, Gris, Hench, High density alumina, Histological events, Hulbert, Hydroxyapatite, Implant, Implant material, Implant materials, Implant site, Implant sites, Implant surface, Implantation, Indiana university school, Inert bioceramics, Inert glass layer, Ingrowth, Interconnecting pores, Interface, Intramuscular application, Inverse relationship, Klawitter, Koster, Lamellar bone, Long bones, Macrophage cultures, Main application, Main applications, Mater, Maxillofacial reconstruction, Mechanical failure, Mechanical integrity, Mechanical strength, Mongrel dogs, Monocalcium phosphate, Months implantation, Muscle tissue, Musculoskeletal system, Nery, Oral biol, Oral mucoperiosteum, Oral path, Oral surg, Osseous, Osseous cavities, Osseous defects, Osseous implants, Osseous infiltration, Osseous penetration, Osseous repair, Osseous tissue, Outer coating, Palatal bone, Paris implants, Periodontal pockets, Phosphate, Physical properties, Physiological environment, Plasma cells, Pmma, Polycrystalline hydroxyapatite, Pore, Pore diameter, Pore size, Porous ceramics, Porous hydroxyapatite, Prosthesis, Radiographic analysis, Random orientation, Reactive, Regeneration, Resorbable, Resorbable bioceramics, Resorbable ceramics, Similar results, Soft tissue, Stainless steel, Subcutaneous tissues, Surface reactive, Surface reactive bioceramics, Surg, Surgical, Surgical implants, Tetracalcium phosphate, Tibia, Tissue infiltration, Tissue ingrowth, Tricalcium, Tricalcium phosphate, Tuberculous cavities.
- Teeft :
- Acetabular components, Acta odontol, Adjacent alveolar bone, Adverse tissue reaction, Alumina, Alumina bioceramics, Alumina ceramics, Alumina implants, Aluminate, Basic calcium phosphate, Bioceramics, Biocompatibility, Bioglass, Bioglass coatings, Biomaterials, Biomed, Bone, Bone cement, Bone formation, Bone growth, Bone ingrowth, Bone marrow, Bony defect, Bony defects, Bony deposition, Calcium, Calcium aluminate, Calcium aluminate implants, Calcium aluminate mixture, Calcium ceramics, Calcium hydroxide, Calcium phosphate, Calcium phosphates, Calcium salts, Cancellous bone, Ceramic, Ceramic implants, Ceramic materials, Ceramics, Cerosium, Chemical reactivity, Clinical studies, Connective tissue, Connective tissue ingrowth, Cutright, Defect, Dent, Dicalcium phosphate, Epoxy resin, Femoral component, Femur, Fibroblastic proliferation, Fibrous membrane, Fibrous tissue, Flexural strength, Foreign body reaction, Good biocompatibility, Gris, Hench, High density alumina, Histological events, Hulbert, Hydroxyapatite, Implant, Implant material, Implant materials, Implant site, Implant sites, Implant surface, Implantation, Indiana university school, Inert bioceramics, Inert glass layer, Ingrowth, Interconnecting pores, Interface, Intramuscular application, Inverse relationship, Klawitter, Koster, Lamellar bone, Long bones, Macrophage cultures, Main application, Main applications, Mater, Maxillofacial reconstruction, Mechanical failure, Mechanical integrity, Mechanical strength, Mongrel dogs, Monocalcium phosphate, Months implantation, Muscle tissue, Musculoskeletal system, Nery, Oral biol, Oral mucoperiosteum, Oral path, Oral surg, Osseous, Osseous cavities, Osseous defects, Osseous implants, Osseous infiltration, Osseous penetration, Osseous repair, Osseous tissue, Outer coating, Palatal bone, Paris implants, Periodontal pockets, Phosphate, Physical properties, Physiological environment, Plasma cells, Pmma, Polycrystalline hydroxyapatite, Pore, Pore diameter, Pore size, Porous ceramics, Porous hydroxyapatite, Prosthesis, Radiographic analysis, Random orientation, Reactive, Regeneration, Resorbable, Resorbable bioceramics, Resorbable ceramics, Similar results, Soft tissue, Stainless steel, Subcutaneous tissues, Surface reactive, Surface reactive bioceramics, Surg, Surgical, Surgical implants, Tetracalcium phosphate, Tibia, Tissue infiltration, Tissue ingrowth, Tricalcium, Tricalcium phosphate, Tuberculous cavities.
Abstract
Abstract: The history of bioceramics is reviewed and the current status of the use of nearly inert, surface reactive, and resorbable bioceramics discussed.
Url:
DOI: 10.1016/0272-8842(82)90003-7
Affiliations:
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Le document en format XML
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<profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Acetabular components</term>
<term>Acta odontol</term>
<term>Adjacent alveolar bone</term>
<term>Adverse tissue reaction</term>
<term>Alumina</term>
<term>Alumina bioceramics</term>
<term>Alumina ceramics</term>
<term>Alumina implants</term>
<term>Aluminate</term>
<term>Basic calcium phosphate</term>
<term>Bioceramics</term>
<term>Biocompatibility</term>
<term>Bioglass</term>
<term>Bioglass coatings</term>
<term>Biomaterials</term>
<term>Biomed</term>
<term>Bone</term>
<term>Bone cement</term>
<term>Bone formation</term>
<term>Bone growth</term>
<term>Bone ingrowth</term>
<term>Bone marrow</term>
<term>Bony defect</term>
<term>Bony defects</term>
<term>Bony deposition</term>
<term>Calcium</term>
<term>Calcium aluminate</term>
<term>Calcium aluminate implants</term>
<term>Calcium aluminate mixture</term>
<term>Calcium ceramics</term>
<term>Calcium hydroxide</term>
<term>Calcium phosphate</term>
<term>Calcium phosphates</term>
<term>Calcium salts</term>
<term>Cancellous bone</term>
<term>Ceramic</term>
<term>Ceramic implants</term>
<term>Ceramic materials</term>
<term>Ceramics</term>
<term>Cerosium</term>
<term>Chemical reactivity</term>
<term>Clinical studies</term>
<term>Connective tissue</term>
<term>Connective tissue ingrowth</term>
<term>Cutright</term>
<term>Defect</term>
<term>Dent</term>
<term>Dicalcium phosphate</term>
<term>Epoxy resin</term>
<term>Femoral component</term>
<term>Femur</term>
<term>Fibroblastic proliferation</term>
<term>Fibrous membrane</term>
<term>Fibrous tissue</term>
<term>Flexural strength</term>
<term>Foreign body reaction</term>
<term>Good biocompatibility</term>
<term>Gris</term>
<term>Hench</term>
<term>High density alumina</term>
<term>Histological events</term>
<term>Hulbert</term>
<term>Hydroxyapatite</term>
<term>Implant</term>
<term>Implant material</term>
<term>Implant materials</term>
<term>Implant site</term>
<term>Implant sites</term>
<term>Implant surface</term>
<term>Implantation</term>
<term>Indiana university school</term>
<term>Inert bioceramics</term>
<term>Inert glass layer</term>
<term>Ingrowth</term>
<term>Interconnecting pores</term>
<term>Interface</term>
<term>Intramuscular application</term>
<term>Inverse relationship</term>
<term>Klawitter</term>
<term>Koster</term>
<term>Lamellar bone</term>
<term>Long bones</term>
<term>Macrophage cultures</term>
<term>Main application</term>
<term>Main applications</term>
<term>Mater</term>
<term>Maxillofacial reconstruction</term>
<term>Mechanical failure</term>
<term>Mechanical integrity</term>
<term>Mechanical strength</term>
<term>Mongrel dogs</term>
<term>Monocalcium phosphate</term>
<term>Months implantation</term>
<term>Muscle tissue</term>
<term>Musculoskeletal system</term>
<term>Nery</term>
<term>Oral biol</term>
<term>Oral mucoperiosteum</term>
<term>Oral path</term>
<term>Oral surg</term>
<term>Osseous</term>
<term>Osseous cavities</term>
<term>Osseous defects</term>
<term>Osseous implants</term>
<term>Osseous infiltration</term>
<term>Osseous penetration</term>
<term>Osseous repair</term>
<term>Osseous tissue</term>
<term>Outer coating</term>
<term>Palatal bone</term>
<term>Paris implants</term>
<term>Periodontal pockets</term>
<term>Phosphate</term>
<term>Physical properties</term>
<term>Physiological environment</term>
<term>Plasma cells</term>
<term>Pmma</term>
<term>Polycrystalline hydroxyapatite</term>
<term>Pore</term>
<term>Pore diameter</term>
<term>Pore size</term>
<term>Porous ceramics</term>
<term>Porous hydroxyapatite</term>
<term>Prosthesis</term>
<term>Radiographic analysis</term>
<term>Random orientation</term>
<term>Reactive</term>
<term>Regeneration</term>
<term>Resorbable</term>
<term>Resorbable bioceramics</term>
<term>Resorbable ceramics</term>
<term>Similar results</term>
<term>Soft tissue</term>
<term>Stainless steel</term>
<term>Subcutaneous tissues</term>
<term>Surface reactive</term>
<term>Surface reactive bioceramics</term>
<term>Surg</term>
<term>Surgical</term>
<term>Surgical implants</term>
<term>Tetracalcium phosphate</term>
<term>Tibia</term>
<term>Tissue infiltration</term>
<term>Tissue ingrowth</term>
<term>Tricalcium</term>
<term>Tricalcium phosphate</term>
<term>Tuberculous cavities</term>
</keywords>
<keywords scheme="Teeft" xml:lang="en"><term>Acetabular components</term>
<term>Acta odontol</term>
<term>Adjacent alveolar bone</term>
<term>Adverse tissue reaction</term>
<term>Alumina</term>
<term>Alumina bioceramics</term>
<term>Alumina ceramics</term>
<term>Alumina implants</term>
<term>Aluminate</term>
<term>Basic calcium phosphate</term>
<term>Bioceramics</term>
<term>Biocompatibility</term>
<term>Bioglass</term>
<term>Bioglass coatings</term>
<term>Biomaterials</term>
<term>Biomed</term>
<term>Bone</term>
<term>Bone cement</term>
<term>Bone formation</term>
<term>Bone growth</term>
<term>Bone ingrowth</term>
<term>Bone marrow</term>
<term>Bony defect</term>
<term>Bony defects</term>
<term>Bony deposition</term>
<term>Calcium</term>
<term>Calcium aluminate</term>
<term>Calcium aluminate implants</term>
<term>Calcium aluminate mixture</term>
<term>Calcium ceramics</term>
<term>Calcium hydroxide</term>
<term>Calcium phosphate</term>
<term>Calcium phosphates</term>
<term>Calcium salts</term>
<term>Cancellous bone</term>
<term>Ceramic</term>
<term>Ceramic implants</term>
<term>Ceramic materials</term>
<term>Ceramics</term>
<term>Cerosium</term>
<term>Chemical reactivity</term>
<term>Clinical studies</term>
<term>Connective tissue</term>
<term>Connective tissue ingrowth</term>
<term>Cutright</term>
<term>Defect</term>
<term>Dent</term>
<term>Dicalcium phosphate</term>
<term>Epoxy resin</term>
<term>Femoral component</term>
<term>Femur</term>
<term>Fibroblastic proliferation</term>
<term>Fibrous membrane</term>
<term>Fibrous tissue</term>
<term>Flexural strength</term>
<term>Foreign body reaction</term>
<term>Good biocompatibility</term>
<term>Gris</term>
<term>Hench</term>
<term>High density alumina</term>
<term>Histological events</term>
<term>Hulbert</term>
<term>Hydroxyapatite</term>
<term>Implant</term>
<term>Implant material</term>
<term>Implant materials</term>
<term>Implant site</term>
<term>Implant sites</term>
<term>Implant surface</term>
<term>Implantation</term>
<term>Indiana university school</term>
<term>Inert bioceramics</term>
<term>Inert glass layer</term>
<term>Ingrowth</term>
<term>Interconnecting pores</term>
<term>Interface</term>
<term>Intramuscular application</term>
<term>Inverse relationship</term>
<term>Klawitter</term>
<term>Koster</term>
<term>Lamellar bone</term>
<term>Long bones</term>
<term>Macrophage cultures</term>
<term>Main application</term>
<term>Main applications</term>
<term>Mater</term>
<term>Maxillofacial reconstruction</term>
<term>Mechanical failure</term>
<term>Mechanical integrity</term>
<term>Mechanical strength</term>
<term>Mongrel dogs</term>
<term>Monocalcium phosphate</term>
<term>Months implantation</term>
<term>Muscle tissue</term>
<term>Musculoskeletal system</term>
<term>Nery</term>
<term>Oral biol</term>
<term>Oral mucoperiosteum</term>
<term>Oral path</term>
<term>Oral surg</term>
<term>Osseous</term>
<term>Osseous cavities</term>
<term>Osseous defects</term>
<term>Osseous implants</term>
<term>Osseous infiltration</term>
<term>Osseous penetration</term>
<term>Osseous repair</term>
<term>Osseous tissue</term>
<term>Outer coating</term>
<term>Palatal bone</term>
<term>Paris implants</term>
<term>Periodontal pockets</term>
<term>Phosphate</term>
<term>Physical properties</term>
<term>Physiological environment</term>
<term>Plasma cells</term>
<term>Pmma</term>
<term>Polycrystalline hydroxyapatite</term>
<term>Pore</term>
<term>Pore diameter</term>
<term>Pore size</term>
<term>Porous ceramics</term>
<term>Porous hydroxyapatite</term>
<term>Prosthesis</term>
<term>Radiographic analysis</term>
<term>Random orientation</term>
<term>Reactive</term>
<term>Regeneration</term>
<term>Resorbable</term>
<term>Resorbable bioceramics</term>
<term>Resorbable ceramics</term>
<term>Similar results</term>
<term>Soft tissue</term>
<term>Stainless steel</term>
<term>Subcutaneous tissues</term>
<term>Surface reactive</term>
<term>Surface reactive bioceramics</term>
<term>Surg</term>
<term>Surgical</term>
<term>Surgical implants</term>
<term>Tetracalcium phosphate</term>
<term>Tibia</term>
<term>Tissue infiltration</term>
<term>Tissue ingrowth</term>
<term>Tricalcium</term>
<term>Tricalcium phosphate</term>
<term>Tuberculous cavities</term>
</keywords>
<keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Biomatériau</term>
<term>Calcium</term>
<term>Céramique</term>
<term>Phosphate</term>
</keywords>
</textClass>
<langUsage><language ident="en">en</language>
</langUsage>
</profileDesc>
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<front><div type="abstract" xml:lang="en">Abstract: The history of bioceramics is reviewed and the current status of the use of nearly inert, surface reactive, and resorbable bioceramics discussed.</div>
</front>
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