The Resource Biomaterials : a tantalus experience, Jozef A. Helsen, Yannis Missirlis

Biomaterials : a tantalus experience, Jozef A. Helsen, Yannis Missirlis

Label
Biomaterials : a tantalus experience
Title
Biomaterials
Title remainder
a tantalus experience
Statement of responsibility
Jozef A. Helsen, Yannis Missirlis
Creator
Contributor
Subject
Language
eng
Member of
Cataloging source
NLM
http://library.link/vocab/creatorName
Helsen, Jef A
Illustrations
illustrations
Index
index present
LC call number
R857.M3
LC item number
H45 2010
Literary form
non fiction
Nature of contents
bibliography
NLM call number
  • 2010 N-021
  • QT 37
http://library.link/vocab/relatedWorkOrContributorDate
1946-
http://library.link/vocab/relatedWorkOrContributorName
Missirlis, Y. F.
Series statement
Biological and medical physics, biomedical engineering,
http://library.link/vocab/subjectName
  • Biomedical materials
  • Tissue engineering
  • Biocompatible Materials
  • Tissue Engineering
Label
Biomaterials : a tantalus experience, Jozef A. Helsen, Yannis Missirlis
Instantiates
Publication
Bibliography note
Includes bibliographical references and index
Contents
  • Scaling of Plants and Animals
  • Thermoplastic Polymers
  • 6.4.
  • External Fixators
  • 6.5.
  • Exploring the Future
  • 6.6.
  • Osteosynthesis
  • 6.7.
  • G.A. Ilizarov
  • 7.
  • 1.4.
  • Layer by Layer
  • 7.1.
  • Computer-Aided Design
  • 7.2.
  • Electron Beam Melting
  • 7.3.
  • Selective Laser Melting of Metal Powder
  • 7.4.
  • Stereolithography of Polymers
  • 7.5.
  • Definitions
  • Characterization of Porous Structures
  • 7.6.
  • Conclusion
  • 8.
  • Metal Implants Bound to Disappear
  • 8.1.
  • Soluble Metals?
  • 8.2.
  • Prospecting for the Best
  • 8.3.
  • 2.
  • Hope?
  • 8.4.
  • Mg Foams
  • 8.5.
  • In Vitro and In Vivo
  • 8.6.
  • Conclusion
  • 9.
  • 7,000 Year Old Story: Ceramics
  • 9.1.
  • Failing Human Machine
  • Greek Pottery, a Useful Intermezzo?
  • 9.2.
  • Ceramics, Impossible to Define?
  • 9.3.
  • Ceramics
  • 9.3.1.
  • High Performance
  • 9.3.2.
  • Low Performance
  • 9.4.
  • 2.1.
  • Glass and Glass-Ceramics
  • 9.4.1.
  • Bioactive Glasses
  • 9.4.2.
  • Glass-Ceramics
  • 9.5.
  • Coatings
  • 9.6.
  • General Conclusion
  • 10.
  • Total Hip Replacement
  • Dental Materials
  • 10.1.
  • Difficulties to "Bridge"
  • 10.2.
  • Amalgam
  • 10.3.
  • Composite Alternatives
  • 10.3.1.
  • Adhesives
  • 10.3.2.
  • 2.2.
  • Restorative Composites
  • 10.4.
  • Orthodontics
  • 10.5.
  • Implants
  • 10.6.
  • Ceramics
  • 10.7.
  • Calcium Phosphates
  • 10.8.
  • Strength and Response to Load
  • Postscript
  • 11.
  • Perfect Prosthesis?
  • 11.1.
  • isoelastic Prosthesis
  • 11.2.
  • Polymers for Implants
  • 11.3.
  • Why is a Polymer Like PMMA Transparent to Visible Light?
  • 11.4.
  • 2.2.1.
  • Polyethyleneterephtalate
  • 11.5.
  • Polyamide
  • 11.6.
  • Was the Isoelastic Concept a Good Idea?
  • 11.7.
  • Heraclitus, 2500 Years Old and Still Alive
  • 11.8.
  • We Shall Overcome... Do We?
  • 11.9.
  • Machine generated contents note:
  • Stainless Steel
  • Thermoplastic Elastomers
  • 11.9.1.
  • Polyurethane
  • 11.9.2.
  • Thermoplastic Polyolefins
  • 11.10.
  • Conclusion
  • 12.
  • Heart Valve Substitutes
  • 12.1.
  • 2.2.2.
  • Introduction: Valve Explants
  • 12.2.
  • Natural Heart Valves
  • 12.2.1.
  • Aortic Valve
  • 12.2.2.
  • Aortic Valve Substitutes
  • 12.3.
  • Soft Tissue Biomechanics
  • 12.4.
  • Cobalt-Chrome alloys
  • Blood-Material Interactions
  • 12.5.
  • Anticoagulants
  • 12.6.
  • Blood Flow Through the Heart Valves
  • 12.7.
  • Epilogue-Future
  • 13.
  • Tissue Engineering: Regenerative Medicine
  • 13.1.
  • 2.2.3.
  • It Has Been Described Before!
  • 13.2.
  • Basic Scheme of Tissue Engineering
  • 13.3.
  • Scaffolds
  • 13.3.1.
  • Materials
  • 13.3.2.
  • Porosity and Architecture
  • 13.3.3.
  • Titanium Alloys
  • Scaffold Surface Chemistry and Topography
  • 13.3.4.
  • Mechanical Properties
  • 13.3.5.
  • Degradation Kinetics
  • 13.3.6.
  • Fabricaton Techniques
  • 13.4.
  • Biomolecules and Cells
  • 13.4.1.
  • 2.3.
  • Biomolecules
  • 13.4.2.
  • Cells
  • 13.5.
  • Tissue Engineered Heart Valves
  • 13.6.
  • Vascular Grafts
  • 13.6.1.
  • Synthetic Vascular Grafts
  • 13.6.2.
  • Skeletal Tissue
  • Stents
  • 13.6.3.
  • Tissue Engineered Blood Vessels
  • 14.
  • Water
  • 14.1.
  • Origin of Life
  • 14.2.
  • Water Molecule
  • 14.3.
  • 2.3.1.
  • Conclusion
  • 15.
  • Closing Dinner Speech
  • A.
  • Physical Data
  • B.
  • Crystallographic Structures
  • B.1.
  • Crystal Systems
  • B.1.1.
  • Cartilage
  • Unit Cells
  • B.1.2.
  • Slip Planes
  • B.1.3.
  • Dislocations
  • B.1.4.
  • Diffusionless or Displacive Transformation
  • B.2.
  • Ceramics
  • C.
  • 2.4.
  • Electrochemical Series
  • C.1.
  • Equilibrium Electrochemical Series
  • C.2.
  • Pitting Potentials and Re-passivating Time
  • D.
  • Simulated Body Fluids
  • 1.
  • Total Hip Replacement Register
  • 2.5.
  • Homage to a Pioneer: Sir John Charnley
  • 3.
  • Corrosion
  • 3.1.
  • It Should not Have Happened
  • 3.2.
  • Water Does not Flow Uphill
  • 3.2.1.
  • Perfect Human Machine
  • Electrochemical Series
  • 3.2.2.
  • Pourbaix Diagram
  • 3.2.3.
  • Corrosion Rate
  • 3.2.4.
  • Styles in Corrosion
  • 3.3.
  • Does it All Fit the Practice of Implants?
  • 3.4.
  • 1.1.
  • Conclusion
  • 4.
  • Intoxicated by Implants?
  • 4.1.
  • Trace and Essential Trace Elements
  • 4.2.
  • Toxicity
  • 4.2.1.
  • Complex Formation
  • 4.2.2.
  • Biomaterials: Philosophical Background
  • Metallothionein
  • 4.2.3.
  • Multiple Interactions
  • 4.3.
  • Immunotoxicology
  • 4.4.
  • Gulliver and the Lilliputians
  • 4.5.
  • Sensitivity to Metal Implants
  • 4.5.1.
  • 1.2.
  • Stainless Steels
  • 4.5.2.
  • Cobalt-Chromium Alloys
  • 4.5.3.
  • Titanium Alloys
  • 4.6.
  • Wear Debris
  • 4.7.
  • And the Answer is?
  • 4.8.
  • Staying Alive Despite the Second Law
  • Postscriptum
  • 5.
  • Zirconium and Other Newcomers
  • 5.1.
  • Excellent But Just not Enough?
  • 5.2.
  • Zirconium, a Newcomer?
  • 5.3.
  • Tantalum and Niobium
  • 5.4.
  • 1.3.
  • Alloys with a Future?
  • 5.5.
  • Postscript
  • 6.
  • Long Bones
  • 6.1.
  • Plaster of Paris
  • 6.2.
  • Corollary Between Mineral and Biological Evolution: An Excursion in the Dark Ages
  • 6.3.
Dimensions
24 cm.
Extent
xvi, 340 p.
Isbn
9783642125317
Isbn Type
(alk. paper)
Lccn
2010938119
Other physical details
ill.
System control number
  • (CaMWU)u2462626-01umb_inst
  • 2498629
  • (Sirsi) i9783642125317
  • (OCoLC)700376019
Label
Biomaterials : a tantalus experience, Jozef A. Helsen, Yannis Missirlis
Publication
Bibliography note
Includes bibliographical references and index
Contents
  • Scaling of Plants and Animals
  • Thermoplastic Polymers
  • 6.4.
  • External Fixators
  • 6.5.
  • Exploring the Future
  • 6.6.
  • Osteosynthesis
  • 6.7.
  • G.A. Ilizarov
  • 7.
  • 1.4.
  • Layer by Layer
  • 7.1.
  • Computer-Aided Design
  • 7.2.
  • Electron Beam Melting
  • 7.3.
  • Selective Laser Melting of Metal Powder
  • 7.4.
  • Stereolithography of Polymers
  • 7.5.
  • Definitions
  • Characterization of Porous Structures
  • 7.6.
  • Conclusion
  • 8.
  • Metal Implants Bound to Disappear
  • 8.1.
  • Soluble Metals?
  • 8.2.
  • Prospecting for the Best
  • 8.3.
  • 2.
  • Hope?
  • 8.4.
  • Mg Foams
  • 8.5.
  • In Vitro and In Vivo
  • 8.6.
  • Conclusion
  • 9.
  • 7,000 Year Old Story: Ceramics
  • 9.1.
  • Failing Human Machine
  • Greek Pottery, a Useful Intermezzo?
  • 9.2.
  • Ceramics, Impossible to Define?
  • 9.3.
  • Ceramics
  • 9.3.1.
  • High Performance
  • 9.3.2.
  • Low Performance
  • 9.4.
  • 2.1.
  • Glass and Glass-Ceramics
  • 9.4.1.
  • Bioactive Glasses
  • 9.4.2.
  • Glass-Ceramics
  • 9.5.
  • Coatings
  • 9.6.
  • General Conclusion
  • 10.
  • Total Hip Replacement
  • Dental Materials
  • 10.1.
  • Difficulties to "Bridge"
  • 10.2.
  • Amalgam
  • 10.3.
  • Composite Alternatives
  • 10.3.1.
  • Adhesives
  • 10.3.2.
  • 2.2.
  • Restorative Composites
  • 10.4.
  • Orthodontics
  • 10.5.
  • Implants
  • 10.6.
  • Ceramics
  • 10.7.
  • Calcium Phosphates
  • 10.8.
  • Strength and Response to Load
  • Postscript
  • 11.
  • Perfect Prosthesis?
  • 11.1.
  • isoelastic Prosthesis
  • 11.2.
  • Polymers for Implants
  • 11.3.
  • Why is a Polymer Like PMMA Transparent to Visible Light?
  • 11.4.
  • 2.2.1.
  • Polyethyleneterephtalate
  • 11.5.
  • Polyamide
  • 11.6.
  • Was the Isoelastic Concept a Good Idea?
  • 11.7.
  • Heraclitus, 2500 Years Old and Still Alive
  • 11.8.
  • We Shall Overcome... Do We?
  • 11.9.
  • Machine generated contents note:
  • Stainless Steel
  • Thermoplastic Elastomers
  • 11.9.1.
  • Polyurethane
  • 11.9.2.
  • Thermoplastic Polyolefins
  • 11.10.
  • Conclusion
  • 12.
  • Heart Valve Substitutes
  • 12.1.
  • 2.2.2.
  • Introduction: Valve Explants
  • 12.2.
  • Natural Heart Valves
  • 12.2.1.
  • Aortic Valve
  • 12.2.2.
  • Aortic Valve Substitutes
  • 12.3.
  • Soft Tissue Biomechanics
  • 12.4.
  • Cobalt-Chrome alloys
  • Blood-Material Interactions
  • 12.5.
  • Anticoagulants
  • 12.6.
  • Blood Flow Through the Heart Valves
  • 12.7.
  • Epilogue-Future
  • 13.
  • Tissue Engineering: Regenerative Medicine
  • 13.1.
  • 2.2.3.
  • It Has Been Described Before!
  • 13.2.
  • Basic Scheme of Tissue Engineering
  • 13.3.
  • Scaffolds
  • 13.3.1.
  • Materials
  • 13.3.2.
  • Porosity and Architecture
  • 13.3.3.
  • Titanium Alloys
  • Scaffold Surface Chemistry and Topography
  • 13.3.4.
  • Mechanical Properties
  • 13.3.5.
  • Degradation Kinetics
  • 13.3.6.
  • Fabricaton Techniques
  • 13.4.
  • Biomolecules and Cells
  • 13.4.1.
  • 2.3.
  • Biomolecules
  • 13.4.2.
  • Cells
  • 13.5.
  • Tissue Engineered Heart Valves
  • 13.6.
  • Vascular Grafts
  • 13.6.1.
  • Synthetic Vascular Grafts
  • 13.6.2.
  • Skeletal Tissue
  • Stents
  • 13.6.3.
  • Tissue Engineered Blood Vessels
  • 14.
  • Water
  • 14.1.
  • Origin of Life
  • 14.2.
  • Water Molecule
  • 14.3.
  • 2.3.1.
  • Conclusion
  • 15.
  • Closing Dinner Speech
  • A.
  • Physical Data
  • B.
  • Crystallographic Structures
  • B.1.
  • Crystal Systems
  • B.1.1.
  • Cartilage
  • Unit Cells
  • B.1.2.
  • Slip Planes
  • B.1.3.
  • Dislocations
  • B.1.4.
  • Diffusionless or Displacive Transformation
  • B.2.
  • Ceramics
  • C.
  • 2.4.
  • Electrochemical Series
  • C.1.
  • Equilibrium Electrochemical Series
  • C.2.
  • Pitting Potentials and Re-passivating Time
  • D.
  • Simulated Body Fluids
  • 1.
  • Total Hip Replacement Register
  • 2.5.
  • Homage to a Pioneer: Sir John Charnley
  • 3.
  • Corrosion
  • 3.1.
  • It Should not Have Happened
  • 3.2.
  • Water Does not Flow Uphill
  • 3.2.1.
  • Perfect Human Machine
  • Electrochemical Series
  • 3.2.2.
  • Pourbaix Diagram
  • 3.2.3.
  • Corrosion Rate
  • 3.2.4.
  • Styles in Corrosion
  • 3.3.
  • Does it All Fit the Practice of Implants?
  • 3.4.
  • 1.1.
  • Conclusion
  • 4.
  • Intoxicated by Implants?
  • 4.1.
  • Trace and Essential Trace Elements
  • 4.2.
  • Toxicity
  • 4.2.1.
  • Complex Formation
  • 4.2.2.
  • Biomaterials: Philosophical Background
  • Metallothionein
  • 4.2.3.
  • Multiple Interactions
  • 4.3.
  • Immunotoxicology
  • 4.4.
  • Gulliver and the Lilliputians
  • 4.5.
  • Sensitivity to Metal Implants
  • 4.5.1.
  • 1.2.
  • Stainless Steels
  • 4.5.2.
  • Cobalt-Chromium Alloys
  • 4.5.3.
  • Titanium Alloys
  • 4.6.
  • Wear Debris
  • 4.7.
  • And the Answer is?
  • 4.8.
  • Staying Alive Despite the Second Law
  • Postscriptum
  • 5.
  • Zirconium and Other Newcomers
  • 5.1.
  • Excellent But Just not Enough?
  • 5.2.
  • Zirconium, a Newcomer?
  • 5.3.
  • Tantalum and Niobium
  • 5.4.
  • 1.3.
  • Alloys with a Future?
  • 5.5.
  • Postscript
  • 6.
  • Long Bones
  • 6.1.
  • Plaster of Paris
  • 6.2.
  • Corollary Between Mineral and Biological Evolution: An Excursion in the Dark Ages
  • 6.3.
Dimensions
24 cm.
Extent
xvi, 340 p.
Isbn
9783642125317
Isbn Type
(alk. paper)
Lccn
2010938119
Other physical details
ill.
System control number
  • (CaMWU)u2462626-01umb_inst
  • 2498629
  • (Sirsi) i9783642125317
  • (OCoLC)700376019

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