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001			EBC3017996
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005			20240729124051.0
006			m o d |
007			cr cnu||||||||
008			240724s2010 xx o ||||0 eng d
020			_a9781612098623 _q(electronic bk.)
020			_z9781608764761
035			_a(MiAaPQ)EBC3017996
035			_a(Au-PeEL)EBL3017996
035			_a(CaPaEBR)ebr10658918
035			_a(OCoLC)923654672
040			_aMiAaPQ _beng _erda _epn _cMiAaPQ _dMiAaPQ
050		4	_aR857.M3 -- B477 2010eb
082	0		_a610.284
100	1		_aBourg, Henri.
245	1	0	_aBiomaterials Developments and Applications.
250			_a1st ed.
264		1	_aHauppauge : _bNova Science Publishers, Incorporated, _c2010.
264		4	_c©2010.
300			_a1 online resource (511 pages)
336			_atext _btxt _2rdacontent
337			_acomputer _bc _2rdamedia
338			_aonline resource _bcr _2rdacarrier
490	1		_aAdvances in Biology and Medicine
505	0		_aIntro -- BIOMATERIALS DEVELOPMENTS AND APPLICATIONS -- BIOMATERIALS DEVELOPMENTS AND APPLICATIONS -- CONTENTS -- PREFACE -- Chapter 1 CALCIUM ORTHOPHOSPHATE-BASED BIOCOMPOSITES AND HYBRID BIOMATERIALS -- ABSTRACT -- INTRODUCTION -- GENERAL INFORMATION ON COMPOSITES AND BIOCOMPOSITES -- THE MAJOR CONSTITUENT MATERIALS OF BIOCOMPOSITES FOR BIOMEDICAL APPLICATIONS -- 3.1. Calcium Orthophosphates -- 3.2. Polymers -- 3.3. Inorganic Materials and Compounds (Metals, Ceramics, Glass, Oxides, Carbon, Etc.) -- CALCIUM ORTHOPHOSPHATE-BASED BIOCOMPOSITES AND HYBRID BIOMATERIALS -- 4.1. Biocomposites with Polymers -- Apatite-Based Biocomposites -- TCP-Based Biocomposites -- Other Calcium Orthophosphate-Based Biocomposites -- 4.2. Calcium Orthophosphate Cement-Based Biocomposites and Concretes -- 4.3. Nano-Calcium Orthophosphate-Based Biocomposites and Nano-Biocomposites -- 4.4. Biocomposites with Collagen -- 4.5. Biocomposites with Other Bioorganic Compounds and Biological Macromolecules -- 4.6. Injectable Bone Substitutes (IBS) -- 4.7. Biocomposites with Glasses, Inorganic Materials and Metals -- 4.8. Functionally Graded Biocomposites -- 4.9. Biosensors -- INTERACTION BETWEEN THE PHASES IN CALCIUM ORTHOPHOSPHATE-BASED BIOCOMPOSITES -- BIOACTIVITY AND BIODEGRADATION OF CALCIUM ORTHOPHOSPHATE-BASED BIOCOMPOSITES -- SOME CHALLENGES AND CRITICAL ISSUES -- CONCLUSIONS -- REFERENCES -- NOMENCLATURE -- Chapter 2 CALCIUM ORTHOPHOSPHATE CEMENTS AND CONCRETES -- ABSTRACT -- 1. INTRODUCTION -- 2. CALCIUM ORTHOPHOSPHATE CEMENTS -- 3. TWO MAJOR TYPES OF CALCIUM ORTHOPHOSPHATE CEMENTS -- 3.1. Apatite Cements -- 3.2. Brushite Cements -- 4. VARIOUS PROPERTIES OF CALCIUM ORTHOPHOSPHATE CEMENTS -- 5. BIORESORPTION AND REPLACEMENT OF THE CEMENTS BY BONES -- 6. THE MECHANICAL PROPERTIES -- 7. REINFORCED CALCIUM ORTHOPHOSPHATE CEMENT COMPOSITES AND CONCRETES.
505	8		_a8. CLINICAL AND MEDICAL APPLICATIONS -- 8.1. Dental Applications -- 8.2. Craniofacial and Maxillofacial Applications -- 8.3. Orthopedic Applications -- 8.4. Vertebroplasty and Kyphoplasty Applications -- 8.5. Drug Delivery Applications -- 8.6. Brief Conclusions on the Medical Applications -- 9. FUTURE DEVELOPMENTS -- 10. CONCLUSIONS -- REFERENCES -- Chapter 3 HYDROGELS IN BIOLOGY AND MEDICINE -- ABSTRACT -- 1. INTRODUCTION -- 2. STRUCTURE OF HYDROGELS IN RELATION TO THE FORMATION CONDITIONS -- 2.1. General Features of Network Build-Up -- 2.2. Physical Polymer Hydrogels -- 2.3. Inter- and Intramolecular Crosslinking -- 2.4. Ways of Formation of Polymer Hydrogels -- 2.5. Special Features of Polymerization in Presence of Diluents. Phase Separation - Macrosyneresis vs. Microsyneresis -- 3. SWELLING AND MECHANICAL PROPERTIES OF HYDROGELS -- 3.1. Swelling Properties of Hydrogels -- 3.1.1. Equilibrium swelling -- Role of the interaction parameter -- Effect of degree of crosslinking -- Effect of dilution during network formation -- Swelling in Solvent vapors -- Effect of charged groups -- Swelling transitions - two crosslinked phases -- Multicomponent systems -- Condition for phase separation during network formation -- 3.1.2. Swelling under confined conditions -- 3.1.3. Other Important Issues -- 3.2. Mechanical Properties of Hydrogels -- 4. CONTACT LENSES -- 5. INTRAOCULAR LENSES -- 6. FUNCTIONAL IMPLANTS -- Hydrogels for Urinary Incontinence Treatment -- 7. BLOOD VESSEL EMBOLIZATION -- 8. WOUND DRESSINGS -- 8.1. Hydrogels Containing Radical Scavengers -- 8.2. Hydrogels as Cultivation Supports -- 9. CONDUCTIVE HYDROGELS FOR BIOMEDICAL USE -- 10. HYDROGELS IN TISSUE ENGINEERING -- REFERENCES -- Chapter 4 BIOMATERIALS IN DENTISTRY AND MEDICINE -- ABSTRACT -- INTRODUCTION -- CLINICAL APPROACHES -- Reparative Reconstructive Surgery.
505	8		_aa. Biomaterials in reparative reconstructive surgery -- b. Factors governing the clinical performance of implantable biomaterials -- c. Approaches to improving device performance in reconstructive surgery -- Regenerative Medicine -- In vivo Tissue Regeneration -- a. Biocompatible, resorbable materials for in vivo tissue regenerative scaffolds -- b. Scaffold morphology -- c. Approaches to scaffold manufacture -- d. Scaffold functional requirements -- In vitro Tissue Regeneration -- CHALLENGES AND OPPORTUNITIES -- REFERENCES -- Chapter 5 BIOMATERIALS IN BLOOD-CONTACTING DEVICES: COMPLICATIONS AND SOLUTIONS -- ABSTRACT -- 1. INTRODUCTION -- 2. BLOOD COMPONENTS INVOLVED IN HEMOSTASIS AND THROMBOSIS -- 2.1. Platelets -- 2.2. Fibrinogen and von Willebrand Factor -- 2.3. Clotting Factors and Coagulation -- 2.4. Blood Flow -- 2.5. Fibrinolysis -- 3. BLOOD-CONTACTING DEVICES AND MATERIALS -- 3.1. Polyurethane (PU) and Polyether Urethane (PEU) -- 3.2. Polyethylene (PE) and Polypropylene (PP) -- 3.3. Silicone Rubbers -- 3.4. Polytetrafluoroethylene (PTFE), Fluorinated Ethylene-Propylene (FEP), and Poly(Ethylene Terephthalate) (PET) -- 3.5. Polyvinyl Chloride (PVC) -- 4. BLOOD-MATERIALS INTERACTIONS -- 5. SURFACE MODIFICATION FOR IMPROVING BLOOD COMPATIBILITY -- 5.1. Heparin -- 5.2. Hydrophilic Surfaces -- 5.3. Phosphorylcholine-Based Polymers -- 5.4. Zwitterionic Surfaces -- 5.5. Clot-Dissolving Surfaces -- 6.CONCLUSION -- REFERENCE -- Chapter 6 BIOCOMPATIBILITY OF DENTAL AND MEDICAL MATERIALS -- ABSTRACT -- INTRODUCTION -- BIOMATERIALS IN DENTISTRY AND MEDICINE -- Metallic Biomaterials -- Bioceramics -- Polymers -- Dental Materials -- Concluding Remarks -- REFERENCES -- Chapter 7 ENHANCING REMINERALIZATION OF SUBSURFACE ENAMEL LESIONS WITH FUNCTIONALIZED -TCP -- ABSTRACT -- 1. INTRODUCTION -- 2. MATERIALS AND METHODS -- 2.1. fTCP Preparation.
505	8		_a2.2. Fluoride Bioavailability -- 2.3. Specimen Preparation and White-Spot Lesion Formation -- 2.4. In Vitro pH Cycling Model for Remineralization Efficacy -- 2.5. Specimen Remineralization: Surface and Profile Microhardness -- 2.6. Fluoride Uptake: pH Cycling and Single Treatment Exposure -- 2.7. Statistics -- 3. RESULTS -- 3.1. Fluoride Bioavailability -- 3.2. In vitro Remineralization via pH Cycling: 500 ppm F -- 3.3. In Vitro Remineralization via pH Cycling: 950 and 5000 ppm F -- 3.4. In Vitro Fluoride Uptake: 500, 950 and 5000 ppm F -- 4. DISCUSSION -- 5. CONCLUSION -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 8 TRANSLATION OF EMERGING HYDROGEL THERAPIES: THE ROLE OF METROLOGY -- ABSTRACT -- INTRODUCTION -- HYDROGEL FUNCTION -- Stimuli Sensitive Hydrogels -- Self-Assembling Hydrogels -- Molecule Selective Hydrogels -- THERAPY TRANSLATION -- METROLOGY NEEDS FOR PRODUCT TRANSLATION -- Attributes Affecting Safety &amp -- Effectiveness -- Protocols to Assess Safety and Effectiveness -- Sterility -- Toxicity -- Immune response -- Bioactive agent release -- Mechanical properties -- Osmotic stability -- Cell motility -- Setting time -- Degradation -- CONCLUSION -- REFERENCES -- Chapter 9 METAL ION RELEASE FROM THE BASE CO▪CR▪MO, NI▪CR, AND NOBLE AU▪PT DENTAL ALLOY INTO THE BUFFERED SOLUTIONS OF DIFFERENT COMPOSITION AND PH VALUE -- ABSTRACT -- 1. INTRODUCTION -- 2. OBJECTIVES -- 3. MATERIALS AND METHODS -- 3. 1. Clean Laboratory -- 3. 2. Chemicals -- 3. 3. Glassware Washing -- 3. 4. Dental Alloy -- 3. 5. Immersion (Extraction) Solutions -- 3. 6. Metal Soaking -- 3. 7. Metal Analysis -- 3. 8. Reagent Blanks -- 3. 9. Detection Limits -- 3.10. Statistics -- 4. RESULTS -- 4.1. Noble Au▪Pt Alloy -- 4.2. Base Alloys: Co▪Cr▪Mo and Ni▪Cr -- 5. DISCUSSION -- 6. CONCLUSION -- REFERENCES.
505	8		_aChapter 10 CO-CR-MO ALLOY SURFACE FEATURES AND COMPOSITION PRIOR AND AFTER MECHANICAL POLISHING AND CORROSION IN FLUIDS SIMULATING ORAL CONDITIONS -- ABSTRACT -- INTRODUCTION -- MATERIALS AND METHODS -- Sample Casting -- Polishing Procedure -- Sample Cleaning Prior to AFM Analysis -- AFM Analysis -- SEM Analysis -- Immersion (Extraction) Solutions -- Alloy Soaking -- Statistical Analysis -- RESULTS -- Typical CoCrMo Surface -- Effect of Polishing -- Effect of Immersion in Saliva and Plaque Solutions -- DISCUSSION -- ACKNOWLEDGMENT -- REFERENCES -- Chapter 11 INTRACELLULAR DELIVERY OF GOLD NANOPARTICLES: APPLICATIONS IN NANOMEDICINE -- ABSTRACT -- INTRODUCTION -- Synthesis of AuNPs -- Protein Mediated Delivery -- Peptide Mediated Delivery -- Small Molecule Mediated Delivery -- Conclusion and Future Outlook -- REFERENCES -- Chapter 12 A COMMENTARY ON NEURAL TISSUE ENGINEERING IN THE CENTRAL NERVOUS SYSTEM - INTERFACING A LESION -- ABSTRACT -- INTRODUCTION -- INFLAMMATION -- THE FORMATION OF THE ECM WITHIN THE CNS AND ROLE FOLLOWING CNS INJURY -- FEATURES AND CHALLENGES OF SCAFFOLDS FOR CNS REGENERATION -- CURRENT SCAFFOLD DESIGN -- PERSPECTIVE -- CONCLUSION -- REFERENCES -- INDEX.
588			_aDescription based on publisher supplied metadata and other sources.
590			_aElectronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
650		0	_aBiomedical materials.
650		0	_aBiomedical engineering.
655		4	_aElectronic books.
700	1		_aLisle, Amaury.
776	0	8	_iPrint version: _aBourg, Henri _tBiomaterials Developments and Applications _dHauppauge : Nova Science Publishers, Incorporated,c2010 _z9781608764761
797	2		_aProQuest (Firm)
830		0	_aAdvances in Biology and Medicine
856	4	0	_uhttps://ebookcentral.proquest.com/lib/orpp/detail.action?docID=3017996 _zClick to View
999			_c59384 _d59384