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ویرایش: [4 ed.] نویسندگان: William Wagner, Shelly Sakiyama Elbert, Guigen Zhang, Michael Yaszemski. سری: ISBN (شابک) : 9780128161371 ناشر: سال نشر: تعداد صفحات: pages cm [1543] زبان: English فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود) حجم فایل: 49 Mb
در صورت تبدیل فایل کتاب Biomaterials science: an introduction to materials in medicine به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب علم بیومواد: مقدمه ای بر مواد در پزشکی نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
علم زیست مواد: مقدمهای بر مواد در پزشکی، ویرایش چهارم، جامعترین متن در مورد علم زیست مواد، از اصول تا کاربردها است. این یک رویکرد متوازن و روشنگر برای یادگیری علم و فناوری بیومواد ارائه می دهد و به عنوان یک مرجع کلیدی برای پزشکان درگیر در کاربرد مواد در پزشکی عمل می کند. در این نسخه جدید، بهروزرسانیهای کلیدی برای منعکس کردن آخرین تحقیقات مرتبط در این زمینه، به ویژه در کاربردهای نانوتکنولوژی، کاشت رباتیک، و مواد زیستی مورد استفاده در تشخیص و درمان سرطان وجود دارد. سایر موارد اضافه شده عبارتند از مهندسی بازسازی، چاپ سه بعدی، پزشکی شخصی و اعضای بدن بر روی یک تراشه. بر اساس بازخورد مشتریان، نسخه جدید همچنین دارای ترکیبی از مواد اضافی برای اطمینان از وضوح و تمرکز است. در صورت لزوم، تمرینات پایان فصل با راه حل های آنلاین موجود گنجانده شده است.
Biomaterials Science: An Introduction to Materials in Medicine, Fourth Edition, is the most comprehensive text on biomaterials science, from principles to applications. It provides a balanced, insightful approach to both the learning of the science and technology of biomaterials, acting as a key reference for practitioners involved in the applications of materials in medicine. In this new edition, there are key updates to reflect the latest relevant research in the field, particularly in applications in nanotechnology, robotic implantation, and biomaterials utilized in cancer research detection and therapy. Other additions include regenerative engineering, 3D printing, personalized medicine and organs on a chip. Based on customer feedback, the new edition also features a consolidation of redundant material to ensure clarity and focus. Where appropriate, end-of-chapter exercises have been included with online solutions available.
Biomaterials Science Copyright List of Contributors Preface How to Use this Book 1.1.1 - Introduction to Biomaterials Science: An Evolving, Multidisciplinary Endeavor Biomaterials and Biomaterials Science Key Definitions The Expansion of the Biomaterials Field Examples of Today’s Biomaterials Applications Heart Valve Prostheses Total Hip Replacement Prostheses Dental Implants Intraocular Lenses Ventricular Assist Devices Characteristics of Biomaterials Science Multidisciplinary Diverse Materials Are Used Biomaterials to Devices to Markets and Medicine Magnitude of the Field Success and Failure Subjects Integral to Biomaterials Science Toxicology Biocompatibility Inflammation and Healing Functional Tissue Structure and Pathobiology Dependence on Specific Anatomical Sites of Implantation Mechanical Requirements and Physical Performance Requirements Industrial Involvement Risk/Benefit and Corporate Realities Ethics Regulation Biomaterials Literature Biomaterials Societies Summary 1.1.2 - A History of Biomaterials Biomaterials Before World War II Before Civilization Dental Implants in Early Civilizations Sutures Dating Back Thousands of Years Artificial Hearts and Organ Perfusion Contact Lenses Basic Concepts of Biocompatibility World War II to the Modern Era: The Surgeon/Physician-Hero Intraocular Lenses Hip and Knee Prostheses Dental Implants The Artificial Kidney The Artificial Heart Breast Implants Vascular Grafts Stents Pacemakers Heart Valves Pyrolytic Carbon Drug Delivery and Controlled Release Designed Biomaterials Silicones Polyurethanes Teflon Hydrogels Poly(Ethylene Glycol) Poly(Lactic-Glycolic Acid) Hydroxyapatite Titanium Bioglass The Contemporary Era (Modern Biology and Modern Materials) Conclusions 1.2.1 - Introduction: Properties of Materials—the Palette of the Biomaterials Engineer 1.2.2 - The Nature of Matter and Materials Introduction Atoms and Molecules Molecular Assemblies Surfaces Conclusion 1.2.3 - Bulk Properties of Materials Introduction Mechanical Variables and Mechanical Properties Five Types of Mechanical Loading From External Loads to Internal Loads and Stresses Linear and Nonlinear Relationship, Elastic and Plastic Behavior Pseudoelastic, Hyperelastic, and Viscoelastic Materials Common Mechanical Properties of Isotropic Materials Elastic Properties Yield Strength and Ductility Strength and Failure Hardness Resilience Toughness Fracture Toughness and Fatigue Strength Generalized Hooke's Law and Anisotropy of Materials Loading Modes, Stress States, and Mohr's Circle Plane-Stress and Plane-Strain Simplification Trajectories of Tensile and Compressive Stress Lines Other Bulk Properties Thermal Properties Optical Properties Piezoelectric Properties Electrochemical Properties Chapter Questions Solution Solution Solution Solution Solution Solution Solution Solution Solution 1.2.4 - Surface Properties and Surface Characterization of Biomaterials Introduction General Surface Considerations and Definitions What Surface Properties Are We Interested in? Surface Analysis Techniques: Principles and Methods Sample Preparation Surface Analysis General Comments Contact Angle Methods Electron Spectroscopy for Chemical Analysis Secondary Ion Mass Spectrometry Scanning Electron Microscopy Infrared Spectroscopy Scanning Tunneling Microscopy (STM), Atomic Force Microscopy (AFM), and the Scanning Probe Microscopies (SPMs) Newer Methods Studies With Surface Methods Platelet Consumption and Surface Composition Contact-Angle Correlations Contamination of Intraocular Lenses Titanium SIMS for Adsorbed Protein Identification and Quantification Poly(Glycolic Acid) Degradation Studied by SIMS MultiTechnique Characterization of Adsorbed Peptides and Proteins Conclusions Chapter Questions 1.2.5 - Role of Water in Biomaterials Water: The Special Molecule Melting Point and Boiling Point Density and Surface Tension Specific Heat and Latent Heats of Fusion and Evaporation Water as a Solvent Water: Structure Water: Significance for Biomaterials Hydrophobic Effect, Liposomes, and Micelles Hydrogels Protein Adsorption Life Chapter Exercises Suggested External Reading 1.3.1 - The Materials Side of the Biomaterials Relationship 1.3.2 - Polymers: Basic Principles Introduction The Polymer Molecule Molecular Structure of Single Polymer Molecules Chemical Structure of Single Polymer Molecules Copolymers Determination of Chemical Composition Tacticity Molecular Mass The Molecular Mass Distribution and Its Averages Characterizing the Molecular Mass Distribution Connecting Physical Behavior With Chemical Characteristics Physical States of Linear Polymers The Rubbery State The Glassy State The Semicrystalline State The Physical Behavior of Linear and Amorphous Polymers The Physical Behavior of Other Physical States Characterizing a Polymer's Physical State and Behavior Measuring the Transition Temperatures Between States Interactions With Water Measuring the Hydrophilicity of Polymer Materials Degradation Characteristics Polymer Synthesis Polymerization Mechanisms Using Synthesis Conditions to Build the Desired Polymer Case Studies The Present and the Future Further Reading 1.3.2A - Polyurethanes Introduction Anatomy of a Polyurethane Molecule The Physical Properties of Polyurethanes Thermosets Thermoplastic Elastomers Polyurethane Synthesis Precursors Synthesis Reactions Tailoring Polyurethane Behavior Concluding Remarks Chapter Exercises 1.3.2B - Silicones Chemical Structure and Nomenclature Preparation Silicone Polymers Polymerization and Polycondensation Physicochemical Properties Types, Properties, and Preparation of Silicone Materials Silicone Elastomers Elastomer Filler Processing of Silicone Elastomers Silicone Gels Silicone Adhesives Silicone Film-in-Place, Fast-Cure Elastomers Biocompatibility of Silicones Biodurability of Silicones Medical Applications Siliconization Extracorporeal Equipment Medical Inserts and Implants Catheters, Drains, and Shunts Aesthetic Implants Conclusion Chapter Questions Chapter Answers Question 1 Question 2 Question 3 Question 4 Question 5 Question 6 Question 7 1.3.2C. - Fluorinated Biomaterials Introduction Distinguishing the Different Fluoropolymers Polytetrafluoroethylene Fluorinated Ethylene Propylene Polyvinylidene Fluoride Fluoropolymer Melt Processing Original Gore-Tex and Generic Equivalents Surfaces Modified by Fluorination Treatments (Grainger and Stewart, 2001) Biomedical Applications Fluorinated Material Biological Response PTFE (Teflon) Mesh and Fabric Vascular Implants ePTFE and Teflon Soft Tissue Repair Meshes ePTFE Vascular Implants Arteriovenous ePTFE Grafts for Dialysis Access Multilumen Catheters Guiding Catheters PTFE Catheter Introducers Perfluorocarbon Liquids and Emulsions as Oxygen-Carrying Blood Substitutes Fluorinated Liquids in the Eye as Experimental Vitreous Substitutes Fluorinated (Meth)Acrylates and (Meth)Acrylated Perfluoroalkyl Silicones as Cross-Linked Polymer Cores for Soft Contact Lenses Fluorinated Materials as Antifouling Coatings for Intraocular Lenses PTFE Paste Injectable Bulking Agent Ligament Replacement Sutures Summary Glossary References Chapter Exercises 1.3.2D - The Organic Matrix of Restorative Composites and Adhesives Introduction—Historical Perspective The Monomer Matrix—Conventional Systems Dimethacrylates (Base and Diluent Monomers) Used in Commercial Composites Adhesive Monomers The Monomer Matrix—Novel Systems Lower Stress Resin Systems Low-Shrinkage Materials Network Modulation Fast Polymerizing Monomers Antimicrobial Resins Enhanced Chemical Stability Enhanced Toughness Hydrophobic Resins Silane Coupling Agents Chapter Exercises 1.3.2E - Hydrogels Introduction Classification and Basic Structures of Hydrogels Synthesis of Hydrogels Swelling Behavior of Hydrogels Determination of Structural Characteristics Biomedical Hydrogels Acrylic Hydrogels Poly(Vinyl Alcohol) (PVA) Hydrogels Poly(Ethylene Glycol) (PEG) Hydrogels Degradable Hydrogels Star Polymer and Dendrimer Hydrogels Self-Assembled Hydrogel Structures “Smart” or “Intelligent,” Stimuli-Responsive Hydrogels and Their Applications pH-Sensitive Hydrogels pH-Responsive Complexation Hydrogels Temperature-Sensitive Hydrogels Affinity Hydrogels Biomedical Applications of Hydrogels Contact Lenses Blood-Contacting Hydrogels Drug Delivery From Hydrogels Targeted Drug Delivery From Hydrogels Tissue Engineering Scaffolds From Hydrogels Miscellaneous Biomedical Applications of Hydrogels 1.3.2F - Degradable and Resorbable Polymers Introduction Brief History of Degradable Polymers Definition of Degradation, Erosion, Bulk, and Surface Processes Degradable Polymer Properties Polymer Backbone Functionality Polyanhydrides Poly(Ortho Esters) Polyesters and Polycarbonates Polymer Architecture Polymerization Routes Molecular Weight Morphology Relative Hydrophobicity versus Hydrophilicity Degradation Routes and Kinetics Hydrolytic Degradation Surface Erosion Bulk Degradation Photodegradation Enzymatic Degradation Polymer Design and Processing Lifetime—How Long Does the Biomaterial Need to Function? Location—Where Will the Biomaterial Perform Its Task? Mechanical Properties—What Mechanical Properties Are Required for the Task? Delivery—How Will the Biomaterial Reach the Required Site? Composites—When Should a Composite Be Used and How Will Additives Affect Degradation? Shape—How Will the Material Be Shaped and How Does Shape Affect Degradation Kinetics? Sterilization—Will Degradation Properties Be the Same After Sterilization? Performance Metrics Worked Examples Question Solution Question Solution Question Solution Case Studies on Degradable Polymers Used in Medicine Chapter Exercises 1.3.2G - Applications of “Smart Polymers” as Biomaterials Introduction Smart Polymers in Solution Smart Polymer–Protein Bioconjugates Site-Specific Smart Polymer Bioconjugates Smart Polymers on Surfaces Smart Polymer Hydrogels Stimuli-Responsive Polymer Micelles and Carriers Conclusions References 1.3.3 - Metals: Basic Principles Introduction Medical Devices and Metals in the Body The Major Alloy Systems (Ti, NiTi, CoCrMo, SS, Pt, Au, Mg, Ag) Metal Processing Processing–Structure–Properties–Performance Paradigm Structure of Metals and Alloys Electronic and Atomic Structure: Crystal Structures Alloying, Microstructure, and Phase Diagrams Defects in Crystals Point Defects Line Defects Area Defects Volume Defects Bulk Mechanical Properties of Metallic Biomaterials Elastic and Plastic Deformation of Metals Strength of Metals and Strengthening Mechanisms Strengthening Mechanisms: Alloying Strengthening Mechanisms: Cold Working Strengthening Mechanisms: Grain Size Strengthening Mechanisms: Precipitation Strengthening Fracture of Metals Fatigue of Metals Surfaces of Metals: Oxide Films and Passivity High-Field, Low-Temperature Oxide Film Growth Introduction to Metallic Corrosion Electrochemical Reactions (Oxidation and Reduction) and the Nernst Equation The Principal Reduction Reaction in Biomaterials (Oxygen Reduction) Polarizable and Nonpolarizable Electrodes Pourbaix Diagrams (Electrode Potentials vs. pH) Electrochemical Currents (Evans Diagrams) Electrochemical Impedance Spectroscopy (an Introduction) Resistive (Faradaic) and Capacitive (Non-Faradaic) Behavior Basic Impedance Concepts Semiconducting Oxide Impedance (Mott–Schottky Analysis) References Questions 1.3.3A - Titanium Alloys, Including Nitinol Introduction Biocompatibility Biocompatible Titanium Alloys Recent Efforts in Fabrication Processes Mechanical Properties of Titanium Alloys Elastic Modulus Wear Resistance Fatigue Behavior Effects of Interstitial Atoms on Mechanical Properties Surface Modification of Titanium Alloys Recent Efforts in the Anodization Process Effects of Anodization on Corrosion and Surface Mechanical Properties Coloring Methods for Titanium Alloys Conclusions Chapter Exercise 1 Chapter Exercise 2 Chapter Exercise 3 1.3.3B - Stainless Steels Overview History Composition and Types Structure Structure, Composition, and Processing Effects on Mechanical Properties Corrosion Summary 1.3.3C - CoCr Alloys Introduction Microstructure, Mechanical Properties, and Manufacturing of CoCr Alloys 3D Printing of CoCr Alloys Bio-Tribocorrosion of CoCr Alloys Application of CoCr Alloys in Biomedical Devices Properties Leading to Biocompatibility of CoCr Alloys and Their Applications Corrosion Resistance CoCr Alloys in Biological Environments Clinical Concerns Related to Metal Ion Release From CoCr Alloys Conclusions Questions 1.3.3D - Biodegradable Metals Introduction General Considerations of Corrosion Design of Biodegradable Metals General Ideas on the Influence of Alloying Elements, Corrosion Behavior, and the Biocompatibility of Zn and Mg Iron-Based Biodegradable Metals Introduction to Fe-Based Implants Modifications to Accelerate the Corrosion Rate of Fe-Based Biodegradable Metals The Proposed Degradation Process of Fe-Based Biodegradable Metals Biocompatibility Evaluations Current Perspective on Fe-Based Degradable Implants Zinc-Based Biodegradable Metals Introduction to Zn-Based Implants Zn-Based Materials Under Investigation The Proposed Degradation Process of Zn-Based Biodegradable Metals Biocompatibility of Dissolved Zn Corrosion Products Current Perspective on Zn-Based Degradable Implants Magnesium-Based Biodegradable Metals Introduction to Mg-Based Implants Impact of Alloying Elements on Mg Processing and Microstructure Current Models of the Corrosion Process In Vitro Situation In Vivo: Tissue Perfusion, pH, and the Issue of Gas Formation Methods to Measure Mg-Based Implant Corrosion In Vitro and In Vivo Preclinical and Clinical Observations for Mg-Based Biodegradable Metals Orthopedic Devices Based on MgYREZr Alloy (Magnezix) Orthopedic Devices Based on MgCaZn Alloy (Resomet) Orthopedic Devices Based on Pure Mg Current Perspective on Mg-Based Degradable Implants Summary Acknowledgment References 1.3.4 - Ceramics, Glasses, and Glass-Ceramics: Basic Principles Introduction Nearly-Bioinert Ceramics Alumina and Zirconia Ceramics Bioactive Ceramics and Glasses Bioactive Ceramics Porous Calcium Phosphate Ceramics Calcium Phosphate Cements Bioglass and Bioactive Glass Bioglass Granules Bioactive Glass Composites and Putties for Bone Repair Porous Bioactive Glasses Wound Healing Bioactive Glass in Toothpaste Glasses for Cancer Therapy Glass-Ceramics Summary Chapter Questions Questions with answers 1.3.4A - Natural and Synthetic Hydroxyapatites Introduction Synthesis of Hydroxyapatite Ceramics Characterization of Hydroxyapatite Ceramics Physicochemical Characterization In Vitro and In Vivo Characterization Clinical Use of Hydroxyapatite Ceramics 1.3.4B - Structural Ceramic Oxides Introduction Structural Ceramic Oxides Aluminum Oxide (Alumina) Zirconia Yttria and Magnesia-Stabilized Zirconias Zirconia-Toughened Alumina A History of These Structural Materials in Medical Devices Properties in General Questions 1.3.5 - Carbon Biomaterials Introduction Carbon Biomaterials Diamond and Diamond-Like Carbon Diamond Diamond-Like Carbon Pyrolytic Carbon Hexagonally Bonded Carbon Graphite Fullerenes Carbon Nanotubes Graphene-Based Materials Other Hexagonally Bonded Carbons .Graphene quantum dots (GQD) are 0D materials (2–20nm) with a crystalline form of carbon containing sp2 hybridized atoms. These ... .Carbon fibers (CF) are a 3D material (diameter: 5–10μm) with a crystalline form of carbon containing sp2 hybridized atoms. Thes... .Carbon nanofibers (CNF) are noncontinuous 1D materials with a crystalline form of carbon containing sp2 hybridized atoms. CNF c... .Graphene nanoribbons (GNR) are 1D materials with a crystalline form of carbon containing sp2 hybridized atoms. GNR are commonly... Other Carbon Biomaterials Carbon Dots Glassy Carbon Activated Charcoal Biomedical Applications of Carbon Biomaterials Drug Delivery Phototherapy and Imaging Biosensors Antimicrobial Therapy Cardiovascular Applications Long-Term Implants Mechanical Heart Valves Vascular Stents Ventricular Assist Devices Tissue-Engineering Approaches Orthopedic Applications Long-Term Implants Tissue-Engineering Approaches Dental Applications Neurological Applications Ophthalmologic Applications Contact Lenses Catheters Guidewires Other Biomedical Applications Safety of Carbon Biomaterials: Short Considerations Summary Chapter Questions and Answers 1.3.6 - Natural Materials Introduction to Natural Materials Natural Based-Biomaterials Exploring Structural Molecules Extracellular Matrix-Based Biomaterials Proteins Glycosaminoglycans Blood Derivatives as a Source of Bioinstructive Materials Multifunctional Biomaterials Based on DNA Dynamic Hydrogels Exploring Supramolecular Chemistry Reversible Hydrogels Based on Supramolecular Cross-Linking of Polymeric Precursors Hydrogels Based on Natural Supramolecular Self-Assembly Soft Nanocomposite Smart Materials Stimuli-Responsive Soft Nanocomposites Future Perspectives Questions 1.3.6A - Processed Tissues Introduction Cryopreservation and Vitrification Tissue Cross-Linking Decellularization Decellularization Methods Quality of Decellularization Post-decellularization Processing and Modifications Milling for ECM Powder and Partial Enzymatic Digestion for Hydrogel Formation Cross-Linking Applications of Decellularized ECM Scaffold-Based Therapies Whole Organ Recellularization Powder and Injectable Decellularized ECM Therapies Tissue-Specific In Vitro Models of the Native Microenvironment Current Challenges and Future Directions for Decellularized Tissues Conclusion Acknowledgments Questions 1.3.6B - Use of Extracellular Matrix Proteins and Natural Materials in Bioengineering Introduction Collagens Elastin, Elastic Fibers, and Elastin-Like Peptides Proteoglycans and Glycosaminoglycans Alginates Chitosan Fibrin Manufacturing Approaches Utilizing Natural Materials Human Recombinant ECM Protein Production Purification of Recombinant ECM Proteins 3D Bioprinting Electrospinning of ECM Proteins and Natural Materials Summary 1.3.7 - Composites Introduction Matrix and Reinforcement in Composites Matrix Materials Reinforcements Nonporous and Porous Composites Properties of Composites Major Influencing Factors Geometry and Size of the Dispersed Phase and Its Distribution in Composite Fiber Arrangement Interfaces in Composites Mechanical Properties of Composites Tensile Properties of Fibrous Composites Compressive Properties of Fibrous (CF/PEEK) Composites: A New Perspective Rosen’s Microbuckling Model and the Contradictions A First-Principles-Based Compressive Microbuckling Model Selected Results Medical Applications of Composites Biomedical Composites in Orthopedic Applications Biomedical Composites in Dental Applications Biomedical Composites for Tissue Engineering Chapter Questions 1.3.8A - Microparticles Introduction Why Size Matters Materials for the Synthesis of Microparticles Natural Polymers Synthetic Polymers Nonpolymeric Materials Microparticle Preparation Characterization of Microparticles Drug Release Mechanisms Biomedical Applications of Microparticles Drug Delivery Radiotherapy Other Applications Concluding Remarks Chapter Exercises 1.3.8B - Nanoparticles Chapter Objectives Introduction Categories of NPs Polymeric NPs Lipid-Based NPs Inorganic NPs Bio-Inspired NPs Hybrid NPs Characterization of NPs Size Surface Charge Morphology Biocompatibility In Vitro Toxicity Hemocompatibility In Vivo Toxicity Drug Delivery Applications of NPs Drug Loading Covalent Bonding (Prodrug) Noncovalent Encapsulation Systemic Barriers Against Drug Delivery Approaches to Overcome Systemic Barriers Long-Circulating NPs Targeted Drug Delivery Tumor Penetration Stimuli-Responsive Drug Delivery Clinical Development Nucleic Acid Delivery Applications of NPs Intracellular Barriers Against Nucleic Acid Delivery Strategies to Overcome Intracellular Barriers Nucleic Acid Condensation and Cellular Internalization Endosomal Escape Stimuli-Responsive NPs for Intracellular Gene Release Nuclear Transport Clinical Development Diagnostic/Theranostic Applications of NPs In Vitro Diagnosis In Vivo Imaging Theranostics Imaging-Guided Surgery Conclusion Chapter Assessment Questions 1.4.1 - Introduction to Materials Processing for Biomaterials 1.4.2 - Physicochemical Surface Modification of Materials Used in Medicine Introduction General Principles Thin Surface Modifications Delamination Resistance Surface Rearrangement Surface Analysis Manufacturability and Commercializability Methods for Modifying the Surfaces of Materials Chemical Reaction Surface Grafting: Radiation Grafting, Photografting, and Newer Methods RFGD Plasma Deposition and Other Plasma Gas Processes The Nature of the Plasma Environment The Apparatus to Generate Plasmas for Surface Modification RFGD Plasmas for the Immobilization of Molecules High-Temperature and High-Energy Plasma Treatments Specific Chemical Reactions for Forming Surface Grafts Silanization Ion Beam Implantation Langmuir–Blodgett Deposition Self-Assembled Monolayers Layer-By-Layer Deposition and Multilayer Polyelectrolyte Deposition Surface-Modifying Additives Conversion Coatings Parylene Coating Laser Methods Patterning References Conclusions 1.4.3A - Nonfouling Surfaces Introduction Background and Mechanism Nonfouling Materials and Methods Conclusions and Perspectives 1.4.3B - Nonthrombogenic Treatments and Strategies Introduction Historical Criteria for Nonthrombogenicity Inert Materials Hydrogels Polyethylene Glycol (PEG) Immobilization Albumin Coating and Alkylation Zwitterionic Group/Phospholipid-Mimicking Surfaces Surface-Modifying Additives (SMAs) Fluorination Heparin-Like Materials Self-Assembled Surface Layers Active Materials Heparinization Ionically Bound Heparin and Controlled-Release Systems Covalently Bound Heparin Thrombin Inhibition Without Heparin Immobilization of Antiplatelet Agents Immobilization of Fibrinolytic Agents Use of Endothelial Cells and RGD Peptides Strategies to Lower the Thrombogenicity of Metals Summary 1.4.4 - Surface-Immobilized Biomolecules Introduction Patterned Surface Compositions Immobilized Biomolecules and Their Uses Immobilized Cell Ligands and Cells Immobilization Methods Conclusions References 1.4.5 - Surface Patterning Introduction Common Concerns In Biomolecular Surface Patterning Resolution Throughput Contrast Bioactivity Shelf-Life and Durability Patterning Techniques Direct-Write Patterning Writing With A Stylus Printing With Inkjets, Quills, and Pins Dip-Pen Nanolithography Nanoshaving and Nanografting Writing With Beams Direct-Write Photolithography Electron Beam Lithography Focused Ion Beam Lithography Writing With Fields Electric Field Magnetic Field Patterning With Masks Photolithography With Masks Deposition/Etching With Masks Patterning With Masters Imprinting With a Master Printing With a Stamp Microcontact Printing: Use of Protruding Features of a Stamp Microfluidic Patterning: Use of Void Features of a Stamp Patterning by Self-Assembly of Polymers and Colloids Block Copolymer Self-Assembly Nanosphere Lithography Magnetic Self-Assembly Dynamic Patterning Three-Dimensional Printing Conclusions 1.4.6 - Medical Fibers and Biotextiles Introduction Fiber-Forming Polymers Characteristics of Fiber-Forming Polymers Natural and Synthetic Polymers for Biotextile Production Medical Fibers and Production Methods Introduction to Textile Fibers Melt Extrusion Wet/Gel Spinning Electrospinning Electrospinning Process and Spinning Parameter Optimization Materials Selection for Electrospinning Coelectrospinning Centrifugal Electrospinning Hydrogel Fiber Spinning Surface Functionalization Textile Structures Woven Textiles Knitted Textiles Braided Textiles Nonwoven Textiles Finishing and Surface Coating Applications of Medical Fibers and Biotextiles Biotextiles of General Surgery Meshes and Sutures: Design and Materials Barbed and Drug-Eluting Sutures Cardiovascular Applications of Biotextiles Design Criteria for Vascular Prostheses Woven Versus Knitted Structure Examples of Cardiovascular Biotextiles Endovascular Stent Grafts Knitted Textile Structures as Sewing Rings Orthopedic Applications of Biotextiles Ligament and Tendon Replacement With Woven and Braided Biotextiles Fiber Reinforcement in Bone Graft Cement Biotextiles as Wound Dressings and Skin Grafts Wound Dressings and Hemostats Skin Grafting for Burn Injuries Applications of Electrospun Fibers Wound Dressing Musculoskeletal Tissue Engineering Neural Tissue Engineering Nanofibers for Cardiovascular Repair Nanofibers for Local Drug Delivery Future Directions Chapter Study Questions 1.4.7 - Textured and Porous Biomaterials Introduction Importance of Texture and Porosity in Facilitating Biomaterial Integration Textured Devices Promote Healing and Restore Organ Function Porosity to Promote Tissue Ingrowth Biomaterials for Tissue Engineering Fabrication Methods for Biomimetic Nanoscale Texture Electrospinning Self-Assembly of Nanoscale Features Thermally Induced Phase Separation Grooves and Micropatterns Fabrication Methods for Micro- and Macroscale Architectural Features Interconnected Spherical Macropores by Porogen Methods Nonspherical Architectural Patterning Combining Multiple Fabrication Methods Macroporous, Nanofibrous Tissue-Engineering Scaffolds Multiphasic Scaffolds 3D Printed Scaffolds Injectable Tissue-Engineering Scaffolds Surface Modification of Biomaterial Constructs Summary and Future Perspectives Chapter Exercises 1.4.8 - Biomedical Applications of Additive Manufacturing Introduction 3D Printing Modalities Vat Photolithography Material Jetting Material Extrusion Powder Bed Fusion Binder Jetting Sheet Lamination Directed Deposition Bioprinting Bioprinting Approaches Bioink Design Parameters Biofabrication Window Biomaterials for Bioprinting Medical Applications of 3D Printing Surgical Planning and Medical Training Fabrication of Complex Implants Personalized Drug Delivery Systems Summary Chapter Review Questions 2.1.1 - Introduction to Biology and Medicine—Key Concepts in the Use of Biomaterials in Surgery and Medical Devices 2.1.2 - Adsorbed Proteins on Biomaterials Introduction Examples of the Effects of Adhesion Proteins on Cellular Interactions With Materials The Effects of Preadsorption With Purified Adhesion Proteins Depletion Studies Inhibition of Receptor Activity With Antibodies The Adsorption Behavior of Proteins at Solid–Liquid Interfaces Adsorption Transforms the Interface Rapid Adsorption Kinetics and Irreversibility The Monolayer Model Competitive Adsorption of Proteins to Surfaces From Protein Mixtures Molecular Spreading Events: Conformational and Biological Changes in Adsorbed Proteins Physicochemical Studies of Conformational Changes Changes in Biological Properties of Adsorbed Proteins The Importance of Adsorbed Proteins in Biomaterials Surface Chemistries Highly Resistant to Protein Adsorption Concluding Remarks Chapter Solutions to Problems Chapter Solutions to Problems Protein Monolayer Calculation 2.1.3 - Cells and Surfaces in Vitro Introduction A Basic Overview of Cell Culture Primary Culture Cell Lines Characteristics of Cultured Cells Understanding Cell–Substrate Interactions Surfaces for Cell Culture Process of Cell Attachment in Vitro Commercial and Experimental Modifications of Culture Surfaces Dynamic Control of Cell Culture Surfaces Investigating Cell–Substrate Interactions Cell Response to Substrate Chemistry Micrometer-Scale Chemical Patterns Nonfouling Surfaces in Cell Culture Chemical Patterning for the Coculture of Cells High-Throughput Screening Nanometer-Scale Chemical Patterning Cell Response to Substrate Topography Micrometer-Scale Topography Nanometer-Scale Topography High-Throughput Screening of Surface Topography Cell Response to Substrate Elasticity Cell Response to Mechanical Deformation (Strain) Comparison and Evaluation of Substrate Cues Chemistry and Topography Chemistry and Strain Topography and Strain Organ-on-a-Chip 3D culture Summary 2.1.4 - Functional Tissue Architecture, Homeostasis, and Responses to Injury Tissue Constituents, Organization, and Integration The Essential Role of Cells Parenchyma and Stroma Vascular Supply: Tissue Perfusion Extracellular Matrix (See also Chapter 2.1.5) Organ Structure Cell and Tissue Differentiation, Phenotype, and Maintenance Structure–Function Correlation Stem Cells Cellular Differentiation and Gene Expression Tissue Homeostasis Cell Turnover Matrix Remodeling Cell and Tissue Injury, Adaptation, and Other Responses (Fig. 2.1.4.12) Cell Regeneration and Proliferation Reversible versus Irreversible Injury Adaptation Hyperplasia Can Be Physiologic or Pathologic Atrophy, Proteasomes, and Autophagy Metaplasia Neoplasia Causes of Cell Injury Hypoxia and Ischemia Toxic Injury and Trauma Infection and Inflammation Pathogenesis of Cell Injury Ischemia-Reperfusion Injury Cell Death Necrosis Apoptosis Response to Tissue Injury and Biomaterials Inflammation and Innate Immunity Macrophage Recruitment and Polarization Regeneration Versus Fibrosis (Scar) Growth Factors Vascular Response Wound Healing in the Presence of Biomaterials Complications and Defective Wound Healing 2.1.5 - The Extracellular Matrix and Cell–Biomaterial Interactions Introduction Extracellular Matrices Properties of the Extracellular Matrix Collagens and Elastin Fibronectin Laminins Proteoglycans, Glycosaminoglycans, and Hyaluronic Acid Growth Factor Sequestering Proteins and Motifs ECM Remodeling and Proteolysis Integrins and Adhesion Receptors Cell–Biomaterial Interactions Cell Interactions With Adsorbed Proteins on Biomaterials Engineered Receptor-Targeting Peptide Sequences for Cell Adhesion Engineered MMP-Sensitive Peptide Sequences for ECM Remodeling and Proteolysis Engineered Peptide Fibers That Mimic the ECM Structure Summary Chapter Exercises 2.1.6 - Effects of Mechanical Forces on Cells and Tissues Introduction Molecular Mechanisms of Cellular Mechanotransduction Focal Adhesion and Mechanosensing at the ECM–Biomaterial Interface Cytoskeletal Mechanotransduction Nuclear Mechanotransduction Techniques for Studying Mechanical Interactions of Cells Shear Stress Mechanical Stretch Substrate Stiffness Micro- and Nanopatterning Mechanical Forces in the Vascular System Effect of Shear Stress on Blood Vessels Effect of Cyclic Strain on Blood Vessels Bone and Cartilage Summary 2.2.1 - Introduction to Biological Responses to Materials 2.2.2 - Inflammation, Wound Healing, the Foreign-Body Response, and Alternative Tissue Responses Biocompatibility and Implantation Sequence of the Host Response Following Implantation of Medical Devices Wound Healing Host Response to Implanted Biomaterials Tissue Remodeling and Biomaterial Integration—Alternative Tissue Responses Cellular and Molecular Mediators of Constructive Remodeling and Tissue Restoration Strategies to Control Host Responses 2.2.3 - Innate and Adaptive Immunity: The Immune Response to Foreign Materials Overview Innate Immunity First Barriers Against Danger Complement System Pattern Recognition by the Innate Immune System Cells of the Innate Immune System Antigen Uptake, Processing, and Presentation Costimulatory Molecules Chemokines and Cytokines Adaptive Immunity Components of Adaptive Immunity Humoral Immunity Cell-Mediated Immunity Cytotoxic T Cells Helper T Cells Recognition in Adaptive Immunity B Cell and Antibody Recognition T Cell Recognition Effector Pathways in Adaptive Immunity Immunological Memory Overview of the Immune Response to Pathogens Overview of Immune Regulation and Tolerance Intersection of Biomaterials and Immunology Chapter Exercises Innate Immunity Adaptive Immunity 2.2.4 - The Complement System Introduction Classical Pathway Lectin Pathway Alternative Pathway Membrane Attack Complex Control Mechanisms Complement Receptors Measurement of Complement Activation Complement–Coagulation System Interactions Clinical Correlates Summary and Future Directions Chapter Questions 2.2.5 - Systemic and Immune Toxicity of Implanted Materials Basic Principles of Systemic Distribution and Toxicity of Biomaterial Constituents Metals and Metal Alloy Toxicity Hypersensitivity and Immunotoxicity Organ Localization of Inflammatory and Immune Responses to Device Materials Summary and Conclusions Chapter Exercises 2.2.6 - Blood Coagulation and Blood–Material Interactions Introduction Platelet Adhesion and the Blood Coagulation Cascade—An Overview Cellular Composition of Blood Erythrocytes (Red Cells) Leukocytes (White Cells) Platelets Platelet Adhesion Platelet Aggregation Platelet Release Reaction Platelet Coagulant Activity Platelet Consumption Coagulation Mechanisms of Coagulation Control Mechanisms Fibrinolysis Complement Blood–Material Interactions Overview Platelet–Material Interactions Contact Activation of the Blood Coagulation Cascade Approaches to Improve the Blood Compatibility of Artificial Materials Conclusions Chapter Exercise Questions Question 1 Question 2 Question 3 2.2.7 - Tumorigenesis and Biomaterials General Concepts Association of Implants With Human and Animal Tumors Pathobiology of Foreign Body Tumorigenesis Stem Cell Therapies and Tumorigenesis Conclusions References 2.2.8 - Biofilms, Biomaterials, and Device-Related Infections Introduction Bacterial Biofilms What Are Biofilms and Why Are They Problematic? The Biofilm Microenvironment Antibiotic and Antimicrobial Tolerance of Bacteria in Biofilms Biofilms and the Immune Response Bacterial Adhesion The Process of Bacterial Adhesion to Surfaces DLVO Theory Thermodynamic Model Influence of Material Properties on Bacterial Adhesion Surface Free Energy (Wettability) Roughness Environment Factors Influence Bacterial Adhesion Device-Related Infection Major Medical Devices, Materials, and Pathogens Evidence for Biofilms on Devices Control of Biofilm Formation Antimicrobial Approaches: Biomaterials With Antimicrobial Properties Biomaterials Releasing Bioactive Molecules Antibiotics Silver Low-Dose Nitric Oxide Intrinsically Bioactive Biomaterials: Cationic Materials Natural Cationic Polymers .Chitosan is a polysaccharide composed of randomly distributed N-acetylglucosamine and d-glucosamine having low toxicity toward ... .Antimicrobial peptides (AMPs) are produced as part of the first line of defense in innate immunity system. Typical AMPs are sma... Synthetic Cationic Polymers Antifouling Approaches: Biomaterials That Repel Microbes Hydrophilic Materials Based on Polyethylene Glycol Superhydrophobic Materials Materials With Nano/Microscale Surface Texture Biomaterials Affecting Biofilm Architecture Biomaterials Modified With QS-Quenching Enzymes Biofilm Matrix-Degrading Enzymes Methods for Testing Antibacterial and Antifouling Properties of Biomaterials Conclusions Chapter Questions 2.3.1 - How Well Will It Work Introduction to Testing Biomaterials 2.3.2 - The Concept and Assessment of Biocompatibility Biocompatibility Today Toxicology The Products of Extrinsic Organisms Colonizing the Biomaterial Mechanical Effects Cell–Biomaterial Interactions Summary of Ideas to This Point New Developments Are Changing the Paradigm of Biocompatibility Clinical Significance of Biocompatibility Conclusions 2.3.3 - In Vitro Assessment of Cell and Tissue Compatibility Introduction Background Concepts Use of Medical Device/Biomaterial Chemical Composition and Their Extracts for Toxicological Risk Assessment and In Vitro Testing... In Vitro Assays to Assess Cell and Tissue Compatibility in Medical Device/Biomaterial Evaluation for Regulatory Purposes In Vitro Tests for Genotoxicity, Carcinogenicity, and Reproductive Toxicity: ISO 10993-3 In Vitro Tests for Interactions with Blood: ISO 10993-4 In Vitro Tests for Cytotoxicity: ISO 10993-5 Application-Specific In Vitro Assays Considered in Proof-of-Concept Testing Future Challenges in In Vitro Assessment of Cell and Tissue Compatibility Summary Remarks Chapter Questions 2.3.4 - In Vivo Assessment of Tissue Compatibility Introduction Selection of in Vivo Tests According to Intended Use Biomaterial and Device Perspectives in In Vivo Testing Specific Biological Properties Assessed by In Vivo Tests Sensitization, Irritation, and Intracutaneous (Intradermal) Reactivity Systemic Toxicity: Acute, Subacute, and Subchronic Toxicity Genotoxicity Implantation Hemocompatibility Chronic Toxicity Carcinogenicity Reproductive and Developmental Toxicity Biodegradation Immune Responses Selection of Animal Models for In Vivo Tests Future Perspectives on In Vivo Medical Device Testing 2.3.5 - Evaluation of Blood–Materials Interactions Introduction Background and Principles of Blood–Materials Interactions Assessment What Is Blood Compatibility? Why Measure Blood Compatibility? What Is Thrombogenicity? Key Considerations for BMI Assessment Blood: A Fragile Fluid That Is Readily Compromised Flow: Blood Interactions Dictated by Shear and Mass Transport Surfaces: Actively Studied, but Least Well Defined, of the BMI Variables Blood Interaction Times With Materials and Devices Evaluation of BMI In Vitro Tests In Vivo Tests of BMI In Vivo Evaluation of Devices Contemporary Concepts in BMI Evaluation Examples of BMI Evaluation What Materials Are Blood Compatible? Conclusions References 2.3.6 - Animal Surgery and Care of Animals Introduction Ethical and Regulatory Overview Governmental Regulations United States Department of Agriculture Public Health Service Food and Drug Administration Institutional Responsibilities Institutional Animal Care and Use Committee Attending Veterinarian Principal Investigator Surgical Facility Design Model Selection Cardiovascular Devices Heart Valve Replacement Ventricular Assist Devices Orthopedic Devices Bone Defect Models Vascular Ophthalmology Skin Animal Management and Care of Animals Rodent Animal Selection and Preoperative Preparation General Anesthesia Analgesia Ruminants (Sheep, Goats, Calves) Animal Selection and Preoperative Preparation Brief Restraint General Anesthesia Analgesia Rabbit Animal Selection and Preoperative Preparation Brief Procedures General Anesthesia Analgesia Swine Animal Selection and Preoperative Preparation Brief Restraint General Anesthesia Analgesia Chapter Study Questions 2.4.1 - Introduction: The Body Fights Back–Degradation of Materials in the Biological Environment 2.4.2- Chemical and Biochemical Degradation of Polymers Intended to Be Biostable Introduction Polymer Degradation Processes Preimplant Degradation Postimplant Degradation Forces Hydrolytic Biodegradation Structures of Hydrolyzable Polymers Host-Induced Hydrolytic Processes Hydrolysis: Preclinical and Clinical Experience Polymers Containing Hydrolyzable Pendant Groups Oxidative Biodegradation Oxidation Reaction Mechanisms and Polymer Structures Direct Oxidation by Host Stress Cracking Device- or Environment-Mediated Oxidation Chemical Structure Strategies to Combat Oxidation Oxidative Degradation Induced by External Environment Emerging Long-Term Elastomer Applications Polyurethanes Hydrocarbon Elastomers Conclusions Chapter Questions 2.4.3 - Metallic Degradation and the Biological Environment Introduction The Severe Biological Environment (Fatigue, Tribology, Corrosion, and Biology) Basic Corrosion of Passive Oxide-Covered Alloys Tribological Aspects of Metal-Hard Contact Degradation Metal-on-Metal (Hard) Surface Mechanics Clinically Observed Mechanically Assisted Crevice Corrosion (Fretting Crevice Corrosion) In Vivo Mechanically Assisted Corrosion Basics for CoCrMo and Ti–6Al–4V Alloys Tribocorrosion Layer and Surface Damage on Metallic Biomaterials Surfaces Biology and Corrosion: Additional Insights Reduction Reactions Affect Cells Reactive Oxygen Species May Enhance Corrosion Reactions Summary Acknowledgments References 2.4.4 - Degradative Effects of the Biological Environment on Ceramic Biomaterials Introduction Reactivity of Bioceramics Factors Influencing the Degradation of Bioceramics Reactivity and Degradation of Natural Apatites Evolution in the Use of Bioceramics for Bone Repair Bioceramic Interactions With the Biological Environment Inert Ceramics: First-Generation Bioceramics Resorbable and Bioactive Ceramics: Second-Generation Bioceramics Third-Generation Ceramics Summary and Future Perspectives 2.4.5 - Pathological Calcification of Biomaterials The Spectrum of Pathologic Biomaterial and Medical Device Calcification Bioprosthetic Heart Valves Transcatheter (or Percutaneous) Cardiac Valve Replacements Polymeric Heart Valves and Blood Pump Bladders Breast Implants Intrauterine Contraceptive Devices Urinary Stents and Prostheses Intraocular and Soft Contact Lenses and Scleral Buckles Assessment of Biomaterial Calcification Morphologic Evaluation Chemical Assessment Mechanisms of Biomaterial Calcification Regulation of Pathologic Calcification Role of Biological Factors Role of Biomaterial Factors Role of Biomechanical Factors Experimental Models for Biomaterial Calcification Role of Cells Role of Collagen and Elastin Role of Glutaraldehyde Role of Immunologic Factors Prevention of Calcification Inhibitors of Hydroxyapatite Formation Bisphosphonates Trivalent Metal Ions Calcium Diffusion Inhibitor Removal/Modification of Calcifiable Material Surfactants Alcohol Treatments Glutaraldehyde Neutralization Decellularization Modification of Glutaraldehyde Fixation and Other Tissue Fixatives Alternative Materials Design Considerations and Selection of Materials to Avoid Calcification Conclusions References 2.5.1 - Introduction to Applications of Biomaterials 2.5.2A - Cardiovascular Medical Devices: Heart Valves, Pacemakers and Defibrillators, Mechanical Circulatory Support, and Other Intracardiac Devices Introduction Heart Valve Function and Valvular Heart Disease Surgical Bioprosthetic and Mechanical Heart Valves Percutaneous Transcatheter Valves and Other Devices Cardiac Arrhythmias Cardiac Pacemakers Implantable Cardioverter-Defibrillators Complications of Pacemakers and ICDs Congestive Heart Failure Cardiopulmonary Bypass Percutaneous Mechanical Circulatory Support Devices Durable Ventricular Assist Devices and Total Artificial Hearts Atrial Septal Defects and Other Intracardiac Defects Closure Devices Atrial Fibrillation Left Atrial Appendage Occlusion Devices 2.5.2B - Cardiovascular Medical Devices: Stents, Grafts, Stent-Grafts and Other Endovascular Devices Key Concepts in Vascular Structure and Function Architecture of the Circulation Vascular Pathology Vascular Injury and Healing Thrombosis Atherosclerosis Aneurysms and Dissections Vascular Devices and Biomaterials Angioplasty and Endovascular Stents Vascular Grafts Endovascular Stent-Grafts Other Vascular Devices Endovascular Catheters Diagnostic Catheters Therapeutic Catheters Endovascular Coils Vascular Filters Vascular Closure Devices (VCDs) Unintended Embolic Biomaterials Ex Vivo Evaluation Conclusions 2.5.3 - Extracorporeal Artificial Organs and Therapeutic Devices Introduction Extracorporeal Respiratory Support Pulmonary Disease—Incidence, Causes, and Mortality Extracorporeal Membrane Oxygenation (ECMO) Alternative Extracorporeal Gas Exchange Devices Oxygenator Biocompatibility Challenges: Coagulation and Inflammation Surface Coatings Nitric Oxide Surface Flux Renal Replacement Therapies and Therapeutic Apheresis Introduction Renal Replacement Therapy Function of the Kidney Treatment of Renal Failure Peritoneal Dialysis Hemodialysis Dialyzer Materials and Coatings Coagulation and Inflammation During Hemodialysis Extracorporeal Hemofiltration Hemoperfusion Therapeutic Apheresis Plasmapheresis Plasma Separation Plasma Exchange Plasma Treatment Sorbent Dialysis Blood Pumps in Extracorporeal Circulation Roller Pumps Summary Chapter Exercises 2.5.4 - Orthopedic Applications Biomaterials Development: A History of Total Hip Arthroplasty Current Biomaterials in Total Arthroplasty Orthopedic Biomaterials: Clinical Concerns Orthopedic Biomaterial Wear Orthopedic Biomaterial Corrosion Fretting Corrosion or Mechanically Assisted Crevice Corrosion (MACC) Implant Debris Types: Particles and Ions Particulate Debris Metal Ions (Soluble Debris) Local Tissue Effects of Wear and Corrosion Remote and Systemic Effects of Wear and Corrosion Hypersensitivity Carcinogenesis Preventive Strategies and Future Directions Chapter Study Questions 2.5.5 - Dental Applications Overview Unique Needs in Developing Biomaterials for DOC Procedures Restorative Materials Dental Implants Criteria for Successful Implant Function Osseointegration and Accelerating Healing and Attachment to Tissue Surface Topology and Chemistry Mechanical Parameters and Implant Design Materials Used in Dental Implants Metals Ceramics Future Directions Tissue Engineering in Dentistry Need for Tissue Engineering in Dentistry Materials for Engineering DOC Tissue Structure and Function DOC Tissue-Engineering Applications Teeth Temporomandibular Joint Oral Mucosa Salivary Glands Bone and Periodontium Summary and How Experience From Dental Biomaterials has Brought Value to Other Areas of Biomaterials Chapter Exercises 2.5.6 - Ophthalmologic Applications: Introduction Overview of the Anatomy of the Eye Eye-related Conditions and Statistics Considerations for Ophthalmic Materials Biomaterials: Contact Lenses Contact Lens Materials Hard Contact Lenses Soft Hydrogel Contact Lenses Silicone Hydrogel Contact Lenses Surface Modification Contact Lens Solutions Intraocular Lens Implants Introduction to Intraocular Lens Implants, the Optics of the Eye, and Cataracts IOL Biomaterials and Design IOLs With Variations of Optical Function Multifocal IOLs Accommodative IOLs Adjustable-Power IOLs Summary and Future of IOLs Glaucoma Drainage Devices Aqueous Humor Production and Drainage New-generation Microinvasive Glaucoma Surgery (MIGS) Implantation Devices The Glaukos iStent Series Summary Retinal Implants Epiretinal Devices Argus II The Intelligent Retinal Implant System II (IRIS II) EPI-RET3 Retinal Implant System Subretinal Devices Alpha IMS/AMS Photovoltaic Retinal Implant (PRIMA) Bionic Vision System Suprachoroidal Devices Bionic Vision Australia (BVA) Team Suprachoroidal–Transretinal Stimulation (STS) Conclusions and Future Directions 2.5.7 - Bioelectronic Neural Implants Introduction Bioelectronic Devices Electrode Materials Factors That Influence Materials Selection Conducting/Capacitive Materials Insulating Materials Equivalent Circuit Models Technologies Battery, IPG Leads and Interconnects Electrode Contacts Applications Research Rehabilitation Sensory Restoration Visual Tactile Auditory Genitourinary, Bladder Dysfunction Motor Function Brain–Computer Interface Bioelectronic Medicine, “Electroceuticals” Regeneration Failure Modes Mechanical Materials Biological Biomaterial-Based Strategies to Enable Neural Implants Micromotion and Tissue Mechanics Antioxidative Strategies Conclusions and Future Directions 2.5.8 - Burn Dressings and Skin Substitutes Burn Wounds Surgical Planning for Wound Care Ideal Properties of Dressings and Skin Substitutes Topical Microbial Management Negative-Pressure Dressings Degradable Polymers Temporary Skin Substitutes Permanent Skin Substitutes Cost Considerations Regulatory Considerations Conclusions and Future Directions Chapter Exercises 2.5.9 - Description and Definition of Adhesives, and Related Terminology Introduction Description and Definition of Adhesives, and Related Terminology The Logic of Adhesion Procedures Hard-Tissue Adhesives: Bone and Tooth Cements Autopolymerizing PMMA Bone Cement Historical Background Mechanism of Setting of PMMA/MMA Dough Mechanism of “Bonding” or Grouting Alternative Bone Cements: Calcium Phosphate Classical and Modern Dental-Bonding Cements: Conventional Acid–Base Cements Polyelectrolyte Cements: Zinc Polycarboxylates and Glass Ionomers Acid-Etch Bonding to Enamel Chemistry of Etchants, Primers, and Bonding Agents Hybrid-Layer Creation Via A Three-Stage Approach: Etch, Prime, Bond Aging and Stability of the Bonded Interface Inhibitors for the Preservation of the Hybrid Interfacial Zone Between Adhesives and Human Dentin Soft-Tissue Adhesives and Sealants Performance Requirements Historical Overview The Relationship Between Soft-Tissue Adhesion and Drug Delivery Cyanoacrylate Esters Chemistry Performance Fibrin Sealants Formulation, Presentation, and Setting Processes Advantages and Applications Bioadhesives Hydrogel Sealants New Research Directions: Biomimetic Approaches Sutures Genesis and Common Uses Description of Surgical Sutures Surgical Gut Sutures Silk Sutures Polyester Sutures Nylon Sutures Polypropylene Sutures Ultrahigh-Molecular-Weight Polyethylene (UHMWPE) Sutures Stainless Steel Sutures Synthetic Absorbable Sutures Monomers and Preparation of Polymers Poly(Glycolic Acid) (PGA) Poly(Dioxanone) (PDO) Sutures High-Glycolide Copolymeric Sutures Dyes Coatings Needles and Attachment Packaging Physical Properties In Vitro and In Vivo Performance Newer Trends and Future Developments 2.5.10 - Biomaterials for Immunoengineering Use of Biomaterials in Vaccine Development Introduction Biomaterials for Improving Vaccine Efficacy Use of Biomaterials to Adjuvant the Immune System Use of Biomaterials to Improve Delivery of Antigen to APCs Activation of B Cells and Humoral Immunity Overview of the B Cell Activation Process Biomaterial Design for Enhancing the Humoral Response Biomaterials for Alternative Vaccine Administration Routes Biomaterials for Improved Vaccine Manufacturing and Accessibility Conclusion/Future Directions Use of Biomaterials in T Cell Modulation Introduction Biomaterials for Targeting and Modulation of T Cell Therapies Biomaterials for Enhanced T Cell Manufacturing Conclusions/Future Directions Use of Biomaterials to Induce Tolerance Introduction Induction of Tolerance in Autoimmune Disorders T Cell Anergy and Deletion Through Incomplete Dendritic Cell Activation Elevation of Treg Activity to Induce Tolerance Suppression of B Cell Activation Concluding Remarks Exercises 2.5.11 - Biomaterials-Based Model Systems to Study Tumor–Microenvironment Interactions Introduction Biological Design Considerations Tissue Dimensionality Transport Phenomena and Interstitial Pressure ECM Physicochemical Properties Immunological Changes Biomaterials to Study the Tumor Microenvironment Natural Biomaterials Protein-Based Materials Carbohydrate-Based Materials Cell- and Tissue-Derived Materials Synthetic Biomaterials Synthetic Hydrogels Polyesters Composite Materials Applications of Biomaterials-Based Tumor Models Analyzing the Effect of Tissue Dimensionality Modeling Tumor–Stroma Interactions Platforms to Interrogate Cell–ECM Interactions Dynamic Materials Systems for Studies of Mechanical Memory Analyzing the Effect of Local and Systemic Transport Phenomena Metastasis Conclusions Chapter Exercises With (Guided) Solutions 2.5.12 - Drug Delivery Systems History of DDS Development General Considerations in DDS Design Routes of Drug Delivery DDS Biomaterials Design Considerations Biomaterials Used in DDSs DDS Biomaterial Properties Degradation Surface Properties Mechanics DDSs to Improve Drug Pharmacokinetics Pharmacokinetics Dosage and Distribution Control Controlling Drug Release Kinetics DDSs to Improve Drug Solubility Colloidal DDSs Noncolloidal DDSs Biomaterial DDSs Can Enhance Drug Stability Small Molecule Drugs Protein/Peptide Drugs Nucleic Acid Drugs DDS Design to Overcome Biological Barriers Epithelial Barriers Parenteral Administration Transdermal DDSs Mucosal DDSs Oral DDSs Endothelial Barriers Biomaterial DDSs for Drug Targeting Passive Targeting Active Targeting Antibodies Proteins Peptides Aptamers Carbohydrates Small Molecules Regulatory and Intellectual Property Considerations for DDSs Regulation Intellectual Property Final Remarks Chapter Review Questions 2.5.13 - Responsive Polymers in the Fabrication of Enzyme-Based Biosensors Introduction Classic Biosensor System Bioreceptor (Recognition Layer) Physicochemical Transducers Computer Processing Types of Enzymatic Glucose Biosensors Electrochemical Biosensors Amperometric Biosensors Conductometric Biosensors Impedimetric Biosensors Potentiometric Biosensors Optical Biosensors Piezoelectric Biosensors Thermal Biosensors Roles of Responsive Polymers in Enzymatic Biosensors Passive Roles (Physical Support) Covalent Linkage Cross-Linking Entrapment Encapsulation Active Roles Redox Mediators Chromogenic Agents Fast Ion Conductors Fluorescence Probes Integrating Responsive Polymers With Enzymes Physicochemical Conjugation With CNTs Active Site Conjugation Using Boric Acid Molecular Wiring Covalent Conjugation Integrating Responsive Polymers With Transducers Interface Engineering Systems Integration Microfabrication Three-Dimensional (3-D) Bioprinting Future Outlook 2.6.1 - Rebuilding Humans Using Biology and Biomaterials 2.6.2 - Overview of Tissue Engineering Concepts and Applications General Introduction History of Tissue Engineering Goals of Tissue Engineering and Classification Goals of Tissue Engineering Classification of Tissue-Engineering Approaches Components of Tissue Engineering The Cell Materials Biological Factors Scaffold Design Integration of Multiple Factors Models for Tissue Engineering Bioreactors Organoids In Vivo Models Applications of Tissue Engineering Transplantation Replacing/Regenerating Target Organs Drug Delivery Disease Models and Therapy Organ-On-a-Chip Systems Current Challenges and Opportunities Cell Source Vascularization Tissue Maturation In Vivo Integration FDA Regulations for Clinical Translation Gene Editing and CRISPR Future Perspectives 2.6.3 - Tissue Engineering Scaffolds Introduction Scaffold Design Criteria Scaffold Applications Cell Delivery Drug and Biomolecule Delivery Scaffold Materials Polycondensation Polymers Ring-Opening Polymerization Click Reactions Polyaddition Polymers Ionic Polymerization Free Radical Polymerization Biological Polymers Composites and Additives Scaffold Fabrication Techniques Rapid Prototyping Electrospinning/Electrospraying Superstructure Engineering Solvent Casting, Particulate/Porogen Leaching Freeze-Drying Phase Separation Gas Foaming/Supercritical Fluid Processing Scaffold Characterization Techniques Cell-Incorporated Scaffolds Conclusions Chapter Exercises Chapter Exercise Answers 2.6.4 - Micromechanical Design Criteria for Tissue-Engineering Biomaterials Introduction Cell–Matrix Interactions and Mechanotransduction Focal Adhesion Roles of Focal Adhesion Maturation and Stress Fiber Formation in Mechanotransduction Important Mechanotransduction Molecular Pathways for Design of Scaffolds Direct Transmission of Forces to the Nucleus Design Considerations for Scaffolds to Regulate Tissue Development Local Stiffness Surface Topography Fibrous Scaffolds Multicellular Interactions Mechanical Stimulation Effects of Combined Mechanical Stimuli Implications for Future Materials Design Conclusion 2.6.5 - Tendon Tissue-Engineering Scaffolds Introduction Native Adult Tendon Properties Mechanical Properties Extracellular Matrix Composition and Molecular Arrangement Tendon Cells Scaffold Design Goals Immediate or Early Return to Load-Bearing Function Guidance Cues to Induce Tenogenic Cell Behaviors Fabrication Methods Spinning Textile Technologies Gelation Freeze Drying Decellularization Postfabrication Modifications Delivery of Bioactive Molecules (e.g., Drugs and Growth Factors) Polymer Selection and Scaffold Designs Natural Plant- and Animal-Derived Polymers Alginates Chitin/Chitosan Collagen Gelatin Silk Synthetic Polymers Poly(Glycolic Acid) and Poly(Lactic Acid) Poly(ε-Caprolactone) Other Synthetic Polymers Future Directions: Developmental Biology-Inspired Strategies Summary 2.6.6 - Bone Tissue Engineering Introduction Bone Biology Types of Bone Tissue Cells Involved Osteoblasts Bone Lining Cells Osteocytes Osteoclasts Bone Tissue Development Intramembranous Ossification Endochondral Ossification Bone Tissue Engineering Bone Grafts Autograft Allograft Bone Graft Substitutes Allograft-Based Substitutes Natural Polymer-Based Substitutes Synthetic Polymer-Based Substitutes Ceramic-Based Substitutes Cell-Based Substitutes Growth Factor-Based Substitutes Composite Substitutes Porosity in Bone Graft Substitutes Dimension in Bone Graft Substitutes Sintered Microspheres Nanofibers In Vitro Culture Techniques for Bone Graft Substitutes Conclusion 2.6.7 - Biomaterials for Cardiovascular Tissue Engineering Introduction Endothelial Cells Cardiac Muscle Heart Valves Blood Vessels Scaffold Materials Protein Hydrogels Decellularized Tissues Synthetic Polymers Synthetic Hydrogels Conclusions 2.6.8 - Soft Tissue Engineering Introduction Properties of Soft Tissues Common Biomaterials Used for Soft Tissue Engineering Synthetic Polymers Natural Polymers Decellularized Tissues Soft Tissue Engineering Applications: Adipose, Gastrointestinal, and Skin Adipose Tissue Engineering Anatomy and Physiology Design Criteria for Adipose Tissue Engineering Commercially Available and Clinically Tested Biomaterials Novel Materials and Technologies Challenges Gastrointestinal Tissue Engineering Anatomy and Physiology Gastrointestinal Disorders and the Need for Tissue Engineering Design Criteria for Engineered Gastrointestinal Tissues Gastrointestinal Soft Tissue-Engineering Strategies Challenges and Future Goals Tissue-Engineered Skin: Future Goals of Skin Substitutes Anatomy and Physiology Design Criteria Skin Substitute Technology Challenges Conclusions Chapter Exercises 3.1.1 - Introduction: Biomaterials in Medical Devices 3.1.2 - Total Product Lifecycle for Biomaterial-Based Medical Devices Chapter Questions for the Student 3.1.3 - Safety and Risk Considerations in Medical Device Development Introduction Absence of Toxicity Is Not Evidence of Safety Assessing the Continuum of Biological Risk in Performance Assessing the Contribution of Secondary Processes to Biological Risk Assessing Biological Risk of Aging Biomaterials in the Aging Patient Summary and Study Guide Chapter Study Guide 3.1.4 - Sterilization and Disinfection of Biomaterials for Medical Devices Introduction Radiation-Based Techniques Safety Considerations Principles of Action and Efficacy Gamma Sterilization Electron Beam Sterilization X-Ray Sterilization Application Considerations R&D, Pilot, and Low-Volume Technologies Material Considerations for Radiation Sterilization Biologics and Human-Based Tissue: Compatibility With Radiation Sterilization Chemical Techniques Safety Considerations Principles of Action and Efficacy Ethylene Oxide Sterilization Sterilization by Oxidation: Hydrogen Peroxide or Ozone Physicochemical Methods: Gas Plasma Material Considerations for Chemical Sterilization R&D, Pilot, and Low-Volume Technologies Pharmaceuticals and Biologics: Compatibility With EO Sterilization Thermal Techniques Safety Considerations Principles of Action and Efficacy Dry Heat Sterilization Steam Sterilization and Disinfection Application Considerations Materials Development Considerations for Sterility Safety Testing and Validation After Sterilization Patient Safety: FDA Recall Classifications: Class I, Class II, and Class III Biological Safety Verification Maintaining Sterility: Packaging and Shelf Life Sourcing, Quality Systems, and Manufacturing Controls Sterilization Standards Summary and Future Challenges Chapter Exercises 3.1.5 - Verification and Validation: From Bench to Human Studies Introduction: Focusing on Commercial Medical Device Development Starting a Medical Device Project Design Controls for Medical Device Development Verification of Medical Device Design Types of Verification Testing Validation of Medical Device Design Verification Versus Validation Concluding Remarks: Design Transfer Beyond Human Studies Chapter Study Questions 3.1.6 - Commercial Considerations in Medical Device Development Introduction Traditional Model of Product Development Determining Market Opportunity Medical Device Reimbursement Securing Intellectual Property and Funding Intellectual Property Securing Funding Commercial Operations: Sales and Marketing Summary Student Questions 3.1.7 - Regulatory Constraints for Medical Products Using Biomaterials Introduction and History in the United States Global Premarket Assessment Methods Premarket Assessment Requirements Premarket Clearance and Approvals Manufacturing and Material Supplier Controls Postmarketing Management of Risk and Product Performance Registration, Device Listing, Licenses Summary and Study Guide Chapter Questions: True or False 3.1.8 - Role of Standards for Testing and Performance Requirements of Biomaterials Introduction: What Is a Standard Reference Materials Reference Data Documentary Standards Documentary Standards: Voluntary, Consensus Who Writes Documentary Standards? How Are Documentary Standards Developed? Applications of Documentary Standards Accelerating the Regulatory Process Specificity versus Universality A Standard Test Method Does Not Necessarily Define the Best Measurement Clinical Relevance Measurement Assurance Interlaboratory Comparison Studies Looking Ahead Conclusion Homework Questions Answer Key for Homework Questions 3.1.9 - Medical Device Failure—Implant Retrieval, Evaluation, and Failure Analysis Overview and Definitions Medical Implants Implant Retrieval Postmarket Surveillance Goals for Implant Retrieval and Evaluation and Failure Mode Analysis Medical Surveillance and the Role of Retrieval Analysis in Device Development Chapter Exercises (With Answers) 3.1.10 - Legal Concepts for Biomaterials Engineers Introduction Employment Agreements Confidentiality and Materials Use Agreements Intellectual Property: Patents, Trade Secrets, and Freedom to Operate Contract Negotiation, Performance, and Compliance Sponsored Research Agreements License Agreements Litigation Conclusion 3.1.11 - Moral and Ethical Issues in the Development of Biomaterials and Medical Products Introduction Selected Approaches to Ethical Reasoning The Utilitarian Approach The Rights Approach The Justice Approach The Virtue Approach Safety Animal Testing Human Testing Research Integrity Conflict of Interest Emerging Ethical Issues in Medical Product Development Ethical Issues in Stem Cell Research Gene Editing Cost and Access to Medical Products Conclusions A - Properties of Biological Fluids B - Properties of Soft Materials C - Chemical Composition of Metals and Ceramics Used for Implants D - The Biomaterials Literature E - Assessment of Cell and Matrix Components in Tissues Light Microscopy Special Staining Immunohistochemical Staining In Situ Hybridization Electron Microscopy Special Techniques Index A B C D E F G H I J K L M N O P Q R S T U V W X Y Z