Mit dem "Handbook of Biomedical Coatings and Deposition Technologies" können Entwickler und Hersteller von medizinischen Geräten ihre Handbibliothek um ein wichtiges neues Referenzwerk ergänzen. Mithilfe von Beschichtungen lassen sich die Oberflächeneigenschaften von Geräten, unabhängig von den zugrunde liegenden Bulk-Eigenschaften, kontrollieren. Sie sind oftmals für die Leistungsfähigkeit eines Gerätes ausschlaggebend und werden immer häufiger eingesetzt. Dieses Buch bietet eine Einführung in viele der wichtigsten Beschichtungsarten, die bei modernen Medizingeräten zum Einsatz kommen, und…mehr
Mit dem "Handbook of Biomedical Coatings and Deposition Technologies" können Entwickler und Hersteller von medizinischen Geräten ihre Handbibliothek um ein wichtiges neues Referenzwerk ergänzen. Mithilfe von Beschichtungen lassen sich die Oberflächeneigenschaften von Geräten, unabhängig von den zugrunde liegenden Bulk-Eigenschaften, kontrollieren. Sie sind oftmals für die Leistungsfähigkeit eines Gerätes ausschlaggebend und werden immer häufiger eingesetzt. Dieses Buch bietet eine Einführung in viele der wichtigsten Beschichtungsarten, die bei modernen Medizingeräten zum Einsatz kommen, und beschreibt die Anwendungsverfahren und Methoden, mit denen die Wirksamkeit von Beschichtungen getestet wird. Für Entwickler von neuen medizinischen Geräten und Gerätehersteller stellt dieses wichtige Werk eine Entscheidungshilfe dar, wenn es darum geht, ob mit einer Beschichtung eine bestimmte Funktion erreicht werden kann und ob bei bestimmten Anwendungen Einschränkungen zu erwarten sind. Auch für Studierende der Materialwissenschaften und Werkstofftechnik mit Interesse an Medizingeräten ist dieses als Praktikerbuch konzipierte Werk mit seinen vielen Beispielen zu Beschichtungen und unzähligen Literaturverweisen eine große Hilfe. Neben Kapiteln zu antimikrobiellen und biokompatiblen Beschichtungen, zu Beschichtungen mit integrierten Arzneistoffen, strahlenundurchlässigen Beschichtungen und Beschichtungen, die einer Oberfläche Härte verleihen, enthält dieses Praktikerbuch Kapitel mit Beschreibungen zu wichtigen Prozessen der Flüssigbeschichtung, plasmabasierten Verfahren und Techniken der chemischen Gasphasenabscheidung. Viele Arten von Beschichtungen lassen sich mit verschiedenen Verfahren aufbringen. Diese unterschiedlichen Technologien mit ihren designinherenten Vor- und Nachteilen, ihren herstellungsbedingten und ökonomischen Einschränkungen werden erläutert. Das Kapitel zu regulatorischen Aspekten befasst sich mit relevanten Vermarktungsperspektiven für diese Beschichtungen und medizinischen Geräte.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Dr. David Glocker has worked in the fields of thin film deposition and plasma treatment for over 35 years. He spent fourteen years at the Eastman Kodak Company, where he led a group responsible for research on PVD coatings and coating processes and methods for the plasma modification of polymers. In 1993 he founded Isoflux Incorporated to manufacture cylindrical magnetron sputtering cathodes and develop coating processes employing that technology. Several medical device manufacturers now use Isoflux cathodes and related patents in both research and manufacturing. Dr. Glocker is an inventor or co-inventor on 32 US patents as well as a number of foreign counterparts and is the author of numerous articles and presentations. He recently retired from Isoflux and consults. Dr. Shrirang Ranade, Technical Development Leader at Genentech, Inc., a member of the Roche Group, has spent over 15 years working within large medical device and Pharma (F. Hoffman-La Roche, Johnson & Johnson and Boston Scientific) in the field of biomaterials, coatings and drug delivery devices. He obtained a Bachelor of Engineering from the University of Poona, a Master of Science from the University of Manchester Institute of Science & Technology and later a Ph.D. in Polymer Science from the University of Connecticut. Through his career he has been involved in research and development of medical devices for combination products in several forms: coronary drug eluting stents, balloon catheters, sinuplasty devices, orthopaedic scaffolds, biodegradable coatings and lately an implantable ocular drug delivery system.
Inhaltsangabe
Preface xxi Part 1 Introduction 1 1 Historical Perspectives on Biomedical Coatings in Medical Devices 3 M. Hendriks and P.T. Cahalan 1.1 Introduction 4 1.2 Improving Physical Properties of Biomaterials: Hydrophilic, Lubricious Coatings 7 1.3 Modulating Host-Biomaterial Interactions: Biologically Active Coatings 7 1.4 Bioinert Coatings Redressed: Nonfouling Coatings 15 1.5 Future Biomedical Coatings 16 References 18 Part 2 Coating Applications 27 2 Antimicrobial Coatings and Other Surface Modifications for Infection Prevention 29 Marc W. Mittelman and Nimisha Mukherjee 2.1 Introduction 29 2.2 Genesis of Device-Related Infections 35 2.3 Antimicrobial Coatings 38 2.4 Non-Eluting Antimicrobial Surfaces 49 2.5 Coating and Surface Modification Technologies 53 2.6 Regulatory Considerations 57 2.7 Future Challenges 58 References 61 3 Drug Delivery Coatings for Coronary Stents 75 Shrirang V. Ranade and Kishore Udipi 3.1 Introduction 75 3.2 Polymer Coatings for DES 81 3.3 Biostable (Non-Bioabsorbable) Polymers 86 3.4 Bioabsorbable Polymers 99 3.5 Concluding Remarks 103 References 104 4 Coatings for Radiopacity 115 Scott Schewe and David Glocker 4.1 Principles of Radiography 115 4.2 Use of Radiopaque Materials in Medical Devices 116 4.3 Radiopaque Fillers 117 4.4 Types of Radiopaque Fillers 117 4.5 Other Radiographic Materials and Coating Systems 121 4.6 Radiopaque Coatings by Physical Vapor Deposition 122 4.7 Challenges in Producing Radiopaque Coatings Using PVD 124 4.8 Gold Radiopaque Coatings 125 4.9 Tantalum Radiopaque Coatings 126 4.10 Summary 129 References 130 5 Biocompatibility and Medical Device Coatings 131 Joe McGonigle, Thomas J. Webster, and Garima Bhardwaj 5.1 Introduction 131 5.2 Challenges with Medical Devices 134 5.3 Examples of Products Coated to Improve Biocompatibility 148 5.4 Types of Biocompatible Coatings 157 5.5 Commercialization 170 5.6 Summary 172 References 172 6 Tribological Coatings for Biomedical Devices 181 Peter Martin 6.1 Introduction 181 6.2 Hard Thin Film Coatings for Implants 187 6.3 Binary Carbon-Based Thin Film Materials: Diamond, Hard Carbon and Amorphous Carbon 194 6.4 Progress of DLC, ta-C and a-C:H Films for Hip and Knee Implants 200 6.5 Wear-Resistant Coatings for Stents and Catheters 208 6.6 Wear-Resistant Coatings for Angioplasty Devices 210 6.7 Scalpel Blades and Surgical Instruments 211 6.8 Multifunctional, Nanostructured, Nanolaminate, and Nanocomposite Tribological Materials 211 References 222 Part 3 Coating and Surface Modification Methods 233 7 Dip Coating 235 Donald M. Copenhagen 7.1 Description and Basic Steps 235 7.2 Equipment and Coating Application 236 7.3 Coating Solution Containers 237 7.4 Coating Parameters and Controls 238 7.5 Role of Solution Viscosity 240 7.6 Coating Problems 241 7.7 Process Considerations 244 8 Inkjet Technology and Its Application in Biomedical Coating Bogdan V. Antohe, David B. Wallace, and Patrick W. Cooley 247 8.1 Introduction 247 8.2 Inkjet Background 248 8.3 Equipment Used 260 8.4 Capabilities 268 8.5 Limitations and Ways around Them 280 8.6 Manufacturing Advantages and Future Directions 293 8.7 Conclusions 299 References 300 9 Direct Capillary Printing in Medical Device Manufacture 309 William J. Grande 9.1 Introduction 309 9.2 Fundamental Elements of Direct Capillary Printing 320 9.3 Practical Operational Considerations 337 9.4 Manufacturing Considerations 349 9.5 Medical Device Examples 352 9.6 Conclusions 367 Acknowledgments 369 References 369 10 Sol-Gel Coating Methods in Biomedical Systems 373 Bakul C. Dave 10.1 Introduction 374 10.2 Overview of Sol-Gel Coatings in Biomedical Systems 377 10.3 The Sol-Gel Process 381 10.4 Coating Methods and Processes 385 10.5 Factors influencing Coatings Characteristics/Performance 390 10.6 Summary and Concluding Remarks 394 References 395 11 Chemical Vapor Deposition 403 Kenneth K. S. Lau 11.1 Introduction 403 11.2 Process Description 405 11.3 Process Mechanism 410 11.4 Technology Advances 414 11.5 Future Outlook 442 References 443 12 Introduction to Plasmas Used for Coating Processes 457 David A. Glocker 12.1 Introduction 457 12.2 DC Glow Discharges 459 12.3 RF Glow Discharges 463 12.4 RF Diode Glow Discharges 464 12.5 Ionization in RF Diode Glow Discharges 466 12.6 Inductively Coupled RF Discharges 466 12.7 Mid-Frequency AC Discharges 468 12.8 Pulsed DC Discharges 469 12.9 Comparison of Plasma Properties 470 12.10 Plasma Species 470 12.11 Summary 471 References 472 13 Ion Implantation: Tribological Applications 473 Peter Martin 13.1 Introduction 473 13.2 Applications 474 13.3 Nanocrystalline Diamond 487 Reference 492 14 Plasma-Enhanced Chemical Vapor Deposition 495 Kenneth K. S. Lau 14.1 Introduction 495 14.2 Process Description 497 14.3 Plasma Effects on Materials Deposition 501 14.4 Future Outlook 520 References 521 15 Sputter Deposition and Sputtered Coatings for Biomedical Applications 531 David A. Glocker 15.1 Introduction 531 15.2 Overview of Sputter Coating 533 15.3 Characteristics of Sputtered Atoms 536 15.4 Sputtering Cathodes 539 15.5 Relationship between Process Parameters and Coating Properties 541 15.6 Biased Sputtering 544 15.7 Adhesion and Stress in Sputtered Coatings 545 15.8 Sputtering Electrically Insulating Materials 546 15.9 Recent Developments 549 15.10 Summary and Conclusions 549 References 550 16 Cathodic Arc Vapor Deposition 553 Gary Vergason 16.1 Introduction 553 16.2 Medical Uses of Cathodic Arc Titanium Nitride Coatings 556 16.3 Brief History and Commercial Advancement of Cathodic Arcs 557 16.4 Review of Arc Devices 559 16.5 Description of PVD Coating Manufacturing 561 16.6 Macroparticle Generation and Mitigation 567 16.7 Considerations for Coating Success 568 16.8 Materials Used in Biomedical PVD Coatings 576 References 576 Part 4 Functional Tests 581 17 Antimicrobial Coatings Efficacy Evaluation 583 Nimisha Mukherjee and Marc W. Mittelman 17.1 Introduction 583 17.2 In-Vitro Methods 584 17.3 In-Vivo (Animal) Methods 590 17.4 Equipment and Laboratory Resources 590 17.5 Human Clinical Trial Considerations 590 17.6 Regulatory Considerations 590 References 596 18 Mechanical Characterization of Biomaterials: Functional Tests for Hardness 605 Vincent Jardret 18.1 Introduction 605 18.2 Basic Principles of Hardness and Indentation Testing 607 18.3 Depth-Sensing Indentation Testing 611 18.4 Dynamic Indentation Testing: A More Advanced Hardness Measurement Technique for More Complex Material Behavior 617 18.5 Special Case of Coatings Configuration under Indentation Testing 626 18.6 Conclusions 628 References 629 19 Adhesion Measurement of Thin Films and Coatings: Relevance to Biomedical Applications 631 Wei-Sheng Lei, Kash Mittal, and Ajay Kumar 19.1 Introduction 631 19.2 Mechanical Test Methods of Adhesion Measurement 634 19.3 Summary and Remarks 654 Appendix 656 References 665 20 Functional Tests for Biocompatability 671 Joe McConigle and Thomas J. Webster 20.1 Introduction 671 20.2 Inflammation 672 20.3 Blood Compatibility 675 20.4 Wound Healing 685 20.5 Encapsulation 688 20.6 Tissue Integration 691 20.7 Vascularization 692 20.8 Toxicity 699 20.9 Infection 700 20.10 When to Move In Vivo? 701 References 702 21 Analytical Requirements for Drug Eluting Stents 707 Lori Alquier and Shrirang Ranade 21.1 Introduction 707 21.2 Instrumentation 708 21.3 API and Excipient Characterization 709 21.4 Analytical Methods 712 21.5 Conclusion 719 References 719 Part 5 Regulatory Overview 723 22 Regulations for Medical Devices and Coatings 725 Robert J. Klepinski 22.1 Introduction 725 22.2 Types of Regulated Products 726 22.3 Scope of Regulation 732 22.4 Marketing Clearance of Medical Devices 733 22.5 Comparison to EU Regulation 737 22.6 Good Manufacturing Practices 737 Part 6 Future of Coating Technologies 743 23 The Future of Biomedical Coatings Technologies 745 Shrirang Ranade and David Glocker 23.1 Introduction 745 23.2 The Continuing Evolution of Biomaterials 749 23.3 Tissue Engineering and Regenerative Medicine 749 23.4 Coating Process Development 750 References 751
Preface xxi Part 1 Introduction 1 1 Historical Perspectives on Biomedical Coatings in Medical Devices 3 M. Hendriks and P.T. Cahalan 1.1 Introduction 4 1.2 Improving Physical Properties of Biomaterials: Hydrophilic, Lubricious Coatings 7 1.3 Modulating Host-Biomaterial Interactions: Biologically Active Coatings 7 1.4 Bioinert Coatings Redressed: Nonfouling Coatings 15 1.5 Future Biomedical Coatings 16 References 18 Part 2 Coating Applications 27 2 Antimicrobial Coatings and Other Surface Modifications for Infection Prevention 29 Marc W. Mittelman and Nimisha Mukherjee 2.1 Introduction 29 2.2 Genesis of Device-Related Infections 35 2.3 Antimicrobial Coatings 38 2.4 Non-Eluting Antimicrobial Surfaces 49 2.5 Coating and Surface Modification Technologies 53 2.6 Regulatory Considerations 57 2.7 Future Challenges 58 References 61 3 Drug Delivery Coatings for Coronary Stents 75 Shrirang V. Ranade and Kishore Udipi 3.1 Introduction 75 3.2 Polymer Coatings for DES 81 3.3 Biostable (Non-Bioabsorbable) Polymers 86 3.4 Bioabsorbable Polymers 99 3.5 Concluding Remarks 103 References 104 4 Coatings for Radiopacity 115 Scott Schewe and David Glocker 4.1 Principles of Radiography 115 4.2 Use of Radiopaque Materials in Medical Devices 116 4.3 Radiopaque Fillers 117 4.4 Types of Radiopaque Fillers 117 4.5 Other Radiographic Materials and Coating Systems 121 4.6 Radiopaque Coatings by Physical Vapor Deposition 122 4.7 Challenges in Producing Radiopaque Coatings Using PVD 124 4.8 Gold Radiopaque Coatings 125 4.9 Tantalum Radiopaque Coatings 126 4.10 Summary 129 References 130 5 Biocompatibility and Medical Device Coatings 131 Joe McGonigle, Thomas J. Webster, and Garima Bhardwaj 5.1 Introduction 131 5.2 Challenges with Medical Devices 134 5.3 Examples of Products Coated to Improve Biocompatibility 148 5.4 Types of Biocompatible Coatings 157 5.5 Commercialization 170 5.6 Summary 172 References 172 6 Tribological Coatings for Biomedical Devices 181 Peter Martin 6.1 Introduction 181 6.2 Hard Thin Film Coatings for Implants 187 6.3 Binary Carbon-Based Thin Film Materials: Diamond, Hard Carbon and Amorphous Carbon 194 6.4 Progress of DLC, ta-C and a-C:H Films for Hip and Knee Implants 200 6.5 Wear-Resistant Coatings for Stents and Catheters 208 6.6 Wear-Resistant Coatings for Angioplasty Devices 210 6.7 Scalpel Blades and Surgical Instruments 211 6.8 Multifunctional, Nanostructured, Nanolaminate, and Nanocomposite Tribological Materials 211 References 222 Part 3 Coating and Surface Modification Methods 233 7 Dip Coating 235 Donald M. Copenhagen 7.1 Description and Basic Steps 235 7.2 Equipment and Coating Application 236 7.3 Coating Solution Containers 237 7.4 Coating Parameters and Controls 238 7.5 Role of Solution Viscosity 240 7.6 Coating Problems 241 7.7 Process Considerations 244 8 Inkjet Technology and Its Application in Biomedical Coating Bogdan V. Antohe, David B. Wallace, and Patrick W. Cooley 247 8.1 Introduction 247 8.2 Inkjet Background 248 8.3 Equipment Used 260 8.4 Capabilities 268 8.5 Limitations and Ways around Them 280 8.6 Manufacturing Advantages and Future Directions 293 8.7 Conclusions 299 References 300 9 Direct Capillary Printing in Medical Device Manufacture 309 William J. Grande 9.1 Introduction 309 9.2 Fundamental Elements of Direct Capillary Printing 320 9.3 Practical Operational Considerations 337 9.4 Manufacturing Considerations 349 9.5 Medical Device Examples 352 9.6 Conclusions 367 Acknowledgments 369 References 369 10 Sol-Gel Coating Methods in Biomedical Systems 373 Bakul C. Dave 10.1 Introduction 374 10.2 Overview of Sol-Gel Coatings in Biomedical Systems 377 10.3 The Sol-Gel Process 381 10.4 Coating Methods and Processes 385 10.5 Factors influencing Coatings Characteristics/Performance 390 10.6 Summary and Concluding Remarks 394 References 395 11 Chemical Vapor Deposition 403 Kenneth K. S. Lau 11.1 Introduction 403 11.2 Process Description 405 11.3 Process Mechanism 410 11.4 Technology Advances 414 11.5 Future Outlook 442 References 443 12 Introduction to Plasmas Used for Coating Processes 457 David A. Glocker 12.1 Introduction 457 12.2 DC Glow Discharges 459 12.3 RF Glow Discharges 463 12.4 RF Diode Glow Discharges 464 12.5 Ionization in RF Diode Glow Discharges 466 12.6 Inductively Coupled RF Discharges 466 12.7 Mid-Frequency AC Discharges 468 12.8 Pulsed DC Discharges 469 12.9 Comparison of Plasma Properties 470 12.10 Plasma Species 470 12.11 Summary 471 References 472 13 Ion Implantation: Tribological Applications 473 Peter Martin 13.1 Introduction 473 13.2 Applications 474 13.3 Nanocrystalline Diamond 487 Reference 492 14 Plasma-Enhanced Chemical Vapor Deposition 495 Kenneth K. S. Lau 14.1 Introduction 495 14.2 Process Description 497 14.3 Plasma Effects on Materials Deposition 501 14.4 Future Outlook 520 References 521 15 Sputter Deposition and Sputtered Coatings for Biomedical Applications 531 David A. Glocker 15.1 Introduction 531 15.2 Overview of Sputter Coating 533 15.3 Characteristics of Sputtered Atoms 536 15.4 Sputtering Cathodes 539 15.5 Relationship between Process Parameters and Coating Properties 541 15.6 Biased Sputtering 544 15.7 Adhesion and Stress in Sputtered Coatings 545 15.8 Sputtering Electrically Insulating Materials 546 15.9 Recent Developments 549 15.10 Summary and Conclusions 549 References 550 16 Cathodic Arc Vapor Deposition 553 Gary Vergason 16.1 Introduction 553 16.2 Medical Uses of Cathodic Arc Titanium Nitride Coatings 556 16.3 Brief History and Commercial Advancement of Cathodic Arcs 557 16.4 Review of Arc Devices 559 16.5 Description of PVD Coating Manufacturing 561 16.6 Macroparticle Generation and Mitigation 567 16.7 Considerations for Coating Success 568 16.8 Materials Used in Biomedical PVD Coatings 576 References 576 Part 4 Functional Tests 581 17 Antimicrobial Coatings Efficacy Evaluation 583 Nimisha Mukherjee and Marc W. Mittelman 17.1 Introduction 583 17.2 In-Vitro Methods 584 17.3 In-Vivo (Animal) Methods 590 17.4 Equipment and Laboratory Resources 590 17.5 Human Clinical Trial Considerations 590 17.6 Regulatory Considerations 590 References 596 18 Mechanical Characterization of Biomaterials: Functional Tests for Hardness 605 Vincent Jardret 18.1 Introduction 605 18.2 Basic Principles of Hardness and Indentation Testing 607 18.3 Depth-Sensing Indentation Testing 611 18.4 Dynamic Indentation Testing: A More Advanced Hardness Measurement Technique for More Complex Material Behavior 617 18.5 Special Case of Coatings Configuration under Indentation Testing 626 18.6 Conclusions 628 References 629 19 Adhesion Measurement of Thin Films and Coatings: Relevance to Biomedical Applications 631 Wei-Sheng Lei, Kash Mittal, and Ajay Kumar 19.1 Introduction 631 19.2 Mechanical Test Methods of Adhesion Measurement 634 19.3 Summary and Remarks 654 Appendix 656 References 665 20 Functional Tests for Biocompatability 671 Joe McConigle and Thomas J. Webster 20.1 Introduction 671 20.2 Inflammation 672 20.3 Blood Compatibility 675 20.4 Wound Healing 685 20.5 Encapsulation 688 20.6 Tissue Integration 691 20.7 Vascularization 692 20.8 Toxicity 699 20.9 Infection 700 20.10 When to Move In Vivo? 701 References 702 21 Analytical Requirements for Drug Eluting Stents 707 Lori Alquier and Shrirang Ranade 21.1 Introduction 707 21.2 Instrumentation 708 21.3 API and Excipient Characterization 709 21.4 Analytical Methods 712 21.5 Conclusion 719 References 719 Part 5 Regulatory Overview 723 22 Regulations for Medical Devices and Coatings 725 Robert J. Klepinski 22.1 Introduction 725 22.2 Types of Regulated Products 726 22.3 Scope of Regulation 732 22.4 Marketing Clearance of Medical Devices 733 22.5 Comparison to EU Regulation 737 22.6 Good Manufacturing Practices 737 Part 6 Future of Coating Technologies 743 23 The Future of Biomedical Coatings Technologies 745 Shrirang Ranade and David Glocker 23.1 Introduction 745 23.2 The Continuing Evolution of Biomaterials 749 23.3 Tissue Engineering and Regenerative Medicine 749 23.4 Coating Process Development 750 References 751
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