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Implantable neural prostheses 2: Techniques and engineering approaches

Tác giả: Greenbaum, Elias; Zhou, David D.

Chủ đề:

Chủ đề: Medicine; Implantable Neural; Prostheses; Techniques; Approaches

Nhà xuất bản: Springer

Năm xuất bản: 2010

Loại tài liệu: Book

Mô tả vật lý: 386 p.

Định danh: 978-0-387-98120-8

Ngôn ngữ: en

Đọc trực tuyến

This book,is part two of a two-volume sequence that describes state-of-the-art advances in techniques associated with implantable neural prosthetic devices. The techniques covered include biocompatibility and biostability, hermetic packaging, electrochemical techniques for neural stimulation applications, novel electrode materials and testing, thin-?lm ?exible microelectrode arrays, in situ char- terization of microelectrode arrays, chip-size thin-?lm device encapsulation, microchip-embedded capacitors and microelectronics for recording, stimulation, and wireless telemetry. The design process in the development of medical devices is also discussed. Advances in biomedical engineering, microfabrication technology, and neu- science have led to improved medical-device designs and novel functions. However, many challenges remain. This book focuses on the engineering approaches, R&D advances, and technical challenges of medical implants from an engineering p- spective. We are grateful to leading researchers from academic institutes, national laboratories, as well as design engineers and professionals from the medical device industry who have contributed to the book. Part one of this series covers designs of implantable neural prosthetic devices and their clinical applications.

Cover
Science and Technology of Bio-Inert Thin Films as Hermetic-Encapsulating Coatings for Implantable Biomedical Devices: Application to Implantable Microchip in the Eye for the Artificial Retina
- 1 Scientific and Technological State-of-the-Art of Bio-inert Coatings for Encapsulation of Implantable Microchips
- 2 Process and Design Considerations for Hermetic Bio-inert Coatings for Implantable Artificial Retina
  - 2.1 Materials for Hermetic-Encapsulating Coatings
  - 2.2 Carbon-Based Ultrananocrystalline Diamond (UNCD) Coatings and Film
  - 2.3 Oxide Films Alone or as Component of Hybrid UNCD/Oxide for Hermetic-Encapsulating Coatings
- 3 Characterization of Bio-inert Hermetic-Encapsulating Coatings
  - 3.1 Characterization of Chemical, Microstructural, and Morphological Properties of UNCD Coatings
  - 3.2 Characterization of Microstructural and Morphological Properties of Oxide Films for Hybrid Hermetic-Encapsulating Coatings
  - 3.3 Characterization of Electrochemical Performance in Saline Solution for Hermetic UNCD Coatings
  - 3.4 Characterization of Electrochemical Performance in Saline Solution for Hermetic Oxide Films
  - 3.5 Characterization of UNCD/CMOS Integration
  - 3.6 In Vivo Animal Tests of Hermetic-Encapsulating Coatings for Artificial Retina
- 4 Challenges for Bio-inert Microchip Encapsulation Hermetic Coatings
- 5 Conclusions and a Future Outlook
- References
Technology Advances and Challenges in Hermetic Packaging for Implantable Medical Devices
- 1 Introduction
  - 1.1 Hermetic Packaging Technology Advances
  - 1.2 Significance of Hermetic Packaging for Implantable Medical Devices
- 2 General Packaging Considerations for Implantable Medical Devices
  - 2.1 Biocompatibility
  - 2.2 Hermeticity Requirement
  - 2.3 Outgassing of Internal Materials
  - 2.4 Wireless Communication
  - 2.5 Package Heating
  - 2.6 Coefficient of Thermal Expansion Compatibility
- 3 Types of Hermetic Sealing and Their Applications
  - 3.1 Polymer Encapsulation
  - 3.2 Glass-to-Metal Seal
  - 3.3 Ceramic-to-Metal Feedthrough
  - 3.4 Ceramic-to-Metal Seal
    - 3.4.1 Active Brazing
    - 3.4.2 Nonactive Brazing
    - 3.4.3 Diffusion Bonding of Ceramic-to-Metal
  - 3.5 Hermetic Seal with Fusion Welding
  - 3.6 Conductive Vias on Ceramic Substrate
- 4 Testing Methods for Hermetic Sealing of Implantable Medical Devices
  - 4.1 Mechanical and Environmental Tests
  - 4.2 Hermeticity Testing Methods and Their Limitations
  - 4.3 Biocompatibility Tests
  - 4.4 Corrosion Tests
  - 4.5 Morphological and Microstructural Characterization
  - 4.6 Accelerated Life Test
  - 4.7 X-Ray Microscopy
  - 4.8 Acoustic Microscopy
- 5 Challenges of Hermetic Packaging for Implantable Medical Devices
  - 5.1 Long-Term Stability of Ceramic Materials
  - 5.2 Metals and Alloys Corrosion
  - 5.3 Challenges in Accelerated Life Test
  - 5.4 Hermeticity Test Reliability for Miniature Devices
  - 5.5 Design challenges for Miniature Devices
  - 5.6 Hermetic Packaging of MEMS for Implantable Medical Devices
- 6 Conclusions
- References
The Biocompatibility and Biostability of New Cardiovascular Materials and Devices
- 1 Introduction
- 2 Background
  - 2.1 Learning from the Past
  - 2.2 Environmental Stress Cracking (ESC)
  - 2.3 Metal Ion Oxidation (MIO)
  - 2.4 Subclavian Crush
  - 2.5 Why Were These Mechanisms Not Discovered Before Market Release?
  - 2.6 Chronic Removability of Transvenous Cardiac Leads
- 3 Risk Assessment
- 4 Material Biocompatibility Testing
  - 4.1 Substantially Equivalent Materials
  - 4.2 New Materials
  - 4.3 Phase 1 Tests (ISO 10993-1)
    - 4.3.1 Phase 2 Tests
- 5 Potential for Biodegradation
- 6 New Material Stability Testing In Vitro
  - 6.1 Metals
  - 6.2 Polymers
- 7 In Vivo Materials Testing
- 8 Device Implants in Animal Models
- 10 Market Release and Postmarket Surveillance
  - 10.1 Returned Products Analysis
  - 10.2 Postmarket Clinical Studies
- 9 Human Clinical Implants
- 11 Summary and Conclusions
- References
The Electrochemistry of Charge Injection at the Electrode/Tissue Interface
- 1 Physical Basis of the Electrode/Electrolyte Interface
  - 1.1 Capacitive/Non-Faradaic Charge Transfer
  - 1.2 Faradaic Charge Transfer and the Electrical Model of the Electrode/Electrolyte Interface
  - 1.3 Reversible and Irreversible Faradaic Reactions
  - 1.4 The Origin of Electrode Potentials and the Three-Electrode Electrical Model
  - 1.5 Faradaic Processes: Quantitative Description
  - 1.6 Ideally Polarizable Electrodes and Ideally Nonpolarizable Electrodes
- 2 Charge Injection Across the Electrode/Electrolyte Interface During Electrical Stimulation
  - 2.1 Charge Injection During Pulsing: Interaction of Capacitive and Faradaic Mechanisms
  - 2.2 Methods of Controlling Charge Delivery During Pulsing
  - 2.3 Charge Delivery by Current Control
  - 2.4 Pulse train response during current control
  - 2.5 Electrochemical reversal
  - 2.6 Charge delivery by a voltage source between the working electrode and counter electrode
- 3 Materials Used as Electrodes for Charge Injection and Reversible Charge Storage Capacity
- 4 Charge Injection for Extracellular Stimulation of Excitable Tissue
- 5 Mechanisms of Damage
- 6 Design Compromises for Efficacious and Safe Electrical Stimulation
- References
Implantable Neural Prostheses 2: Techniques and Engineering Approaches
- BIOLOGICAL AND MEDICAL PHYSICS, BIOMEDICAL ENGINEERING
- ISBN 0387981195
- Preface
- Contents
- Contributors
- Acronyms
Title page
Copyright 2010
In Situ Characterization of Stimulating Microelectrode Arrays: Study of an Idealized Structure Based on Argus II Retinal implants
- 1 Introduction
- 2 Physical Analysis of Argus II Electrode Array and Representative Analogs
  - 2.1 The Argus II Electrode Array
  - 2.2 Electrical Properties of the Vitreous
    - 2.2.1 Stimulation Waveforms
    - 2.2.2 AC and DC Impedance
    - 2.2.3 Retinal Tissues
  - 2.3 Electrical Stimulation, Electrodes, and Systems
    - 2.3.1 Electrode Configuration
    - 2.3.2 Electrode Size and Spacing
    - 2.3.3 Materials and Stability
  - 2.4 Return Electrode
    - 2.4.1 Functions
    - 2.4.2 Design
- 3 Characterization of Simplified Argus II Analogs
  - 3.1 Single Electrode
    - 3.1.1 Design and Material
  - 3.2 9-Electrode Array Structure
- 4 Numerical Simulation of Argus II Simplified Model
  - 4.1 Numerical Simulation
  - 4.2 Single Electrode
  - 4.3 60-Electrode Array Cross-Talk Modeling
- 5 Conclusions
- References
Thin-Film Microelectrode Arrays for Biomedical Applications
- 1 Introduction
- 2 Microfabrication Methods and Materials
  - 2.1 Micromachining
  - 2.2 Microfabricated Microelectrodes
  - 2.3 Silicon-Based Thin-Film Electrodes
    - 2.3.1 Planar Silicon-Based Electrodes
    - 2.3.2 Three-Dimensional Silicon-Based Electrodes
    - 2.3.3 Sieve Electrodes
  - 2.4 Metal-Based Thin-Film Electrodes
  - 2.5 Ceramic-Based Thin-Film Electrodes
  - 2.6 Polymer-Based Thin-Film Electrodes
    - 2.6.1 Polyimide
    - 2.6.2 Other Polymer-Based Microelectrodes
  - 2.7 Nanostructured Electrodes
    - 2.7.1 Carbon Nanotube Coatings
    - 2.7.2 Conductive Polymer Nanotubes
- 3 Central Nervous System Response to Implanted Devices
  - 3.1 Reactive Gliosis
  - 3.2 Histology
  - 3.3 Glial Scar and Tissue Impedance
- 4 Implant Biocompatibility
  - 4.1 Microelectrode Structure
  - 4.2 Pharmacology
  - 4.3 Hybrid Structures
- 5 Conclusion
- References
Stimulation Electrode Materials and Electrochemical TestingMethods
- 1 Introduction
- 2 Electrode Reactions
  - 2.1 Electrode Interface
  - 2.2 Electrical Double Layer
  - 2.3 Reversible Metal Oxidation/Reduction
  - 2.4 Irreversible Chemical Reaction
  - 2.5 Electrolyte Resistance
- 3 Common Electrochemical Tests and Electrode Materials
  - 3.1 Cyclic Voltammetry
  - 3.2 Platinum
  - 3.3 Titanium
  - 3.4 Iridium
  - 3.5 Effect of Protein
  - 3.6 Impedance Measurement
- 4 Neural Stimulation Settings Which Affect Charge Injections
  - 4.1 Basis of Neural Stimulation
  - 4.2 Components of a Neural Stimulation System
  - 4.3 Monophasic Voltage Stimulation
  - 4.4 Constant Voltage vs. Constant Current
  - 4.5 Analysis of Constant-Current Electrode-Voltage Waveform
  - 4.6 Current Control with Passive Recharge
  - 4.7 Active Recharge
  - 4.8 Cathodic Bias
  - 4.9 Bipolar vs. Monopolar Stimulation
- 5 Other Measurement Techniques
  - 5.1 Electrode-Potential Measurement
  - 5.2 Pulse Clamp
  - 5.3 Computer Simulation
  - 5.4 Dissolution Testing
  - 5.5 Inductively Coupled Plasma (ICP)
- 6 Summary
- References
Conducting Polymers in Neural Stimulation Applications
- 1 Introduction
- 2 Neural Stimulation and Electrode Materials
  - 2.1 Charge Transfer Processes During Stimulation
  - 2.2 Electrodes for Neural Stimulation Implants
- 3 Conducting Polymers
  - 3.1 Various Conducting Polymers
    - 3.1.1 Polypyrrole
    - 3.1.2 Polyaniline
    - 3.1.3 PEDOT
  - 3.2 Methods of Preparing Conducting Polymers
  - 3.3 Biomedical Applications of Conducting Polymers
- 4 Challenges of Conducting Polymers for Chronic Neural Stimulation
  - 4.1 Electrode Impedance
  - 4.2 Polymer Volume Changes Under Electrical Stimulation
  - 4.3 Charge Injection Capability
  - 4.4 Biocompatibility
  - 4.5 Long-Term Stability
- 5 Conclusions
- References
Microelectronics of Recording, Stimulation, and Wireless Telemetry for Neuroprosthetics: Design and Optimization
- 1 Introduction
- 2 Basic Building Blocks
  - 2.1 Amplifier
    - 2.1.1 Negative-Feedback Amplifier
    - 2.1.2 Chopper Amplifier
  - 2.2 Filter
    - 2.2.1 Passive R-C Filter
    - 2.2.2 Active Filter
    - 2.2.3 Switched-Capacitor Filter
  - 2.3 ADC
- 3 Subsystem Design
  - 3.1 Front-End Blocks for Neural Recording
    - 3.1.1 System Architecture and Circuit Modeling
    - 3.1.2 System Resolution
    - 3.1.3 Trade-Off Between System Power and Chip Area
  - 3.2 Neural-Signal Processing Unit
    - 3.2.1 Theory
    - 3.2.2 Spike Sorting Methods and Results
  - 3.3 Neuromuscular Current Stimulator with High-Compliance Voltage
  - 3.4 Wireless Telemetry
    - 3.4.1 Power Telemetry
    - 3.4.2 Data Telemetry
- 4 System Design Examples
  - 4.1 Recording: 128-Channel Wireless Neural-Recording System
    - 4.1.1 Chip Architecture
    - 4.1.2 Front-End Block Design
    - 4.1.3 Neural-Signal Processing Engine
    - 4.1.4 UWB Telemetry
    - 4.1.5 Test Results
    - 4.1.6 60-Hz Power Interference Issue
  - 4.2 Stimulation: 256-Channel Retinal Prosthesis Chip
    - 4.2.1 System Architecture
    - 4.2.2 Stimulator Pixel Design
    - 4.2.3 Dual-Band Power and Data Telemetry Design
- 5 Summary
- References
Microchip-Embedded Capacitors for Implantable NeuralStimulators
- 1 Introduction
- 2 Design and Process Considerations for Oxide Films for Microchip-Embedded Capacitors
  - 2.1 Materials for High-Dielectric Constant (K) Layers
  - 2.2 TiAlOx or TiO 2 /Al 2 O 3 Superlattice Oxide Layers
  - 2.3 Synthesis and Deposition Techniques of Oxide Films for Embedded Capacitors
    - 2.3.1 Sputter-Deposition
    - 2.3.2 Atomic Layer Deposition (ALD)
- 3 Characterization of Oxide Films for Microchip Embedded Capacitors
  - 3.1 Characterization of Oxide/Silicon Interface and Structure
  - 3.2 Electrical Performance of High-K Dielectric Oxide
- 4 Challenges for Oxide Films as High-K Dielectric Films for Microchip-Embedded Capacitors
- 5 Conclusions
- References
An Effective Design Process for the Successful Developmentof Medical Devices
- 1 Introduction
- 2 The Design Control Process for the Development of Medical Devices
  - 2.1 Overview of the Design Control Process
  - 2.2 Research and Development Phase
  - 2.3 General Design Control Philosophy
  - 2.4 Design and Development Planning
  - 2.5 Design Input
    - 2.5.1 Case Studies of Design Input Requirements
  - 2.6 Design Output
  - 2.7 Design Review
  - 2.8 Design Verification
  - 2.9 Design Validation
    - 2.9.1 Case Studies of Design Verification and Validation
  - 2.10 Design Transfer
  - 2.11 Design Changes
    - 2.11.1 Case Studies of the Design Changes Process
  - 2.12 Risk and Hazard Analysis
  - 2.13 Design History File
- 3 Conclusion
- References
Subject Index