Medical Devices Surgical and Image Guided Technologies 1st Edition by Martin Culjat, Rahul Singh, Hua Lee ISBN 978-0470549186 0470549181

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Product details: 

ISBN 10:  0470549181

ISBN 13: 978-0470549186

Author: Martin Culjat, Rahul Singh, Hua Lee

Addressing the exploding interest in bioengineering for healthcare applications, this book provides readers with detailed yet easy-to-understand guidance on biomedical device engineering. Written by prominent physicians and engineers, Medical Devices: Surgical and Image-Guided Technologies is organized into stand-alone chapters covering devices and systems in diagnostic, surgical, and implant procedures.

Assuming only basic background in math and science, the authors clearly explain the fundamentals for different systems along with such topics as engineering considerations, therapeutic techniques and applications, future trends, and more. After describing how to manage a design project for medical devices, the book examines the following:

Instruments for laparoscopic and ophthalmic surgery, plus surgical robotics
Catheters in vascular therapy and energy-based hemostatic surgical devices
Tissue ablation systems and the varied uses of lasers in medicine
Vascular and cardiovascular devices, plus circulatory support devices
Ultrasound transducers, X-ray imaging, and neuronavigation
An absolute must for biomedical engineers, Medical Devices: Surgical and Image-Guided Technologies is also an invaluable guide for students in all engineering majors and pre-med programs interested in exploring this fascinating field.

Table of contents: 

PART I INTRODUCTION TO MEDICAL DEVICES

1. Introduction

Martin Culjat

1.1 History of Medical Devices

1.2 Medical Device Terminology

1.3 Purpose of the Book

2. Design of Medical Devices

Gregory Nighswonger

2.1 Introduction

2.2 The Medical Device Design Environment

2.2.1 US Regulation

2.2.2 Differences in European Regulation

2.2.3 Standards

2.3 Basic Design Phases

2.3.1 Feasibility

2.3.2 Planning and Organization-Assembling the Design Team

2.3.3 When to Involve Regulatory Affairs

2.3.4 Conceptualizing and Review

2.3.5 Testing and Refinement

2.3.6 Proving the Concept

2.3.7 Pilot Testing and Release to Manufacturing

2.4 Postmarket Activities

2.5 Final Note

PART II MINIMALLY INVASIVE DEVICES AND TECHNIQUES

3. Instrumentation for Laparoscopic Surgery

Camellia Racu-Keefer, Scott Um, Martin Culjat, and Erik Dutson

3.1 Introduction

3.2 Basic Principles

3.3 Laparoscopic Instrumentation

3.3.1 Trocars

3.3.2 Standard Laparoscopic Instruments

3.3.3 Additional Laparoscopic Instruments

3.3.4 Specimen Retrieval Bags

3.3.5 Disposable Instruments

3.4 Innovative Applications

3.5 Summary and Future Applications

4. Surgical Instruments in Ophthalmology

Allen Y. Hu, Robert M. Beardsley, and Jean-Pierre Hubschman

4.1 Introduction

4.2 Cataract Surgery

4.2.1 Basic Technique

4.2.2 Principles of Phacoemulsification

4.2.3 Phacoemulsification Instruments

4.2.4 Phacoemulsification Systems

4.2.5 Future Directions

4.3 Vitreoretinal Surgery

4.3.1 Basic Techniques

4.3.2 Principles of Vitrectomy

4.3.3 Vitrectomy Instruments

4.3.4 Vitrectomy Systems

4.3.5 Future Directions

4.4 Other Ophthalmic Surgical Procedures

4.5 Conclusion

5. Surgical Robotics

Jacob Rosen

5.1 Introduction

5.2 Background and Leading Concepts

5.2.1 Human-Machine Interfaces: System Approach

5.2.2 Tissue Biomechanics

5.2.3 Teleoperation

5.2.4 Image-Guided Surgery

5.2.5 Objective Assessment of Skill

5.3 Commercial Systems

5.3.1 ROBODOC® (Curexo Technology Corporation)

5.3.2 daVinci (Intuitive Surgical)

5.3.3 Sensei® X (Hansen Medical)

5.3.4 RIO® MAKOplasty (MAKO Surgical Corporation)

5.3.5 CyberKnife (Accuray)

5.3.6 Renaissance™™ (Mazor Robotics)

5.3.7 ARTAS® System (Restoration Robotics, Inc.)

5.4 Trends and Future Directions

6. Catheters in Vascular Therapy

Axel Boese

6.1 Introduction

6.2 Historic Overview

6.3 Catheter Interventions

6.4 Catheter and Guide Wire Shapes and Configurations

6.4.1 Catheters

6.4.2 Guide Wires

6.5 Conclusion

PART III ENERGY DELIVERY DEVICES AND SYSTEMS

7. Energy-Based Hemostatic Surgical Devices

Amit P. Mulgaonkar, Warren Grundfest, and Rahul Singh

7.1 Introduction

7.2 History of Energy-Based Hemostasis

7.3 Energy-Based Surgical Methods and Their Effects on Tissues

7.3.1 Disambiguation

7.3.2 Thermal Effects on Tissues

7.4 Electrosurgery

7.4.1 Electrosurgical Theory

7.4.2 Cutting and Coagulation Techniques

7.4.3 Equipment

7.4.4 Considerations and Complications

7.5 Future Of Electrosurgery

7.6 Conclusion

8. Tissue Ablation Systems

Michael Douek, Justin McWilliams, and David Lu

8.1 Introduction

8.2 Evolving Paradigms in Cancer Therapy

8.3 Basic Ablation Categories and Nomenclature

8.4 Hyperthermic Ablation

8.5 Fundamentals of In Vivo Energy Deposition

8.6 Hyperthermic Ablation: Optimizing Tissue Ablation

8.7 Radiofrequency Ablation

8.8 RFA: Basic Principles

8.9 RFA: In Vivo Energy Deposition

8.10 Optimizing RFA

8.11 Other Hyperthermic Ablation Techniques

8.11.1 Microwave Ablation (MWA)

8.11.2 MWA: Basic Principles

8.11.3 MWA: In Vivo Energy Deposition

8.11.4 Optimizing MWA

8.12 Laser Ablation

8.13 Hypothermic Ablation

8.13.1 Cryoablation: Basic Concepts

8.13.2 Cryoablation: In Vivo Considerations

8.13.3 Optimizing Cryoablation Systems

8.14 Chemical Ablation

8.15 Novel Techniques

8.15.1 High Intensity Focused Ultrasound (HIFU)

8.15.2 Irreversible Electroporation (IRE)

8.16 Tumor Ablation and Beyond

9. Lasers in Medicine

Zachary Taylor, Asael Papour, Oscar Stafsudd, and Warren Grundfest

9.1 Introduction

9.1.1 Historical Perspective

9.1.2 Basic Operational Concepts

9.1.3 First Experimental MASER (Microwave Amplification by Stimulated Emission of Radiation)

9.2 Laser Fundamentals

9.2.1 Two-Level Systems and Population Inversion

9.2.2 Multiple Energy Levels

9.2.3 Mode of Operation

9.2.4 Beams and Optics

9.3 Laser Light Compared to Other Sources of Light

9.3.1 Temporal Coherence

9.3.2 Spectral Coherence (Line Width)

9.3.3 Beam Collimation

9.3.4 Short Pulse Duration

9.3.5 Summary

9.4 Laser-Tissue Interactions

9.4.1 Biostimulation

9.4.2 Photochemical Interactions

9.4.3 Photothermal Interactions

9.4.4

Ablation

9.4.5 Photodisruption

9.5 Lasers in Diagnostics

9.5.1 Optical Coherence Tomography

9.5.2 Fluorescence Angiography

9.5.3 Near Infrared Spectroscopy

9.6 Laser Treatments and Therapy

9.6.1 Overview of Current Medical Applications of Laser Technology

9.6.2 Retinal Photodynamic Therapy (Photochemical)

9.6.3 Transpupillary Thermal Therapy (TTT) (Photothermal)

9.6.4 Vascular Birth Marks (Photocoagulation)

9.6.5 Laser Assisted Corneal Refractive Surgery (Ablation)

9.7 Conclusions

PART IV IMPLANTABLE DEVICES AND SYSTEMS

10. Vascular and Cardiovascular Devices

Dan Levi, Allan Tulloch, John Ho, Colin Kealey, and David Rigberg

10.1 Introduction

10.2 Biocompatibility Considerations

10.3 Materials

10.3.1 316L Stainless Steel

10.3.2 Nitinol

10.3.3 Cobalt-Chromium Alloys

10.4 Stents

10.5 Closure Devices

10.6 Transcatheter Heart Valves

10.7 Inferior Vena Cava Filters

10.8 Future Directions-Thin Film Nitinol

10.9 Conclusion

11. Mechanical Circulatory Support Devices

Colin Kealey, Paymon Rahgozar, and Murray Kwon

11.1 Introduction

11.2 History

11.3 Basic Principles

11.3.1 Biocompatibility and Mechanical Circulatory Support Devices

11.3.2 Hemocompatibility: Microscopic Considerations

11.3.3 Hemocompatibility: Macroscopic Considerations

11.4 Engineering Considerations in Mechanical Circulatory Support

11.4.1 Overview

11.4.2 Pump Design

11.4.3 Positive Displacement Pumps

11.4.4 Rotary Pumps

11.4.5 Pulsatile Versus Nonpulsatile Flow

11.5 Devices

11.5.1 The HeartMate XVE Left Ventricular Assist System

11.5.2 The HeartMate II Left Ventricular Assist System

11.5.3 Short-Term Mechanical Circulatory Support: The Intraaortic Balloon Pump

11.5.4 Pediatric Mechanical Circulatory Support: The Berlin Heart

11.6 The Future of MCS Devices

11.6.1 CorAide

11.6.2 HeartMate III

11.6.3 HeartWare

11.6.4 VentrAssist

11.7 Summary

12. Orthopedic Implants

Sophia N. Sangiorgio, Todd S. Johnson, Jon Moseley, G. Bryan Cornwall, and Edward Ebramzadeh

12.1 Introduction

12.1.1 Overview

12.1.2 History

12.2 Basic Principles

12.2.1 Optimization for Strength and Stiffness

12.2.2 Maximization of Implant Fixation to Host Bone

12.2.3 Minimization of Degradation

12.2.4 Sterilization of Implants and Instrumentation

12.3 Implant Technologies

12.3.1 Total Hip Replacement

12.3.2 Technology in Total Knee Replacement

12.3.3 Technology in Spine Surgery

12.4 Summary

PART V IMAGING AND IMAGE-GUIDED TECHNIQUES

13. Endoscopy

Gregory Nighswonger

13.1 Introduction

13.2 Ancient Origins

13.3 Modern Endoscopy

13.3.1 Creating Cold Light

13.3.2 Introduction of Rod-Lens Technology

13.4 Principles of Modern Endoscopy

13.4.1 Optics

13.4.2 Mechanics

13.4.3 Electronics

13.4.4 Software

13.5 The Imaging Chain

13.5.1 Light Source (1)

13.5.2 Telescope (2)

13.5.3 Camera Head (3)

13.5.4 CCU Camera (4)

13.5.5 Video Cables (5)

13.5.6 Monitor (6)

13.5.7 Image Management Systems (7)

13.6 Endoscopes for Today

13.6.1 Rigid Endoscopes-Designs to Enhance Functionality

13.6.2 Less Traumatic Ureterorenoscopes

13.6.3 Advances in Flexible Endoscope Design

13.6.4 Broader Functionality with New Technologies

13.6.5 Enhancing Video Capabilities

13.7 Endoscopy’s Future

14. Medical Ultrasound Devices

Rahul Singh and Martin Culjat

14.1 Introduction

14.2 Basic Principles of Ultrasound

14.2.1 Basic Acoustic Physics

14.2.2 Reflection and Refraction

14.2.3 Attenuation

14.2.4

Piezoelectricity

14.2.5 Ultrasound Systems

14.2.6 Resolution and Bandwidth

14.2.7 Beam Characteristics

14.3 Ultrasound Transducer Design

14.3.1 Piezoelectric Material

14.3.2 Backing Layers and Damping

14.3.3 Matching Layers

14.3.4 Mechanical Focusing

14.3.5 Electrical Matching

14.3.6

Sector Scanners

14.3.7 Array Transducers

14.3.8 Transducer Array Fabrication

14.3.9 Regulatory Considerations

14.4 Applications of Medical Ultrasound

14.4.1 Image Guidance Applications

14.4.2 Intravascular and Intracardiac Applications

14.4.3 Intraoral and Endocavity Applications

14.4.4 Surgical Applications

14.4.5 Ophthalmic Ultrasound

14.4.6 Doppler and Doppler Applications

14.4.7 Therapeutic Applications

14.5 The Future of Medical Ultrasound

15. Medical X-ray Imaging

Mark Roden

15.1 Introduction

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Tags: Martin Culjat, Rahul Singh, Hua Lee, Medical Devices, Image Guided