| Description |
1 online resource |
| Contents |
Cover -- Half Title -- Title Page -- Copyright Page -- Table of Contents -- Preface -- Chapter 1: Manipulation of Mechanical and Functional Properties of the Ti-Au-Based Shape Memory Alloys by Transition Metal Introduction -- 1.1: Introduction -- 1.2: Experimental -- 1.2.1: Chemicals -- 1.2.2: Alloy Fabrication -- 1.2.3: Phase Identification and Lattice Parameter Analysis -- 1.2.4: Microstructure Observation and Composition Analysis -- 1.2.5: Mechanical Property Evaluations -- 1.2.5.1: Bending examinations -- 1.2.5.2: Tensile examinations -- 1.3: Ti-4Au-5M Alloy Systems |
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1.3.1: Cold Workability -- 1.3.2: Phase Identification -- 1.3.3: Mechanical Behavior Evaluations -- 1.3.3.1: Bending examinations -- 1.3.3.2: Continuous tensile examinations -- 1.3.3.3: Cyclic loading-unloading tensile examinations -- 1.3.4: Brief Summaries of the Ti-4Au-5M Alloys -- 1.4: Ti-4Au-5Cr-nTa Alloy System -- 1.4.1: Cold Workability -- 1.4.2: Phase Identification -- 1.4.3: Mechanical Behavior Evaluations -- 1.4.3.1: Continuous tensile examinations -- 1.4.3.2: Elongation vs Ta amount -- 1.4.3.3: Yielding stress vs Ta amount -- 1.4.3.4: UTS vs Ta amount -- 1.4.3.5: UTS vs yielding stress |
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1.4.3.6: Cyclic loading-unloading tensile examinations -- 1.4.4: Shape Recovery -- 1.4.5: Brief Summaries of the Ti-4Au-5Cr-nTa Alloys -- Chapter 2: Ceramics for Bone Repair and Cancer Therapy -- 2.1: Introduction -- 2.2: Ceramics for Bone Repair -- 2.2.1: Bioresponsive Materials -- 2.2.2: Antibacterial Materials -- 2.3: Ceramics for Cancer Therapy -- 2.3.1: Ceramics for Radiotherapy -- 2.3.2: Ceramics for Hyperthermia -- 2.4: Summary -- Chapter 3: Hydrophilic Treatment Using Atmospheric Pressure Low-Temperature Plasma -- 3.1: Introduction -- 3.2: Atmospheric Pressure Low-Temperature Plasma |
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3.2.1: Direct and Remote Processing -- 3.2.2: Dielectric Barrier Discharge -- 3.2.3: Multi-Gas Plasma Jet -- 3.3: Hydrophilic Treatment Using Atmospheric Pressure Low-Temperature Plasma -- 3.3.1: Evaluation Method of Hydrophilicity -- 3.3.2: Hydrophilization Effect on Polyimide Film -- 3.3.3: Duration of Hydrophilic Effect by Nitrogen Plasma Treatment -- 3.4: Hydrophilization Effect on Biomaterials -- 3.4.1: Hydrophilization Effect on PFA -- 3.4.2: Hydrophilization Effect on Silicone Rubber Sheet -- 3.5: Summary -- Chapter 4: Microwave Imaging Algorithms for Breast Cancer Detection |
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4.1: Introduction -- 4.2: Fundamental Principle -- 4.3: Imaging Algorithm for Breast Cancer Detection -- 4.4: Review of Recent Progress -- 4.5: Conclusion -- Chapter 5: Synergy of Data Glove-Based Motion Tracking and Functional Electrical Stimulation for Rehabilitation and Assisted Learning -- 5.1: Introduction -- 5.2: Components, Devices, and Equipment -- 5.2.1: Rapid Response Widely Stretchable CNT-Based Strain Sensors -- 5.2.2: High-Fidelity Data Gloves with Embedded CNT Strain Sensors -- 5.2.3: Belt-Shaped Multi-Pad Electrodes -- 5.2.4: Multichannel FES Equipment |
| Summary |
In the context of an aging society and the challenges posed by the COVID-19 pandemic, ensuring a healthy life expectancy has become a pressing social concern. Amidst the pandemic's impact on medical systems worldwide, the need for advancements in early diagnosis, minimally invasive treatments, and infectious disease countermeasures has been reaffirmed. The demand for practical solutions, including new drugs, medical devices, and healthcare systems, is vocalized by healthcare professionals. To address these challenges, engineering researchers play a crucial role in swiftly translating their technological innovations into medical applications. In this book, cutting-edge researchers introduce biomedical engineering from materials, devices, imaging, and information. The chapter contributors are major members of the Research Center for Biomedical Engineering, Japan. This text discusses topics on biomaterials (Chapters 1 to 3), medical devices (Chapters 4 to 11), basic medicine and dentistry (Chapters 12 to 15), and medical systems (Chapters 16 and 17). All of the topics are important areas in biomedical engineering |
| Notes |
Akihiro Miyauchi is a professor at the Institute of Biomaterials and Bioengineering, Tokyo Medical and Dental University, Japan. He received his PhD from Tokyo Institute of Technology, Japan, in 1995. With a wealth of experience, he served at Hitachi Ltd from 1986 to 2017 and held the position of visiting scientist at the Massachusetts Institute of Technology from 1995 to 1996. Prof. Miyauchi's research focuses on semiconductor process, nanoimprint, and biomimetics. Hiroyuki Kagechika is a professor and director at the Institute of Biomaterials and Bioengineering, Tokyo Medical and Dental University. He received his PhD in pharmaceutical sciences from the University of Tokyo, Japan, in 1989. Prof. Kagechika's major research interest is in the development of functional organic molecules in the fields of medicinal chemistry, chemical biology, and materials sciences. He has developed various novel bioactive compounds, including a drug for acute promyelocytic leukemia |
| Subject |
Biomedical engineering.
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biomedical engineering.
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SCIENCE / Chemistry / Inorganic
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MEDICAL / Infectious Diseases
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| Genre/Form |
Electronic books
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| Form |
Electronic book
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| Author |
Kagechika, Hiroyuki
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| ISBN |
9781040006436 |
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1040006434 |
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9781003464044 |
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1003464041 |
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9781040006429 |
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1040006426 |
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