Integrated Smart Micro-Systems Towards Personalized Healthcare

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Integrated Smart Micro-Systems Towards Personalized Healthcare

Presents a thorough summary of recent advances in microelectronic systems and their applications for personalized healthcare

Integrated Smart Micro-Systems Towards Personalized Healthcare provides up-to-date coverage of developments in smart microelectronics and their applications in health-related areas such as sports safety, remote diagnosis, and closed-loop health management. Using a comprehensive approach to the rapidly growing field, this one-stop resource examines different methods, designs, materials, and applications of systems such as multi-modal sensing biomedical platforms and non-invasive health monitoring sensors.

The book’s five parts detail the core units of micro-systems, self-charging power units, self-driven monitor patches, self-powered sensing platforms, and integrated health monitoring systems. Succinct chapters address topics including multi-functional material optimization, multi-dimensional electrode preparation, multi-scene application display, and the use of multi-modal signal sensing to monitor physical and chemical indicators during exercise. Throughout the text, the authors offer key insights on device performance improvement, reliable fabrication processing, and compatible integration designs.

  • Provides an overview self-powered, wearable micro-systems with emphasis on personalized healthcare
  • Covers the working mechanisms and structural design of different energy-harvesting units, energy storage units, and functional units
  • Introduces an integrated self-charging power unit consisting of triboelectric nanogenerators with supercapacitor
  • Describes a general solution-evaporation method for developing porous CNT-PDMS conductive elastomers
  • Examines a fully-integrated self-powered sweat sensing platform built on a wearable freestanding-mode triboelectric nanogenerator

Integrated Smart Micro-Systems Towards Personalized Healthcare is an essential text for researchers, electronic engineers, entrepreneurs, and industry professionals working in material science, electronics, mechanical engineering, bioengineering, and sensor development.

Author(s): Yu Song, Wei Gao, Haixia Zhang
Publisher: Wiley-VCH
Year: 2021

Language: English
Pages: 216
City: Weinheim

Cover
Title Page
Copyright
Contents
Preface
Chapter 1 Introduction
1.1 Overview of Integrated Smart Micro‐systems
1.1.1 The Progress of Portable Smart Micro‐systems
1.1.2 Integrated Smart Micro‐systems Toward Healthcare Monitoring
1.2 Three Core Units of Smart Micro‐systems
1.2.1 Triboelectric Nanogenerator (Energy‐Harvesting Unit)
1.2.2 Solid‐State Supercapacitors (Energy‐Storage Unit)
1.2.3 Strain Sensors (Functional Sensing Unit)
1.3 The Progress of the Integration of Smart Micro‐systems
1.3.1 Self‐Charging Power Unit
1.3.2 Self‐Driven Monitor Patch
1.3.3 Self‐Powered Sensing Platform
1.4 The Progress of Applications of Integrated Smart Micro‐systems
1.4.1 Real‐Time Health Monitoring
1.4.2 Multifunctional Human–Machine Interaction
1.4.3 Assisted Precision Therapy
1.5 Scope and Layout of the Book
1.5.1 Scope of the Book
1.5.2 Layout of the Book
Abbreviations
References
Chapter 2 Core Units of Smart Micro‐systems
2.1 Triboelectric Nanogenerators for Energy Harvesting
2.1.1 Single‐electrode Triboelectric Nanogenerator
2.1.2 Freestanding Triboelectric Nanogenerator
2.2 Supercapacitors for Energy Storage
2.2.1 Wearable Supercapacitor
2.2.2 Planar Micro‐supercapacitor
2.3 Piezoresistive Sensors for Function Sensing
2.3.1 Conductive Sponge‐Based Piezoresistive Sensor
2.3.2 Porous Conductive Elastomer‐Based Piezoresistive Sensor
2.4 Summary
Abbreviations
References
Chapter 3 Sandwiched Self‐charging Power Unit
3.1 Self‐charging Power Unit
3.1.1 Working Principle
3.1.2 Theoretical Analysis
3.2 Enhancement of TENG Based on Surface Optimization
3.2.1 Formation Mechanism of Wrinkle Structure
3.2.2 Fabrication Process and Morphology Characterization
3.3 Flexible Paper Electrode–Based Supercapacitor
3.3.1 Percolation Theory
3.3.2 Flexible CNT–Paper Electrode
3.3.3 Fabrication Process and Morphology Characterization
3.4 Performance Characterization of SCPU
3.4.1 Evaluation of TENG
3.4.2 Evaluation of SC
3.4.3 Self‐charging Performance
3.5 Applications of SCPU
3.5.1 Power Supply for Low‐power Electronics
3.5.2 Smart Display of Electrochromic Device
3.6 Summary
Abbreviations
References
Chapter 4 All‐in‐one Self‐driven Monitor Patch
4.1 Self‐driven Monitor Patch
4.1.1 Working Principle
4.1.2 Theoretical Analysis
4.2 Fabrication Process of Self‐driven Monitor Patch
4.2.1 “Solution‐Evaporation” Method
4.2.2 Modulation of Parameters and Morphologies
4.2.3 Integrated Fabrication
4.3 Performance Characterization of Self‐driven Monitor Patch
4.3.1 Evaluation of PRS
4.3.2 Evaluation of MSC
4.4 Applications of Self‐driven Monitor Patch
4.4.1 Real‐time Health Monitoring
4.4.2 Personalized Human–Machine Interaction
4.4.3 Static Pressure Distribution and Dynamic Tactile Trajectory
4.5 Summary
Abbreviations
References
Chapter 5 Fully Integrated Self‐powered Sweat‐Sensing Platform
5.1 Structural Design of Self‐powered Sweat‐Sensing Platform
5.2 Freestanding Triboelectric Nanogenerator
5.2.1 Working Principle and Structural Design
5.2.2 Performance Characterization
5.3 Potentiometric Electrochemical Sensing Unit
5.3.1 Working Principle
5.3.2 Microfluidic Structural Design
5.3.3 Fabrication Process
5.3.4 Performance Characterization
5.3.4.1 Sensitivity
5.3.4.2 Selectivity
5.3.4.3 Cycling Repeatability
5.4 System‐level Integrated Circuit Module
5.4.1 Schematic Diagram and Operation Flow Analysis
5.4.2 Performance Characterization
5.5 Applications of Fully Integrated Self‐powered Sweat‐Sensing Platform
5.5.1 Validation of Flexible Sensing Unit
5.5.2 On‐body Evaluation for Dynamic Sweat Analysis
5.6 Summary
Abbreviations
References
Chapter 6 Multimodal Sensing Integrated Health‐Monitoring System
6.1 Multimodal Sensing Platform
6.1.1 Structural Design
6.1.2 Fabrication and Morphology of All‐Laser‐Engraved Process
6.2 LEG‐based Chemical Sensor for UA and Tyr Detection
6.2.1 Performance Characterization
6.2.2 Reliability and Selectivity
6.3 LEG‐based Physical Sensor for Vital Signs Monitoring
6.3.1 Evaluation of LEG‐based Temperature Sensor
6.3.2 Microfluidic Structural Design
6.4 System‐Level Circuity Module
6.4.1 Design and Block Diagram
6.4.2 Signal Processing and Validation
6.5 On‐body Evaluation of Integrated Health‐Monitoring System
6.5.1 Sweat Analysis at Different Body Parts
6.5.2 Multimodal Real‐Time Continuous In Situ Measurement
6.6 Health‐Monitoring System for Non‐invasive Gout Management
6.6.1 Purine‐Rich Diets and Gout
6.6.2 Personalized Non‐Invasive Gout Management
6.7 Summary
Abbreviations
References
Chapter 7 Progress and Perspectives
7.1 The Progress of the Micro‐systems
7.2 Perspectives of the Micro‐systems
Abbreviations
References
Index
EULA