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電子皮膚パッチ:2018 - 2028年

Electronic Skin Patches 2018-2028

発行 IDTechEx Ltd. 商品コード 658696
出版日 ページ情報 英文 310 Slides
納期: 即日から翌営業日
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電子皮膚パッチ:2018 - 2028年 Electronic Skin Patches 2018-2028
出版日: 2018年07月02日 ページ情報: 英文 310 Slides
担当者のコメント
薄型で伸縮性を持つフレキシブルデバイスである電子皮膚パッチは、ウェアラブルデバイスよりも、さらに身近に情報データを収集できるようになります。また装着していることを意識ぜずに、健康予防や在宅ケアなど幅広い利用価値や可能性を生み出すと言われております。
概要

電子皮膚パッチ市場における年間総収益は、2023年までに100億米ドルを上回ると予測され、2028年までに150億米ドルへ近づくと見られています。

当レポートでは、電子皮膚パッチの市場・技術・企業について包括的調査し、26件のアプリケーション領域、85社の企業、95件の製品ケーススタディ、市場データ実績、および市場予測を提供しています。

第1章 エグゼクティブサマリー

第2章 イントロダクション

第3章 電子皮膚パッチのアプリケーション

  • アプリケーション概要
  • 心血管モニタリング皮膚パッチ
  • 皮膚パッチによるワイヤレス患者モニタリング
  • 皮膚パッチによる糖尿病管理
  • イオン導入皮膚パッチ:化粧品・ドラッグデリバリー
  • 体温センシング皮膚パッチ
  • 発汗センシング:発汗速度・バイオマーカー
  • 皮膚パッチによるモーションセンシング
  • 皮膚パッチによる創傷モニタリング・治療
  • 皮膚パッチのその他のアプリケーション

第4章 スキンパッチ技術の開発

  • イントロダクション:皮膚パッチ技術の開発
  • フレキシブルエレクトロニクス
  • フレキシブル基板
  • プラスチック基板
  • プラスチック基板の主なパラメーター
  • フレキシブルガラス
  • 伸縮可能な、または超フレキシブルな回路基板
  • ウェアラブル・ディスプレイアプリケーションにおける薄型・フレキシブルPCBの実例
  • 多様なアプリケーションにおける薄型・フレキシブルPCBの実例
  • 伸縮性曲折インターコネクト
  • 伸縮性プリント基板
  • 伸縮性PCBにおける完全回路の実例
  • 導電性インク
  • 皮膚パッチ向け低刺激性導電性インク
  • 導電性インクプリント回路の実例
  • 伸縮可能な実際にプリントされた電子回路/システム
  • 伸縮性インク:一般観察
  • 伸縮性導電性インクの性能
  • 伸縮性導電性インクの性能における進化と改善
  • 伸縮性インク:サプライヤーの増加
  • ヘルスモニタリング向け電子皮膚マイクロシステム

第5章 電子皮膚パッチ市場の予測

  • 予測詳細・前提条件
  • 市場予測:電子皮膚パッチ
  • 市場予測:心臓・糖尿病管理デバイスを除く電子皮膚パッチ
  • 市場予測:糖尿病管理用電子皮膚パッチ
  • 市場予測:心臓デバイス
  • 市場予測:体温センシング皮膚パッチアプリケーション
  • 市場予測:モーションセンシング皮膚パッチアプリケーション
  • 市場予測:その他の電子皮膚パッチアプリケーション

第6章 企業プロファイル

目次

Title:
Electronic Skin Patches 2018-2028
The most comprehensive assessment on the commercialization of flexible, wearable, smart skin patches.

The market for electronic skin patches will reach $10bn per year by 2023.

This report characterizes the markets, technologies and players in electronic skin patches. With coverage across 26 application areas, >85 companies, 95 different product case studies, historic market data and market forecasts to 2028, it is the most comprehensive study compiled for this emerging product area. It reveals significant opportunity, with a forecast for total annual revenues in electronic skin patches to reach over $10bn per year by 2023, and approaching $15bn per year by 2028.

Interest in electronic skin patches has soared, predominantly as a by-product of the meteoric hype around wearable devices peaking in 2014. However, the interest in the area has its own grounding, with several skin patch product areas experiencing significant growth and becoming markets in the billions of dollars each year. However, success is not ubiquitous; each market discussed within this report sits within a unique ecosystem, with different players, drivers, limitations and history to build on.

As such, the report looks at each of the application areas for electronic skin patches in turn, discussing the relevant technology, product types, competitive landscape, industry players, pricing, historic revenue and market forecasts. The areas covered include diabetes management, cardiac devices, medical patient monitoring (both inpatient and outpatient), motion sensing, temperature sensing, drug and cosmetic delivery patches, smart bandages for wound care and more. For the established markets within the sector, the report contains historic revenue data by company back to 2010. The report also contains detailed market forecasting over 10 years for each of the key application areas.

The product category of "electronic skin patches" conceals a significant amount of diversity. Whilst many people may imagine skin patches to be thin, highly conformable devices that sit close to the skin, the reality is that many of the most successful products today are still relatively bulky devices. As such, the report also contains a discussion of technology areas relevant to the future development of smart patches, particularly around areas such as flexible, stretchable and conformal electronic components. Development of these technologies will not only enable more products to be deployed as skin patches, but will also for improvement in the form factor of electronic skin patches that already exist.

The research behind the report has been compiled over several years by IDTechEx analysts. It follows existing coverage of areas such as wearable technology, flexible electronics, stretchable and conformal electronics, electronic textiles, advanced wound care, bioelectronics and more. The methodology involved a mixture of primary and secondary research, with a key focus on speaking to executives and scientists from companies developing commercial electronic skin patches. As such, the report compiles case studies around 95 different products from over 80 companies, each updated over time and compared within their appropriate product ecosystems.

Unique position and experience behind the report

IDTechEx is afforded a particularly unique position in covering this topic. The experienced analyst team builds on decades of experience covering emerging technology markets, and particularly areas such as flexible electronics which are central to electronic skin patches. IDTechEx also organizes leading industry conferences and exhibitions covering flexible and wearable electronics. With a combined total of over 6000 delegates each year and presentations from all of the leading players in these spaces, IDTechEx has the unique ability to curate a network in these topic areas, facilitating the reporting in this report.

Analyst access from IDTechEx

All report purchases include up to 30 minutes telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.

Table of Contents

1. EXECUTIVE SUMMARY

  • 1.1. Executive introduction: Electronic skin patches
  • 1.2. Application overview
  • 1.3. Skin patches competing with established products
  • 1.4. New market creation around skin patches
  • 1.5. Applications, market sizes and outlook
  • 1.6. Wearable, ambulatory cardiac monitoring: Comparison of over 30 players
  • 1.7. Key conclusions: cardiac monitoring skin patches
  • 1.8. Diabetes management: Positioning of 25 players
  • 1.9. Historic data: 2010 - 2017 A shifting focus in diabetes management
  • 1.10. CGM builds on a steady start
  • 1.11. Diabetes management: full forecast
  • 1.12. Key conclusions: Iontophoresis
  • 1.13. Skin patch temperature sensing: Use cases across 12 case studies
  • 1.14. Key conclusions: Temperature sensing skin patches
  • 1.15. Key conclusions: Sweat sensing
  • 1.16. Key conclusions: Motion sensing
  • 1.17. List of players from case studies

2. INTRODUCTION

  • 2.1. The case for skin patches: Augmenting the human body
  • 2.2. The case for skin patches: Improving device form factor
  • 2.3. Definitions and exclusions
  • 2.4. History of skin patches
  • 2.5. Applications, market sizes and outlook
  • 2.6. Commercialising skin patches: Survey of 95 different examples
  • 2.7. List of players from case studies
  • 2.8. Commercial progress vs form factor
  • 2.9. Commercial progress by application focus
  • 2.10. Patents: Total active patents by assignee
  • 2.11. Patents: Active and strong patents by assignee
  • 2.12. Top 30 skin patch patent assignees, by country & region
  • 2.13. Patents: Assignees with activity in the last 2 years
  • 2.14. Skin patch commercialisation efforts, by geography
  • 2.15. Context: Wearables hype
  • 2.16. Glossary

3. ELECTRONIC SKIN PATCH APPLICATIONS

  • 3.1. Application overview
    • 3.1.1. Skin patches competing with established products
    • 3.1.2. New market creation around skin patches
    • 3.1.3. Section contents
  • 3.2. Cardiovascular monitoring skin patches
    • 3.2.1. Introduction - Cardiovascular monitoring via wearable devices
    • 3.2.2. Introduction - Measuring biopotential
    • 3.2.3. Introduction - Electrocardiography (ECG, or EKG)
    • 3.2.4. Technology overview - the circuitry for measuring biopotential
    • 3.2.5. Technology overview - electrode properties
    • 3.2.6. Progress towards ambulatory cardiac monitoring
    • 3.2.7. Differentiation between ambulatory cardiac monitors
    • 3.2.8. Wearable vs implantable monitoring
    • 3.2.9. Conclusion: Wearable vs implantable monitoring
    • 3.2.10. Wearable, ambulatory cardiac monitoring: Comparison of over 30 players
    • 3.2.11. Case studies: key players
    • 3.2.12. BioTelemetry, Inc.
    • 3.2.13. BioTelemetry: Timeline
    • 3.2.14. iRhythm: ZIO
    • 3.2.15. Medtronic: SEEQ MCT
    • 3.2.16. VivaLNK
    • 3.2.17. Cardiomo
    • 3.2.18. Holst Center: Skin patches
    • 3.2.19. LumiraDx: Ampstrip
    • 3.2.20. Other form factors for ambulatory cardiac monitoring
    • 3.2.21. Comparison: Chest straps
    • 3.2.22. Comparison: Apparel
    • 3.2.23. Comparison: Apparel (examples)
    • 3.2.24. Comparison: Portable devices
    • 3.2.25. Comparison: Smartwatch optical HRM
    • 3.2.26. Alternatives to electrodes in cardiac monitoring
    • 3.2.27. Background: PPG and it's use in wearables
    • 3.2.28. Transmission-mode PPG
    • 3.2.29. Reflectance-mode PPG
    • 3.2.30. Optical HRM companies
    • 3.2.31. Market overview and forecasts
    • 3.2.32. Market data and forecast: 2015-2023
    • 3.2.33. Ambulatory, wearable cardiac monitoring, 2018-2028
    • 3.2.34. Key conclusions: cardiac monitoring skin patches
  • 3.3. Wireless inpatient monitoring via skin patches
    • 3.3.1. Inpatient monitoring: The case for removing the wires
    • 3.3.2. Players and approaches
    • 3.3.3. Sensium (Surgical Company Group)
    • 3.3.4. VitalConect
    • 3.3.5. Isansys Lifecare
    • 3.3.6. Leaf Healthcare
    • 3.3.7. Conclusions & related areas
  • 3.4. Diabetes management via skin patches
    • 3.4.1. Background: Diabetes in numbers
    • 3.4.2. Background: Diabetes on the rise
    • 3.4.3. Background: The cost of diabetes
    • 3.4.4. Diabetes management process
    • 3.4.5. Diabetes management device roadmap: Sensors
    • 3.4.6. The case for CGM
    • 3.4.7. Non-invasive glucose monitoring?
    • 3.4.8. Opinions against non-invasive glucose monitoring
    • 3.4.9. Diabetes management device roadmap: Insulin delivery
    • 3.4.10. Closing the feedback loop: towards an artificial pancreas
    • 3.4.11. Diabetes management device roadmap: Side-effect management
    • 3.4.12. Skin patches for diabetes management
    • 3.4.13. Diabetes management: Players
    • 3.4.14. The largest players
    • 3.4.15. The largest players: Strategy comparison
    • 3.4.16. Abbott Laboratories
    • 3.4.17. Dexcom
    • 3.4.18. Medtronic
    • 3.4.19. Roche
    • 3.4.20. Other players
    • 3.4.21. Senseonics
    • 3.4.22. Sano
    • 3.4.23. PKVitality
    • 3.4.24. Verily / Google: Contact lenses
    • 3.4.25. Academic examples
    • 3.4.26. Binghampton University
    • 3.4.27. University of Bath
    • 3.4.28. Market data: Historic & forecasts
    • 3.4.29. Historic data: 2010 - 2017 A shifting focus in diabetes management
    • 3.4.30. Test strip business in decline
    • 3.4.31. CGM builds on a steady start
    • 3.4.32. Diabetes management: full forecast
    • 3.4.33. Diabetes management devices, 2010 - 2028: (Full dataset)
  • 3.5. Iontophoresis skin patches: Cosmetics and drug delivery
    • 3.5.1. Introduction - Iontophoresis
    • 3.5.2. Cosmetics
    • 3.5.3. Cosmetic skin patches
    • 3.5.4. Estée Lauder
    • 3.5.5. BioBliss™, Iontera, Patchology
    • 3.5.6. Feeligreen (Feeligold)
    • 3.5.7. Drug delivery
    • 3.5.8. Iontophoresis for drug delivery
    • 3.5.9. Drugs studied for iontophoretic delivery
    • 3.5.10. Feeligreen (Feelicare)
    • 3.5.11. Seoul National University: Parkinson's medication via skin patches
    • 3.5.12. Reverse Iontophoresis
    • 3.5.13. Example: GlucoWatch
    • 3.5.14. Nemaura Medical: sugarBEAT
    • 3.5.15. Key conclusions: Iontophoresis
  • 3.6. Temperature sensing skin patches
    • 3.6.1. Introduction - Body Temperature
    • 3.6.2. Temperature sensing technology options
    • 3.6.3. Approaches and standards for medical temperature sensing
    • 3.6.4. Skin patches for temperature sensing
    • 3.6.5. Skin patch temperature sensing: Use cases across 12 case studies
    • 3.6.6. Blue Spark
    • 3.6.7. Life Science Technology
    • 3.6.8. ... 9 other companies ...
    • 3.6.17. Alternative options: Tympanic temperature sensing
    • 3.6.18. Key conclusions: Temperature sensing skin patches
  • 3.7. Sweat sensing: Sweat rate and biomarkers
    • 3.7.1. Introduction - Sweat sensing
    • 3.7.2. Measuring sweat rate
    • 3.7.3. Technology overview - measuring bioimpedance
    • 3.7.4. Technology overview - Galvanic skin response (GSR)
    • 3.7.5. Technology overview - humidity sensors for sweat
    • 3.7.6. GE Global Research
    • 3.7.7. Sensing biomarkers in sweat
    • 3.7.8. Technology overview - chemical sensing in sweat
    • 3.7.9. Sweat vs other sources of analytes
    • 3.7.10. Analytes in sweat
    • 3.7.11. Technology overview: Chemical sensing
    • 3.7.12. Biolinq
    • 3.7.13. Kenzen
    • 3.7.14. Milo Sensors
    • 3.7.15. Eccrine Systems
    • 3.7.16. ... 3 other companies
    • 3.7.19. Key conclusions: Sweat sensing
  • 3.8. Motion sensing with skin patches
    • 3.8.1. Introduction - Monitoring motion via skin patches
    • 3.8.2. Different modes for sensing motion
    • 3.8.3. Measuring motion with inertial measurement units
    • 3.8.4. Introduction - Inertial measurement units
    • 3.8.5. Measuring motion with IMUs: Examples
    • 3.8.6. Value chain and examples of players
    • 3.8.7. IMUs in skin patches
    • 3.8.8. Suunto: Movesense
    • 3.8.9. Measuring motion with conformal sensors
    • 3.8.10. Introduction - alternatives for measuring motion
    • 3.8.11. Technology overview - Resistive/piezoresistive sensing
    • 3.8.12. Players and industry dynamic
    • 3.8.13. Peratech
    • 3.8.14. Quantum tunnelling composite: QTC®
    • 3.8.15. QTC® vs. FSR™ vs. piezoresistor?
    • 3.8.16. Bebop Sensors
    • 3.8.17. Bainisha
    • 3.8.18. Technology overview - Capacitive sensing
    • 3.8.19. Parker Hannifin
    • 3.8.20. Stretchsense
    • 3.8.21. LEAP Technology
    • 3.8.22. Bando Chemical
    • 3.8.23. Technology overview - Piezoelectric sensing
    • 3.8.24. Application examples
    • 3.8.25. Applications for skin patch motion sensors
    • 3.8.26. Case study - Concussion detection
    • 3.8.27. X2 Biosystems
    • 3.8.28. US Military head trauma patch / PARC
    • 3.8.29. Triax
    • 3.8.30. Key conclusions: Motion sensing
  • 3.9. Wound monitoring and treatment with skin patches
    • 3.9.1. Wound Monitoring
    • 3.9.2. Wound Monitoring: KAUST
    • 3.9.3. Wound Monitoring: Purdue University
    • 3.9.4. Wound Monitoring: Tufts University
    • 3.9.5. ... 6 other companies
    • 3.9.11. Wound Treatment
  • 3.10. Others applications of skin patches
    • 3.10.1. List of examples
    • 3.10.2. General technology platforms
    • 3.10.3. Qualcomm Life
    • 3.10.4. LifeSignals
    • 3.10.5. Samsung
    • 3.10.6. MC10
    • 3.10.7. Other healthcare & medical applications
    • 3.10.8. Acoustic respiration rate
    • 3.10.9. Proteus Digital Health
    • 3.10.10. Novioscan: Wearable Ultrasound
    • 3.10.11. Supporting vaccination with microneedle patches
    • 3.10.12. Avanix
    • 3.10.13. Avanix - business model and target milestones
    • 3.10.14. Other fitness & wellness applications
    • 3.10.15. UV protection
    • 3.10.16. MC10 & L'Oréal: Wisp
    • 3.10.17. Hivox Biotek
    • 3.10.18. Lief Therapeutics: Stress Management
    • 3.10.19. Others
    • 3.10.20. EOG - eye tracking with skin patches

4. SKIN PATCH TECHNOLOGY DEVELOPMENT

  • 4.1. Introduction: Skin patch technology development
  • 4.2. Flexible electronics
  • 4.3. Flexible substrates
  • 4.4. Plastic Substrates
  • 4.5. Key parameters for plastic substrates
  • 4.6. Flexible glass
  • 4.7. Stretchable or extremely flexible circuit boards
  • 4.8. Stretchable or extremely flexible circuit boards (Reebok)
  • 4.9. Examples of thin and flexible PCBs in wearable and display applications
  • 4.10. Examples of thin and flexible PCBs in various applications
  • 4.11. Stretchable meandering interconnects
  • 4.12. Stretchable printed circuits boards
  • 4.13. Examples of fully circuits on stretchable PCBs
  • 4.14. Conductive inks
  • 4.15. Hypoallergenic conductive inks for skin patches
  • 4.16. Examples of circuits printed with conductive inks
  • 4.17. Stretchable actually-printed electronic circuits/systems
  • 4.18. Stretchable inks: general observations
  • 4.19. Performance of stretchable conductive inks
  • 4.20. Evolution and improvements in performance of stretchable conductive inks
  • 4.21. Stretchable ink: suppliers increase
  • 4.22. Electronic skin microsystems for health monitoring

5. MARKET FORECASTS

  • 5.1. Forecast details and assumptions
  • 5.2. Market forecast: all electronic skin patches, 2015 - 2028
  • 5.3. Market forecast: Electronic skin patches excluding cardiac and diabetes management devices, 2015 -2028
  • 5.4. Market forecast: Electronic skin patches for diabetes management
  • 5.5. Market forecast: Cardiac devices
  • 5.6. Market forecast: Medical patient monitoring
  • 5.7. Market forecast: Temperature sensing skin patch applications
  • 5.8. Market forecast: Motion sensing skin patch applications
  • 5.9. Market forecast: Other electronic skin patch applications

6. COMPANY PROFILES

  • 6.1. List of 95 electronic skin patch case studies
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