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市場調查報告書

抗菌紡織品的技術突破

Technology Breakthroughs in Antimicrobial Textiles

出版商 Frost & Sullivan 商品編碼 921036
出版日期 內容資訊 英文 65 Pages
商品交期: 最快1-2個工作天內
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抗菌紡織品的技術突破 Technology Breakthroughs in Antimicrobial Textiles
出版日期: 2019年12月25日內容資訊: 英文 65 Pages
簡介

在智慧紡織品、個人護理、個人防護設備領域中,抗菌技術廣受矚目。

本報告研究抗菌紡織品市場的目前技術、創新、以及目前市場趨勢,彙整分析各種抗菌技術、各種抗菌平台、處於開發階段的創新技術等情報。

第1章 摘要整理

第2章 技術簡介與應用情勢

  • 使用於抗菌紡織品的技術
  • 目前正在開發天然抗菌劑作為合成抗菌劑的替代品
  • 用於抗菌紡織品的天然來源抗菌□正在研究階段中
  • 奈米銀為奈米技術基礎之抗菌平台中最先進的
  • 銀是抗菌紡織品的首選
  • Chitosan是主要使用的抗菌聚合物
  • 四級銨主要與其他抗菌技術結合使用
  • 三氯沙是最常使用的苯酚基礎技術
  • Polybiguanides還未在抗菌紡織品大規模採用
  • 結合抗菌藥的多種方法帶來各種益處
  • 抗菌紡織品有助醫療保健和醫療現場的傳染擴散
  • EPA與ECHA監控於美國及歐盟中的抗菌紡織品之殺生物劑的使用

第3章 抗菌技術產業情勢

  • Zinc Pyrithione為抗菌紡織品提供廣大範圍的防護
  • 聚合物含浸銀基的粒子提供了持久有效的抗菌解決方案
  • 銀基抗菌添加劑在抗菌紡織品產業中的採用越來越多
  • 金屬銀離子或鹽基抗菌劑是最常用的抗菌技術
  • 鋅離子基的抗菌劑提供了基於銀的抗菌劑之優秀替代品

第4章 抗菌技術:應用和影響評估

  • 抗菌技術對各應用領域的影響取決於多種因素
  • 提供材料耐久性之應用領域的高安全率
  • 主要抗菌解決方案在複數影響因素上取得一貫的成功
  • 由於安全性問題奈米技術採用率可能降低
  • 天然抗菌劑在智慧紡織品應用方面顯現出最高潛力
  • Polybiguanides將較於四級銨,在抗菌紡織品方面享有較高的技術成熟度
  • 作為結合平台使用的抗菌性聚合物之靈活度,為其高潛力貢獻

第5章 抗菌技術創新情勢

  • 新天然抗菌解決方案目前聚焦於智慧紡織品與醫療紡織品領域
  • 薄荷在抗生素抗藥性細菌方面的效果獲得證明
  • 抗菌平台也專注於提供抗病毒功能
  • 在作為安全有效的抗菌紡織品解決方案方面,針對氧化鋅的研究越來越多
  • 合作數量在提升抗菌紡織品能力進步方面提供了助力
  • 抗菌技術專利情勢

第6章 成長機會

  • 成長機會1:為提升紡織品性能結合抗菌平台
  • 成長機會2:開發更有效的抗菌□及其他天然抗菌劑解決方案
  • 成長機會3:實施可永續的製造

第7章 附錄

目錄
Product Code: D8F3

Gaining Prominence of Antimicrobial Technologies in Smart Textiles, Personal Care and Personal Protective Equipment Sectors

This research service is focused on capturing the current technology scenario, emerging innovations and the current trends in antimicrobial textiles.

Some of the key aspects covered in this research includes the different types of antimicrobial technologies, both that are currently used and emerging, for the manufacture of antimicrobial textiles. This research service also features the various antimicrobial platforms and highlights key innovations that are in use as well as under development by the market participants.It also highlights the various industry trends, detailing how these trends impact the adoption of antimicrobial textile technologies and how the adoption of the same is expected to evolve in the future.

Table of Contents

1.0. Executive Summary

  • 1.1. Research Scope
  • 1.2. Research Methodology
  • 1.3. Application Scope
  • 1.4. Key Findings
  • 1.5. Need for Antimicrobial Platforms
  • 1.6. Varying Modes of Action of Antimicrobial Technologies

2.0. Technology Snapshot and Application Landscape

  • 2.1. Technologies Used for Antimicrobial Textiles
  • 2.2. Natural Agents are Currently Being Developed as an Alternative for Synthetic Antimicrobials
    • 2.2.1. Peppermint Shows High Potential for Use in Antimicrobial Textiles
    • 2.2.2. Natural Antimicrobials May Find Increasing Adoption in Personal Care and Smart Textiles
  • 2.3. Naturally Occurring Antimicrobial Peptides are nder Research for Use in Antimicrobial Textiles
    • 2.3.1. L-Cystine Is a Promising Antimicrobial Peptide Technology for Textile Applications
  • 2.4. Nano-Silver is the Most Advanced Among Nanotechnology-based Antimicrobial Platforms
    • 2.4.1. More Research is Required to Establish the Safe Use of Nanotechnology in Antimicrobial Textiles
  • 2.5. Silver Is the Most Preferred Choice for Antimicrobial Textiles
    • 2.5.1. Zinc Is Being Increasingly Used for Smart Textile Applications
  • 2.6. Chitosan is the Majorly Used Antimicrobial Polymer
    • 2.6.1. Complex Polymers are Used as Combination Technology for Effective Antimicrobial Solutions
  • 2.7. Quaternary Ammonium is Mostly Used in Combination with Other Antimicrobial Technologies
    • 2.7.1. QACs are Effective Against Viruses in addition to Other Microbes
  • 2.8. Triclosan is the Most Commonly Used Phenol-based Technology
    • 2.8.1. Phenol and Derivatives Provide Durable Antimicrobial Effects
  • 2.9. Polybiguanides are yet to Find Large Scale Adoption in Antimicrobial Textiles
    • 2.9.1. PHMB is the Most Widely Used Biguanide in Antimicrobial Textiles
  • 2.10. Multiple Methods of Antimicrobial Incorporation Offer Varying Benefits
  • 2.11. Antimicrobial Textiles Can Help Prevent Spread of Infection in Healthcare and Medical Settings
  • 2.12. EPA and ECHA Monitor the Use of Biocidal Agents for Antimicrobial Textiles in the US and EU Respectively

3.0 Industry Landscape of Antimicrobial Technologies

  • 3.1. Zinc Pyrithione Offers Broad Spectrum Protection for Antimicrobial Textiles
  • 3.2. Polymer-impregnated Silver-based Particles Offer Durable and Effective Antimicrobial Solutions
  • 3.3. Silver-based Antimicrobial Additives are Being Increasingly Adopted in the Antimicrobial Textile Industry
  • 3.4. Metallic Silver Ions or Salt-based Antimicrobials are the Most Commonly Used Antimicrobial Technology
  • 3.5. Zinc Ion-based Antimicrobials Offer a Good Alternative to Their Silver-Based Antimicrobial Counterparts

4.0. Antimicrobial Technology- Application and Impact Assessment

  • 4.1. Impact of Antimicrobial Technologies on Various Application Sectors Depends on Multiple Factors
  • 4.2. Safety Rates High in Application Segments that Offer Material Durability
  • 4.3. Leading Antimicrobial Solutions Score Consistently on Multiple Impact Factors
  • 4.4. Nanotechnology May Experience Low Adoption Rates due to Probability of Safety Issues
  • 4.5. Natural Agents Display the Highest Potential for Smart Textile Applications
  • 4.6. Polybiguanides Enjoy Better Technology Maturity in Comparison to Quaternary Ammonium for Antimicrobial Textiles
  • 4.7. Flexibility of Antimicrobial Polymers for Use as a Combination Platform Contributes to their High Potential

5.0 Innovation Landscape of Antimicrobial Technologies

  • 5.1. Emerging Natural Antimicrobial Solutions Are Currently Focused on the Smart Textile and Medical Textile Segments
  • 5.2. Peppermint Has Proven Effective against Antibiotic-Resistant Bacteria
  • 5.3. Antimicrobial Platforms Also Focused on Offering Antiviral Capabilities
  • 5.4. Zinc Oxide is Increasingly Being Researched as a Safe and Effective Antimicrobial Textile Solution
  • 5.5. Number of Collaborations Have Provided an Impetus to Advancing the Capabilities of Antimicrobial Textiles
  • 5.6. Patent Landscape for Antimicrobial Technologies
    • 5.6.1. The US and Europe lead the Global Development of Novel Antimicrobial Technologies
    • 5.6.2. Steady Patenting Activity Witnessed

6.0 Growth Opportunities

  • 6.1. Growth Opportunity 1: Combining Antimicrobial Platforms For Better Textile Performance
  • 6.2. Growth Opportunity 2: Developing More Effective Antimicrobial Peptides & Other Natural Antimicrobial Solutions
  • 6.3. Growth Opportunity 3: Implementing Sustainable Manufacturing Practices

7.0 Appendix

  • 7.1. Key Contacts
  • 7.1. Key Contacts (Continued)
  • Legal Disclaimer
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