自我修復医生用材料及人工设计生物材料的市场及技术:2025-2045年

什么能让更多人活到120岁，并在一生中的大部分时间里保持健康？其中之一就是利用自修復材料进行重建和治疗。

报告指出，有机自修復材料，尤其是热塑性聚合物，预计将在预测期内占据市场主导地位，而水凝胶和工程生物材料预计将获得更大的市场占有率。

本报告研究了自修復医用材料和工程生物材料市场与技术，并总结了市场背景、关键技术的趋势和前景、市场推动因素和课题、2025年至2045年的17条预测线以及68家公司的公司资讯。

目录

第1章 摘要整理·总论

• 本报告的目的·调查手法·背景
• 定义和焦点
• 主要的结论
• 医疗的自我修復材料费技术的成熟曲线
• 医疗的自我修復材料费的蓝图
• 市场预测

第2章 简介

• 定义及方案
• 市场推动因素及方案
• 2025年前30个自修復材料案例研究分析

章节3 自修復技术工具包：概论

• 概述
• 技术方案概述：内在与外在机制
• 自修復方案：操作、物理、化学、配方和形态
• 常用的化学家族
• 原子级自修復材料工具包
• 预计在2025-2045年实现商业化的顶级自修復材料（按应用）
• 自修復效能指标的困境
• 自修復聚合物工具包
• 内源性自修復材料工具包
• 透过微胶囊实现外在自修復
• 透过血管系统实现外在自修復
• 类血管自修復
• 自修復弹性体：内在与外在的
• 形状记忆辅助自修復

第4章 自修復技术工具包：工程生物材料 (ELM)

• 概述
• ELM 的 SWOT 分析
• 障碍与未来展望
• 利用生物材料的自修復方法
• 生物 ELM 与混合 ELM 的比较
• 2025 年前的相关研究

第五章 自修復材料在医疗领域的应用：2025-2045

• 概述：自修復医疗材料的主题、生物材料和愿景
• SWOT 分析：自修復材料在医疗领域的应用
• 人造皮肤和肌肉：自修復材料和支持材料“自修復”
• 组织工程、细胞共培养及器官移植
• 人造肌肉、软骨、义肢和软体机器人
• 骨修復与置换
• 钛及其他植入物
• 膜
• 微胶囊和水凝胶药物输送
• 电子产品

第6章 自我修復企业简介

• 概要·价值链
• 62公司的自我修復材料费製造商的第8项比较
• 14家相关公司的简介

Summary

What will enable many human beings to live to 120 years and live healthily for most of that span? A major contributor will consist of humans being rebuilt and treated with self-healing materials. A new report details your opportunities from this. It is 347-page Zhar Research report, "Self-Healing Healthcare Material and Engineered Living Material Markets, Technology: 2025-2045" . It details how even hospital infrastructure and equipment will benefit from the new self-healing materials. Its six chapters present 10 technology SWOT appraisals, 17 forecast lines for 2025-2045. It covers 68 companies and the abundant research through 2025 is analysed to reveal winning trends and formulations. Learn which applications are likely to be large and when. See your most promising potential partners and acquisitions and your emerging competition.

Commercially oriented, balanced

The report identifies a host of opportunities for your materials specialities but is blunt about issues such as toxicity. The authors find that organic self-healing materials, particularly thermopolymers, will dominate 2025-2045 but hydrogels and Engineered Living Materials ELM will take share, so the report's balance reflects such realities.

Quick read, graphic summary

The "Executive summary and conclusions" is sufficient in itself for those with limited time. Its 51 pages include 33 key conclusions, 8 SWOT appraisals and the leading compound families that are trending, with many new infograms. See the roadmap 2025-2045 and all the 17 forecasts 2025-2045 by table and graph plus technology maturity curves for 2025, 2035, 2045. Out-of-date reports are useless for this fast-moving topic, so this one is constantly updated so you only get the latest.

Context

The Introduction (23 pages) explains definitions, choices, market drivers, the trend to self-healing smart materials, long life, reliability, fit-and-forget and rejuvenation. See how biomimetics has much further to go and how we are overcoming the soft material dilemma. Understand the challenges of putting a value on the market. 30 examples of research on self-healing materials in 2025 and earlier are analysed as a taster of what is to come.

Deep examination of your toolkit for self-healing and ELM

Chapter 3. "The self-healing technology toolkit: general" with 104 pages on the self-healing inanimate materials toolkit is brought alive with many other research advances from 2025 and earlier. Inevitably the terminology overlaps somewhat but here you can see why intrinsic self-healing and use of hydrogels, polyurethanes and Diels-Alder materials are very important. However, self-healing vitrimers, ionogels and even metals and ceramics and many others have a place, including self-healing proteins and elastomers. They are discussed in the context of various mechanisms explained. Physical or chemical approaches? The dilemmas are aired including self-healing metrics and cost-performance compromises. Understand important self-healing materials by application likely to be commercialised 2025-2045.

Chapter 4. "Self-healing technology toolkit: Engineered Living Materials ELM" (30 pages) covers self-healing versions and others not yet self-healing. ELM are engineered materials composed of living cells that form or assemble the material itself or modulate the functional performance of the material in some manner. Think enzymes, fungi and even bacteria. Overview, definition, choice of hosts and learning from nature are followed by analysis of the allied topic: assisting human healing by application of biological materials that may or may not be self-healing themselves. There is a close look at ELM features, four stages of ELM creation and deployment and a SWOT appraisal. Grasp the obstacles and the way forward for the various self-healing approaches with biological materials. Bio ELM is compared to hybrid ELM with much relevant research and commercialisation, including the current star turn - fungi - mycelial materials - with advances in 2025. See self-healing mycelial leather, formwork, ELM textiles and even concrete.

Deep study of the toolkit in action 2025-2045, latest research, 68 companies

Chapter 5. "Self-healing material applications in healthcare 2025-2045" at 100 pages is a large chapter complementing the two chapters on the technology toolkit by giving deep insights concerning the technologies in use. An important aspect is artificial human skin and muscle with self-healing materials and ones helping the patient to "self-heal".

More generally, see progress in 2025, technology trend to 2025 including sensory, electronic, biocompatibility, anti-bacterial and anti-fouling aspects comparing hydrogel, polyimine, fluoropolymer, silicone, PVA and other approaches. Understand self-healing with tissue engineering (adhesives, films etc), cell co-culture and organ replacement with objectives and progress in 2025. Scan hydrogels and PDMS in action too, soft robotics, bone repair and replacement. Here are titanium and other implants, membranes by difficulty level. Assessments with 2025 research advances include drug delivery by microcapsules and hydrogels, self-healing healthcare electronics, nanogenerators, optical and photonic materials, implantable and smart patch batteries. The report ends with 22 pages of Chapter 6. "Self-healing company profiles" comparing 62 tabled in six appraisal columns then 14 of them profiled in more detail, other being in earlier text.

The Zhar Research report, "Self-Healing Healthcare Material and Engineered Living Material Markets, Technology: 2025-2045" is your essential reading on this large emerging market for both devices and materials. Here are your exciting opportunities rising to $19 billion in 2045.

CAPTION: Primary mentions in latest advances of self-healing healthcare materials by compound basis (not mutually exclusive). Source: Zhar Research report, "Self-Healing Healthcare Material and Engineered Living Material Markets, Technology: 2025-2045" .

Table of Contents

1. Executive summary and conclusions

• 1.1. Purpose, methodology and background of this report
• 1.2. Definitions and focus
• 1.3. Primary conclusions
  • 1.3.1. Addressable markets: 9 general conclusions, 3 infograms and 2 SWOT appraisals
  • 1.3.2. Emerging technologies and capabilities: 24 key conclusions, 6 infograms, compound prioritisation chart, 6 SWOT appraisals
  • 1.3.3. Self-healing Engineered Living Materials ELM with infograms and SWOT
  • 1.3.4. Market fundamentals in infograms, pie charts and commentary
• 1.4. Maturity curves of self-healing material technologies in healthcare 2025, 2035,2045
• 1.5. Roadmap for self-healing materials in healthcare 2025-2045
• 1.6. Market forecasts 2025-2045 in 17 lines
  • 1.6.1. Self-healing materials for all applications: value market 2025-2045
  • 1.6.2. Self-healing materials for healthcare value market $ billion 2025-2045
  • 1.6.3. Percentage share of self-healing healthcare value market by four regions 2025-2045
  • 1.6.4. Percentage share of hydrogel value market by four regions 2025-2045
  • 1.6.5. Global hydrogel value market by four business sectors 2025-2045

2. Introduction

• 2.1. Definition and choices
• 2.2. Market drivers and options
  • 2.2.1. Trend to self-healing smart materials
  • 2.2.2. Trend to long life, reliability, fit-and-forget, rejuvenation
  • 2.2.3. Biomimetics - much further to go
  • 2.2.4. Overcoming the soft material dilemma
  • 2.2.5. Beyond biomimetics
  • 2.2.6. Challenges of putting a value on the market
  • 2.2.7. Stretching the logic to include minimal post treatment
• 2.3. 30 analysed examples of research on self-healing materials in 2025 and earlier

3. The self-healing technology toolkit: general

• 3.1. Overview
• 3.2. Technology options top down - intrinsic and extrinsic mechanisms
• 3.3. Self-healing options: operational, physical, chemical, formulation, format
• 3.4. Chemical families typically involved
• 3.5. Atomic toolkit for self-healing materials
• 3.6. Some of the important self-healing materials by application likely to be commercialised 2025-2045
• 3.7. The dilemma of metrics for self-healing efficacy
  • 3.7.1. Quantifying healing time, maximum number of healing cycles enabled, degree of recovery
  • 3.7.2. Efficiency and mobility over time
• 3.8. Self-healing polymer toolkit
  • 3.8.1. Types of polymer damage to be healed
  • 3.8.2. Healing options for polymers
  • 3.8.3. Difficulty levels for self-healing commercialisation in polymer sectors
• 3.9. Toolkit for intrinsic self-healing materials
  • 3.9.1. Overview, importance of nanomaterials
  • 3.9.2. Hydrogels with SWOT appraisal, options for repairing structural damage, recovering original functions, mimicking natural healing, improvement 2025-2045
  • 3.9.3. Wound healing, tissue engineering, and nerve regeneration with biocompatible self-healing cellulose-based hydrogels: research advances in 2025
  • 3.9.4. Sustained hydrogel delivery of decorin to prevent corneal scarring
  • 3.9.5. Wound-healing and injectable self-healing hydrogels: tissue engineering and regenerative medicine in 2025
  • 3.9.6. Ionogel self healing including 2025 research advances
  • 3.9.7. Silica gel
  • 3.9.8. Supramolecular gels and elastomers for implantable and smart patch energy storage in 2025
  • 3.9.9. Diels Alder self-healing adhesives, coatings including SWOT and latest research appraisal
  • 3.9.10. Self-healing ionomers for healthcare packaging and biomedical sensors
  • 3.9.11. Vitrimers
  • 3.9.12. Self-healing proteins such as polypeptides
  • 3.9.13. Self-healing metals
  • 3.9.14. Self-healing under water
• 3.10. Extrinsic self-healing by microcapsules
  • 3.10.1. SWOT appraisal
  • 3.10.2. Design issues and examples
  • 3.10.3. Self-healing microcapsule manufacturing options
• 3.11. Extrinsic self-healing by vascular systems
  • 3.11.1. Vascular self-healing SWOT appraisal
  • 3.11.2. Geometrical design and challenges
• 3.12. Vascular-like self-healing
• 3.13. Self-healing elastomers intrinsic and extrinsic
• 3.14. Shape memory assisted self-healing SMASH
  • 3.14.1. Shape memory alloys and polymers and SMASH potential markets
  • 3.14.2. Stress-Induced shape-shifting materials possessing autonomous self-healing and scratch-resistant ability
  • 3.14.3. Hydrogel versions
  • 3.14.4. Polyolefin and polyurethane versions
  • 3.14.5. Close-then-heal and fiber dispersion options

4. Self-healing technology toolkit: Engineered Living Materials ELM

• 4.1. Overview
  • 4.1.1. Definition and choice of hosts
  • 4.1.2. Learning from nature
  • 4.1.3. Allied topic: assisting human healing by application of biological materials that may or may not be self-healing themselves
  • 4.1.4. Features of engineered living materials
  • 4.1.5. Four stages of ELM creation and deployment
• 4.2. Self-healing Engineered Living Material SWOT appraisal
• 4.3. Obstacles and the way forward
• 4.4. Self-healing approaches with biological materials
• 4.5. Bio ELM vs hybrid ELM
• 4.6. Relevant ELM research in 2025 and earlier
  • 4.6.1. Fungi - mycelial materials - advances in 2025
  • 4.6.2. Self-healing mycelial leather, formwork and other applications
  • 4.6.3. General research advances with ELM in 2025 and earlier

5. Self-healing material applications in healthcare 2025-2045

• 5.1. Overview: topics, biomaterials and vision of self-healing healthcare materials
• 5.2. SWOT appraisal of self-healing material applications in healthcare
• 5.3. Artificial human skin and muscle: self-healing materials and material that helps you to "self-heal"
  • 5.3.1. Overview: progress in 2025, technology trend to 2025 including sensory, electronic, biocompatibility, anti-bacterial, anti-fouling aspects
  • 5.3.2. Hydrogel approach
  • 5.3.3. Polyimine approach
  • 5.3.4. Fluoropolymer sensory robots
  • 5.3.5. Silicone approach: e-skin, siloxanes
  • 5.3.6. PVA, organometallic polymer and other approaches
• 5.4. Tissue engineering, cell co-culture, organ replacement
  • 5.4.1. Objectives and progress in 2025
  • 5.4.2. Tissue engineering adhesives
  • 5.4.3. Tissue engineering films
  • 5.4.4. Hydrogel approaches
• 5.5. Artificial muscle, cartilage, prosthetics and soft robotics
  • 5.5.1. Overview
  • 5.5.2. PDMS approach
  • 5.5.3. Hydrogel approaches including as engineered living materials and SWOT appraisal
  • 5.5.4. Self-healing soft robotics: US Army and others
• 5.6. Bone repair and replacement
• 5.7. Titanium and other implants
• 5.8. Membranes
  • 5.8.1. Definitions
  • 5.8.2. Fabricated membranes
  • 5.8.3. Difficulty levels for self-healing membrane
• 5.9. Drug delivery by microcapsules and hydrogels
• 5.10. Electronics
  • 5.10.1. Overview and health monitoring
  • 5.10.2. Conductors
  • 5.10.3. Transistors
  • 5.10.4. Sensors
  • 5.10.5. Optical and photonic materials
  • 5.10.6. Self-healing implantable and smart patch batteries and battery parts including 2025 research advances
  • 5.10.7. Triboelectric nanogenerators

6. Self-healing company profiles

• 6.1. Overview and value chain
• 6.2. Comparison of 62 self-healing material manufacturers in eight columns
• 6.3. Profiles of 14 companies involved