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表紙:バイオベースマイクロビーズの世界市場(2026年~2036年)
市場調査レポート
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1740242

バイオベースマイクロビーズの世界市場(2026年~2036年)

The Global Market for Biobased Microbeads 2026-2036

出版日
ページ情報
英文 132 Pages, 76 Tables, 26 Figures
納期
即納可能 即納可能とは
価格
価格表記: GBPを日本円(税抜)に換算
本日の銀行送金レート: 1GBP=199.28円
バイオベースマイクロビーズの世界市場(2026年~2036年)
出版日: 2025年06月03日
発行: Future Markets, Inc.
ページ情報: 英文 132 Pages, 76 Tables, 26 Figures
納期: 即納可能 即納可能とは
GIIご利用のメリット
  • 全表示
  • 概要
  • 図表
  • 目次
概要

バイオベースマイクロビーズ市場は、環境規制の高まりと、従来のプラスチックマイクロビーズに代わる環境にやさしいものを求める消費者の需要によって、広大な持続可能材料産業の中で急速に発展しているセグメントです。これらの微細な球状粒子は、一般的に直径1~1,000マイクロメートルで、植物セルロース、藻類、農業廃棄物、生分解性ポリマーなどの再生可能な生体由来のものです。世界のバイオベースマイクロビーズ市場は、パーソナルケア製品に含まれる合成プラスチックマイクロビーズに対する規制を受け、大きな成長を示しています。米国、カナダ、英国、EU数ヶ国を含む国々は、その環境残留性と海洋生態系への潜在的危害を理由に、洗い流すタイプの化粧品に含まれるプラスチックマイクロビーズの使用禁止を実施しています。この規制情勢は、生分解性を維持しながら同様の機能特性を提供するバイオベースの代替品に大きな機会をもたらしています。

バイオベースマイクロビーズ市場には、多様な天然材料と生分解性ポリマーが含まれ、それぞれがユニークな性能特性と応用可能性を提供しています。デンプン、セルロース、キチンのような多糖類から、コラーゲンやカゼインを含むタンパク質まで、ポリヒドロキシアルカノエート(PHA)やポリ乳酸(PLA)のようなポリエステルの技術革新により、材料情勢は拡大を続けています。さらに、リグニンやアルギン酸のような新たな材料は、産業全体にわたる特殊用途に新たな機会をもたらしています。

バイオベースマイクロビーズの主な用途は複数の産業にまたがっており、パーソナルケア・化粧品が最大の市場セグメントとなっています。これらの製品は、フェイススクラブ、ボディーソープ、歯磨き粉においてやさしいスクラブ剤として機能し、消費者が期待する触感と美的特性を提供すると同時に、環境上の懸念に対応しています。パーソナルケア以外にも、バイオベースマイクロビーズはドラッグデリバリーシステムとして医薬品に、制御放出肥料キャリアーとして農業に、そして生分解性研磨剤として工業プロセスに応用されています。

競合情勢には、新たなバイオベースソリューションを開発する既存の化学企業と革新的なスタートアップが混在しています。主要企業には、木材パルプや綿からセルロースベースのマイクロビーズを生産する企業が含まれ、新技術は藻類由来の粒子や農業廃棄物の変換に焦点を当てています。製造プロセスには通常、所望の粒度分布と機能特性を達成するために、制御された沈殿、噴霧乾燥、または特殊な重合技術が含まれます。

市場促進要因は、環境規制の強化、企業の持続可能性への取り組み、マイクロプラスチック汚染に対する消費者の意識の高まりなどです。美容・パーソナルケア産業の「クリーン」処方へのシフトは、特に採用を加速させています。さらに、技術の進歩によりバイオベースマイクロビーズの性能特性が改良され、効果や保存安定性に関する初期の懸念に対処しています。

しかし、市場は複数の課題に直面しています。バイオベースの代替品の生産コストは通常、従来のプラスチックマイクロビーズのそれを上回ります。とはいえ、この差は規模や技術の向上によって縮まりつつあります。安定した品質と信頼できる原材料の調達には継続的な投資が必要であるため、サプライチェーンの開発は依然として懸念事項です。さらに、生分解率と環境動態は、引き続き活発な研究と規制精査の分野となっています。

地域の市場力学は大きく異なり、欧州が規制圧力と市場採用でともにリードしており、北米がそれに続いています。アジア太平洋市場は、特に厳しい環境基準を導入している国々で関心が高まっています。市場構造には、既存のプラスチックマイクロビーズを直接置き換えるものと、バイオベースの代替品のユニークな特性を活用した新用途を開発するものが含まれます。将来の市場見通しは、規制枠組みの拡大、企業の環境コミットメントの増加、原材料と加工技術における継続的な技術革新に支えられ、健全なものとみられます。産業アナリストは、多様な用途における規制遵守と持続可能な代替品の自主的な採用によって市場が拡大し、今後10年間は2桁成長を維持すると予測しています。

当レポートでは、世界のバイオベースマイクロビーズ市場について調査分析し、市場促進要因、技術革新、応用分野、競合力学などの情報を提供しています。

目次

第1章 マイクロプラスチック市場

  • 製品に添加されたマイクロプラスチック
    • 分類
    • 機能と用途
  • マイクロプラスチックに関する法律
    • REACH
    • 米国
    • カナダ
    • オーストラリア
    • アジア
  • 環境への影響の評価
    • 海洋汚染とマイクロプラスチックの蓄積
    • 海洋生物への毒性の影響
    • 人間の健康に対する影響

第2章 バイオベースマイクロビーズ材料

  • マイクロプラスチックの代替品としての使用
  • 生分解のメカニズムと時間枠
  • 天然硬質材料
  • 天然ポリマー
    • 多糖類
    • タンパク質
    • ポリエステル
    • その他の天然ポリマー
  • 製造技術とプロセス
    • 溶融加工、押出技法
    • 溶剤ベースの生産方式
    • エマルション、スプレードライ技術
    • 品質管理、粒度分布
  • 規制枠組みと規格
    • 生分解性試験規格(ASTM、ISO)
    • 食品接触と化粧品の安全規制
    • 国際認定プログラム

第3章 バイオベースマイクロビーズの市場

  • マイクロプラスチック(1~50マイクロメートル)の代替品:用途別、市場別
  • 天然マイクロプラスチック代替品の市場浸透の可能性:市場別
    • 市場浸透の障壁と課題
    • 採用タイムラインと市場準備度の評価
  • パーソナルケア
    • 市場の概要
    • 用途
    • ブランド採用のケーススタディ
    • 消費者の受容性と支払い意欲
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 化粧品
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 農業・園芸
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 塗料・コーティング
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 石鹸・洗剤・メンテナンス用品
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 石油・ガス
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 医療用品
    • 市場の概要
    • 用途
    • マイクロプラスチックの総量:規模別(2024年~2036年)
  • 新用途
    • 3Dプリンティング・積層造形
    • テキスタイル・繊維
    • 食品包装・生分解性フィルム
  • 市場金額の分析
  • 価格弾力性とコスト競争力の分析

第4章 世界の市場規模

  • 一次微粒子(メートルトン単位の数量)
    • 市場別
    • 地域別
  • バイオベースマイクロビーズ(MT)
    • 原材料別
    • 市場別
    • 地域別

第5章 SWOT分析と市場の課題

  • バイオベースマイクロビーズの強み
  • 弱みと技術的限界
  • 市場機会と成長促進要因
  • 脅威と市場のリスク
  • 市場浸透への重要な成功要因

第6章 メーカーのプロファイル(企業40社のプロファイル)

第7章 レポートの調査手法

第8章 参考文献

図表

List of Tables

  • Table 1. Summary of functions and applications for microplastics
  • Table 2. Global Microplastics Legislation
  • Table 3. Microplastics environmental impact assessment
  • Table 4. Biodegradable polymers
  • Table 5. Biodegradation mechanisms and timeframes
  • Table 6. Performance comparison vs. conventional microplastics
  • Table 7.Companies developing starch microspheres/microbeads
  • Table 8. Companies developing microcrystalline cellulose (MCC) spheres/beads
  • Table 9. Companies developing cellulose microbeads
  • Table 10. CNC properties
  • Table 11. Applications of cellulose nanocrystals (NCC)
  • Table 12. Companies developing cellulose nanocrystal microbeads
  • Table 13. Cellulose nanocrystal production capacities and production process, by producer
  • Table 14. Applications of bacterial nanocellulose (BNC)
  • Table 15. Companies developing bacterial nanocellulose microbeads
  • Table 16.Companies developing chitin microspheres/microbeads
  • Table 17.Types of PHAs and properties
  • Table 18. Polyhydroxyalkanoates (PHA) producers
  • Table 19. Companies developing PHA for microbeads
  • Table 20. PLA producers and production capacities
  • Table 21. Technical lignin types and applications
  • Table 22. Properties of lignins and their applications
  • Table 23. Production capacities of technical lignin producers
  • Table 24. Production capacities of biorefinery lignin producers
  • Table 25. Companies developing lignin for microbeads (current or potential applications)
  • Table 26. Companies developing alginate for microbeads (current or potential applications)
  • Table 27. Manufacturing Technologies and Processes for Biobased Microbeads
  • Table 28. Biodegradability Testing Standards (ASTM, ISO)
  • Table 29. Food Contact and Cosmetic Safety Regulations
  • Table 30. International Certification Programs
  • Table 31. Alternatives to microplastics (1-50 micrometer) by application and market
  • Table 32. Likelihood of market penetration of natural microplastic alternatives, by main markets
  • Table 33. Market penetration barriers and challenges
  • Table 34. Personal care products containing primary microplastics
  • Table 35. Alternative Microplastic Materials in Personal Care
  • Table 36. Total quantity of microplastics present in personal care products 2024-2036 (MT), by scale
  • Table 37. Types of Microplastics in Cosmetics
  • Table 38. Alternative Microplastic Materials in Cosmetics
  • Table 39. Total quantity of microplastics present in cosmetics 2024-2036 (MT), by scale
  • Table 40. Types of Microplastics in Agriculture and Horticulture
  • Table 41. Agriculture and horticulture products containing microplastics
  • Table 42. Alternative Microplastic Materials in Agriculture and Horticulture
  • Table 43. Total quantity of microplastics present in agriculture and horticulture 2024-2036 (MT), by scale
  • Table 44. Types of Microplastics in Paints and Coatings
  • Table 45. Alternative Microplastic Materials in Paints and Coatings
  • Table 46. Total quantity of microplastics present in paints and coatings 2024-2036 (MT), by scale
  • Table 47. Soaps, detergents and maintenance products containing microplastics
  • Table 48. Alternative Microplastic Materials in Soap, Detergents, and Maintenance Products
  • Table 49. Total quantity of microplastics present in Soaps, detergents and maintenance products 2024-2036 (MT), by scale
  • Table 50. Types of Microplastics in Oil and Gas
  • Table 51. Alternative Microplastic Materials in Oil and Gas
  • Table 52. Total quantity of microplastics present in oil and gas 2024-2036 (MT), by scale
  • Table 53. Example microsphere products in drug delivery
  • Table 54. Medical products containing microplastics
  • Table 55. Alternative Microplastic Materials in Medical Products
  • Table 56. Total quantity of microplastics present in medicinal products 2024-2036 (MT), by scale
  • Table 57. Biobased Microbeads in Emerging Applications
  • Table 58. Biobased microbeads in 3D printing and additive manufacturing
  • Table 59. Biobased microbeads in Textile and fibre applications
  • Table 60. Biobased microbeads in Food packaging and biodegradable films
  • Table 61. Market Value Analysis - Biobased Microbeads Global Market ($USD Million)
  • Table 62. Price elasticity and cost-competitiveness analysis
  • Table 63. Global market for primary microparticles 2017-2024, by Market, (Metric Tons)
  • Table 64. Global Market for Primary Microparticles 2025-2036, by Market (Metric Tons)
  • Table 65. Global Market Size by Region 2017-2024, Primary Microparticles (Metric Tons)
  • Table 66. Global market for primary microparticles 2025-2036, by region, (Metric Tons)
  • Table 67. Market Segmentation by Raw Materials (2025 Projections)
  • Table 68. Global market 2017-2036, for biobased microbeads, (MT)
  • Table 69. Global Market 2017-2036, for Biobased Microbeads, by Market (MT)
  • Table 70. Global market 2017-2036, for biobased microbeads, by region (MT)
  • Table 71. Strengths of biobased microbeads
  • Table 72. Weaknesses and technical limitations
  • Table 73. Biobased microbeads Market opportunities and growth drivers
  • Table 74. Biobased microbeads Threats and market risks
  • Table 75. Biobased microbeads Critical success factors for market penetration
  • Table 76. Lactips plastic pellets

List of Figures

  • Figure 1. Typical sources of primary microplastics
  • Figure 2. Bacterial nanocellulose shapes
  • Figure 3. Adoption timeline and market readiness assessment
  • Figure 4. Total quantity of microplastics present in personal care products 2024-2036 (MT), by scale
  • Figure 5. Toothpaste incorporating microbeads
  • Figure 6. Total quantity of microplastics present in cosmetics 2024-2036 (MT), by scale
  • Figure 7. Total quantity of microplastics present in agriculture and horticulture 2024-2036 (MT), by scale
  • Figure 8. Total quantity of microplastics present in paints and coatings 2024-2036 (MT), by scale
  • Figure 9. Total quantity of microplastics present in Soaps, detergents and maintenance products 2024-2036 (MT), by scale
  • Figure 10. Total quantity of microplastics present in oil and gas 2024-2036 (MT), by scale
  • Figure 11. Total quantity of microplastics present in medicinal products 2024-2036 (MT), by scale
  • Figure 12. Global market for primary microparticles 2017-2024, by Market, (Metric Tons)
  • Figure 13. Global market for primary microparticles 2024-2036, by Market, (Metric Tons)
  • Figure 14. Global market size by region 2020-2024, primary microparticles, (Metric Tons)
  • Figure 15. Global market for primary microparticles 2025-2036, by region, (Metric Tons)
  • Figure 16. Global market 2017-2036, for biobased microbeads, (MT)
  • Figure 17. Global market 2017-2036, for biobased microbeads, by market (MT)
  • Figure 18. Global market 2017-2036, for biobased microbeads, by region (MT)
  • Figure 19: CNC produced at Tech Futures' pilot plant; cloudy suspension (1 wt.%), gel-like (10 wt.%), flake-like crystals, and very fine powder. Product advantages include:
  • Figure 20: NCCTM Process
  • Figure 21. Pressurized Hot Water Extraction
  • Figure 22. BELLOCEA(TM)
  • Figure 23. VIVAPUR-R MCC Spheres
  • Figure 24. Viscopearl-R
  • Figure 25. Supramolecular plastic that dissolves in seawater
  • Figure 26. The Proesa-R Process
目次

The market for biobased microbeads represents a rapidly evolving segment within the broader sustainable materials industry, driven by increasing environmental regulations and consumer demand for eco-friendly alternatives to conventional plastic microbeads. These microscopic spherical particles, typically ranging from 1 to 1000 micrometers in diameter, are derived from renewable biological sources such as plant cellulose, algae, agricultural waste, and biodegradable polymers. The global biobased microbeads market has experienced significant growth following regulatory restrictions on synthetic plastic microbeads in personal care products. Countries including the United States, Canada, the United Kingdom, and several EU nations have implemented bans on plastic microbeads in rinse-off cosmetics due to their environmental persistence and potential harm to marine ecosystems. This regulatory landscape has created substantial opportunities for biobased alternatives that offer similar functional properties while maintaining biodegradability.

The biobased microbeads market encompasses a diverse range of natural materials and biodegradable polymers, each offering unique performance characteristics and application potential. From polysaccharides like starch, cellulose, and chitin to proteins including collagen and casein, the material landscape continues to expand with innovations in polyesters such as polyhydroxyalkanoates (PHA) and polylactic acid (PLA). Additionally, emerging materials like lignin and alginate present new opportunities for specialized applications across industries.

Key applications for biobased microbeads span multiple industries, with personal care and cosmetics representing the largest market segment. These products serve as gentle exfoliants in facial scrubs, body washes, and toothpaste, providing the tactile and aesthetic properties consumers expect while addressing environmental concerns. Beyond personal care, biobased microbeads find applications in pharmaceuticals as drug delivery systems, in agriculture as controlled-release fertilizer carriers, and in industrial processes as biodegradable abrasives.

The competitive landscape features a mix of established chemical companies and innovative startups developing novel biobased solutions. Major players include companies producing cellulose-based microbeads from wood pulp and cotton, while emerging technologies focus on algae-derived particles and agricultural waste conversion. Manufacturing processes typically involve controlled precipitation, spray drying, or specialized polymerization techniques to achieve desired particle size distributions and functional properties.

Market growth drivers include strengthening environmental regulations, corporate sustainability commitments, and growing consumer awareness of microplastic pollution. The beauty and personal care industry's shift toward "clean" formulations has particularly accelerated adoption. Additionally, technological advances have improved the performance characteristics of biobased microbeads, addressing early concerns about effectiveness and shelf stability.

However, the market faces several challenges. Production costs for biobased alternatives typically exceed those of conventional plastic microbeads, though this gap is narrowing with scale and technological improvements. Supply chain development remains a consideration, as consistent quality and reliable sourcing of raw materials require ongoing investment. Additionally, biodegradation rates and environmental fate studies continue to be areas of active research and regulatory scrutiny.

Regional market dynamics vary significantly, with Europe leading in both regulatory pressure and market adoption, followed by North America. Asia-Pacific markets show growing interest, particularly in countries implementing stricter environmental standards. The market structure includes both direct replacement of existing plastic microbeads and development of new applications leveraging unique properties of biobased alternatives. Future market prospects appear robust, supported by expanding regulatory frameworks, increasing corporate environmental commitments, and continued innovation in raw materials and processing technologies. Industry analysts project sustained double-digit growth rates through the next decade, with market expansion driven by both regulatory compliance and voluntary adoption of sustainable alternatives across diverse applications.

"The Global Market for Biobased Microbeads: Market Report 2026-2036" provides critical insights into the rapidly evolving landscape of biobased microbeads from 2026 to 2036, analyzing market drivers, technological innovations, application segments, and competitive dynamics across multiple industries. Market segmentation analysis reveals significant opportunities across multiple application areas, with personal care and cosmetics leading adoption rates due to regulatory pressure and consumer demand. The agricultural and horticultural sectors present substantial growth potential for controlled-release applications, while paints and coatings, soap and detergents, oil and gas, and medical products offer diverse market entry points. Emerging applications in 3D printing, textiles, and food packaging represent future growth vectors for innovative market participants.

Manufacturing technologies and processes continue to evolve, with advances in melt processing, extrusion techniques, solvent-based production methods, and emulsion and spray-drying technologies enabling improved quality control and particle size distribution. These technological developments directly impact cost competitiveness and market penetration potential across various application segments.

Report contents include:

  • Regulatory Landscape Analysis: Comprehensive examination of microplastics legislation across major markets including REACH compliance, US federal regulations, Canadian restrictions, Australian guidelines, and emerging Asian regulatory frameworks
  • Material Technology Assessment: Detailed evaluation of natural hard materials, polysaccharides (starch, cellulose variants, chitin), proteins (collagen, gelatin, casein), polyesters (PHA, PLA), and other natural polymers (lignin, alginate)
  • Manufacturing Process Innovation: Analysis of melt processing, extrusion techniques, solvent-based production, emulsion technologies, spray-drying methods, and quality control systems
  • Market Penetration Barriers: Identification of technical limitations, cost competitiveness challenges, supply chain constraints, and regulatory compliance requirements
  • Application Market Sizing: Quantitative analysis of microplastics volumes across personal care (2024-2036), cosmetics, agriculture and horticulture, paints and coatings, soap and detergents, oil and gas, and medical products
  • Regional Market Dynamics: Geographic analysis covering North America, Europe, Asia-Pacific, and emerging markets with volume projections in metric tons
  • Competitive Intelligence: Comprehensive profiles of 40+ leading companies developing biobased microbead technologies and commercial solutions. Companies profiled include
  • Environmental Impact Assessment: Analysis of marine pollution mitigation, toxicological effects reduction, and human health implications
  • Price Elasticity and Cost Analysis: Economic modeling of market adoption rates, price sensitivity, and cost-competitiveness factors
  • Technology Readiness Assessment: Evaluation of commercialization timelines, market readiness levels, and adoption barriers across different application segments
  • SWOT Analysis Framework: Systematic assessment of market strengths, weaknesses, opportunities, and threats affecting industry development
  • Emerging Applications: Forward-looking analysis of 3D printing, textile applications, and food packaging opportunities

TABLE OF CONTENTS

1. THE MICROPLASTICS MARKET

  • 1.1. Microplastics added to products
    • 1.1.1. Classification
    • 1.1.2. Function and applications
  • 1.2. Microplastics legislation
    • 1.2.1. REACH
    • 1.2.2. United States
    • 1.2.3. Canada
    • 1.2.4. Australia
    • 1.2.5. Asia
  • 1.3. Environmental Impact Assessment
    • 1.3.1. Marine pollution and microplastic accumulation
    • 1.3.2. Toxicological effects on marine life
    • 1.3.3. Human health implications

2. BIOBASED MICROBEADS MATERIALS

  • 2.1. Use as an alternative to microplastics
  • 2.2. Biodegradation mechanisms and timeframes
  • 2.3. Natural hard materials
  • 2.4. Natural polymers
    • 2.4.1. Polysaccharides
      • 2.4.1.1. Starch
        • 2.4.1.1.1. Applications and commercial status
        • 2.4.1.1.2. Companies
      • 2.4.1.2. Cellulose
        • 2.4.1.2.1. Microcrystalline cellulose (MCC)
          • 2.4.1.2.1.1. Applications and commercial status
          • 2.4.1.2.1.2. Companies
        • 2.4.1.2.2. Regenerated cellulose microspheres
          • 2.4.1.2.2.1. Applications and commercial status
          • 2.4.1.2.2.2. Companies
        • 2.4.1.2.3. Cellulose nanocrystals
          • 2.4.1.2.3.1. Applications and commercial status
          • 2.4.1.2.3.2. Companies
        • 2.4.1.2.4. Bacterial nanocellulose (BNC)
          • 2.4.1.2.4.1. Applications and commercial status
          • 2.4.1.2.4.2. Companies
      • 2.4.1.3. Chitin
        • 2.4.1.3.1. Applications and commercial status
        • 2.4.1.3.2. Companies
    • 2.4.2. Proteins
      • 2.4.2.1. Collagen/Gelatin
        • 2.4.2.1.1. Applications and commercial status
      • 2.4.2.2. Casein
        • 2.4.2.2.1. Applications and commercial status
    • 2.4.3. Polyesters
      • 2.4.3.1. Polyhydroxyalkanoates
        • 2.4.3.1.1. Applications and commercial status
        • 2.4.3.1.2. Companies
      • 2.4.3.2. Polylactic acid
        • 2.4.3.2.1. Applications and commercial status
        • 2.4.3.2.2. Companies
    • 2.4.4. Other natural polymers
      • 2.4.4.1. Lignin
        • 2.4.4.1.1. Description
        • 2.4.4.1.2. Applications and commercial status
        • 2.4.4.1.3. Companies
      • 2.4.4.2. Alginate
        • 2.4.4.2.1. Applications and commercial status
        • 2.4.4.2.2. Companies
  • 2.5. Manufacturing Technologies and Processes
    • 2.5.1. Melt processing and extrusion techniques
    • 2.5.2. Solvent-based production methods
    • 2.5.3. Emulsion and spray-drying technologies
    • 2.5.4. Quality control and particle size distribution
  • 2.6. Regulatory Framework and Standards
    • 2.6.1. Biodegradability testing standards (ASTM, ISO)
    • 2.6.2. Food contact and cosmetic safety regulations
    • 2.6.3. International certification programs

3. MARKETS FOR BIOBASED MICROBEADS

  • 3.1. Alternatives to microplastics (1-50 micrometer), by application and market
  • 3.2. Likelihood of market penetration of natural microplastic alternatives, by market
    • 3.2.1. Market penetration barriers and challenges
    • 3.2.2. Adoption timeline and market readiness assessment
  • 3.3. Personal care
    • 3.3.1. Market overview
    • 3.3.2. Applications
    • 3.3.3. Brand adoption case studies
      • 3.3.3.1. Unilever
      • 3.3.3.2. L'Oreal
      • 3.3.3.3. Procter & Gamble
    • 3.3.4. Consumer acceptance and willingness to pay
    • 3.3.5. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.4. Cosmetics
    • 3.4.1. Market overview
    • 3.4.2. Applications
    • 3.4.3. Total quantity of microplastics present 2024-2036, by scale
  • 3.5. Agriculture and horticulture
    • 3.5.1. Market overview
    • 3.5.2. Applications
    • 3.5.3. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.6. Paints & coatings
    • 3.6.1. Market overview
    • 3.6.2. Applications
    • 3.6.3. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.7. Soap, detergents and maintenance products
    • 3.7.1. Market overview
    • 3.7.2. Applications
    • 3.7.3. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.8. Oil and gas
    • 3.8.1. Market overview
    • 3.8.2. Applications
    • 3.8.3. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.9. Medical products
    • 3.9.1. Market overview
    • 3.9.2. Applications
    • 3.9.3. Total quantity of microplastics present 2024-2036 (MT), by scale
  • 3.10. Emerging Applications
    • 3.10.1. 3D printing and additive manufacturing
    • 3.10.2. Textile and fibre
    • 3.10.3. Food packaging and biodegradable films
  • 3.11. Market value analysis
  • 3.12. Price elasticity and cost-competitiveness analysis

4. GLOBAL MARKET SIZE

  • 4.1. Primary microparticles (volume in Metric Tons)
    • 4.1.1. By Market
    • 4.1.2. By Region
  • 4.2. Biobased microbeads (MT)
    • 4.2.1. By Raw Materials
    • 4.2.2. By Market
    • 4.2.3. By Region

5. SWOT ANALYSIS AND MARKET CHALLENGES

  • 5.1. Strengths of biobased microbeads
  • 5.2. Weaknesses and technical limitations
  • 5.3. Market opportunities and growth drivers
  • 5.4. Threats and market risks
  • 5.5. Critical success factors for market penetration

6. PRODUCER PROFILES (40 company profiles)

7. REPORT METHODOLOGY

8. REFERENCES