生物基与生物可降解口罩过滤材料的研究进展

doi:10.13475/j.fzxb.20250304502

摘要/Abstract

摘要：

口罩作为重要的个人防护装备,在疫情防控和环境健康保护中至关重要。然而,传统口罩依赖石油基聚丙烯材料,其不可降解性导致严重的环境问题。生物基与生物可降解材料因此成为研究热点,其中聚乳酸(PLA)材料凭借其可再生性、可降解性和优异的加工性备受关注。综述了PLA基口罩过滤材料的研究进展,重点分析其性能优势及面临的挑战,如质硬而脆、降解速率较慢等问题,并探讨了多种改性策略,包括增韧增塑和加速降解改性等。研究认为:共混可降解聚合物可有效改善PLA的力学性能和降解速率,但仍存在相分离和生产成本高等问题;此外,生物基小分子增塑剂因其资源丰富、环保且成本低,能显著增强PLA的韧性并促进降解,但其高添加量及易迁移问题影响材料的长期稳定性。未来,PLA基口罩有望朝着更环保和智能的方向发展,结合生物基添加剂、可回收设计及智能化技术,实现从传统“一次性耗材”向“高性能智能装备”的升级,为绿色防护材料的可持续发展提供新机遇。

关键词: 聚乳酸, 生物基增塑剂, 可降解聚合物, 空气过滤, 口罩, 生物可降解口罩, 过滤材料

Abstract:

Significance Facemasks serve as essential personal protective equipment, playing a crucial role in preventing the spread of infectious diseases and safeguarding environmental health. The COVID-19 pandemic has significantly increased global demand and consumption of facemasks, leading to concerns on the environmental impact due to excessive plastic waste. Conventional facemasks are predominantly made of petroleum-based polypropylene (PP), a non-degradable polymer that contributes to persistent environmental pollution and exacerbates the global plastic waste crisis. As a result, there is an urgent need to develop sustainable alternatives that maintain high-performance filtration efficiency while minimizing environmental harm. Polylactic acid (PLA) has emerged as a promising candidate for next-generation facemask filter materials due to its bio-based origin, biodegradability, and excellent processability. Derived from renewable resources such as corn starch and sugarcane, PLA offers a viable solution to reducing reliance on fossil fuels while minimizing environmental impact. Despite these advantages, PLA-based materials face inherent limitations, including brittleness, low elongation at break, and slow degradation rates under ambient conditions. Addressing these challenges is critical to advancing the practical application of PLA-based facemasks. This review provides a comprehensive analysis of PLA-based facemask filter materials, emphasizing their advantages, limitations, and modification strategies to address existing challenges.

Progress Significant research efforts have been devoted to improving the mechanical properties and biodegradability of PLA-based facemask materials to meet the requirements of protective applications. Among the various strategies, modification of PLA through polymer blending has been an effective method for enhancing toughness and accelerating degradation. The blends of PLA with other biodegradable polymers, such as polycaprolactone (PCL), polybutylene succinate (PBS), and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV), have demonstrated marked improvements in flexibility and biodegradability. These blends not only retain the biocompatibility and renewability of PLA but also help overcome its inherent brittleness. However, critical challenges remain, particularly in achieving homogeneous dispersion of the secondary polymer phase, minimizing phase separation, and reducing the overall production cost—factors that significantly hinder the scalability and industrial adoption of such materials. In addition to the polymer blends, plasticization has gained considerable attention as a means of enhancing the ductility, flexibility, and processability of PLA. Bio-based small-molecule plasticizers, such as citrate esters, triglycerides, and oligomeric lactic acid, have shown great potential in improving PLA's mechanical properties and promoting faster degradation. These plasticizers, derived from renewable sources, provide an environmentally friendly and cost-effective solution to enhancing PLA's flexibility, which align well with the principles of green chemistry and sustainable materials development. Nevertheless, issues related to high plasticizer content and migration tendencies pose concerns regarding long-term stability and material integrity. Current research is increasingly focused on the development of high-performance plasticizers with reduced migration tendencies, as well as the use of reactive compatibilization and advanced processing techniques (e.g., electrospinning, melt blending) to ensure stable and effective modification of PLA-based facemask materials.

Conclusion and Prospect PLA-based fibrous materials show considerable promise as sustainable alternatives for facemask production due to their biodegradability and potential for functional modification. Current research has yielded encouraging results, particularly in enhancing mechanical properties and degradability through polymer blending and plasticization. However, several challenges remain. These include maintaining long-term structural integrity, ensuring uniform dispersion of additives, controlling plasticizer migration, reducing the production cost, and achieving performance comparable to PP-based masks. From a forward-looking perspective, the development of next-generation PLA-based facemasks should focus on multifunctionality and reusability. Integrating bio-based antibacterial and antiviral agents, self-cleaning coatings, and even real-time sensing functionalities can significantly expand the applicability of PLA in protective equipment. Furthermore, optimization of spinning and membrane-forming technologies, such as electrospinning or melt-blown processes, is crucial for producing highly efficient filtration media with enhanced comfort and breathability. The shift from single-use to reusable PLA-based facemasks not only aligns with global sustainability goals but also offers a viable solution to plastic pollution caused by disposable PP masks. To achieve this, interdisciplinary efforts combining materials science, environmental engineering, and health technology are essential. Ultimately, the evolution of PLA-based facemasks from disposable consumables to high-performance, sustainable protective equipment will contribute significantly to the advancement of green protective materials.

Key words: polylactic acid, bio-based plasticizer, biodegradable polymer, air filtration, facemask, biodegradable facemask, filtration material

中图分类号:

TS151

孙玉发, 孙刚. 生物基与生物可降解口罩过滤材料的研究进展[J]. 纺织学报, 2025, 46(12): 29-38.

SUN Yufa, SUN Gang. Research progress in bio-based and biodegradable facemask filter materials[J]. Journal of Textile Research, 2025, 46(12): 29-38.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250304502

http://www.fzxb.org.cn/CN/Y2025/V46/I12/29

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改性剂	添加量/%	T_g/℃	结晶度/%	拉伸强度/MPa	断裂伸长率/%	降解性能	参考文献
PBS	5	63.2	—	2.28	30.36	—	[37]
PBS	10	54.0	46.5	2.19	12.97	—	[38]
PCL	10	—	18.4	9.00	189.0	—	[42]
ATBC	15	26.0	15.9	4.50	105.0	10 d堆肥环境中易碎	[46]
TC	7	53.0	34.7	1.02	12.21	50 ^oC,4 d酶降解30.51%	[47]
GT	7	52.0	31.1	1.08	12.53	50 ^oC,4 d酶降解34.18%	[47]
OTOA	5	61.3	7.4	1.20	22.50	—	[50]
PHBV	5	—	—	2.50	45.00	4个月土壤中完全降解	[59]
PHBV	25	49.4	13.8	3.10	24.20	3周模拟土壤中完全降解	[60]
OLA	15	44.7	21.7	3.75	41.50	16 d堆肥环境中易碎	[61]