Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (06): 45-55.doi: 10.13475/j.fzxb.20241104802

• Column of Youth Scientists′Salon on New Fiber Materials and Green Textile Development • Previous Articles     Next Articles

Review on multidimensional structural evolution of natural cellulose and its functional materials

YU Houyong(), HUANG Chengling, CHEN Yi, GAO Zhiying   

  1. College of Textile and Engineering (International Institute of Silk), Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
  • Received:2024-11-20 Revised:2025-02-24 Online:2025-06-15 Published:2025-07-02

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Abstract:

Significance Driven by global sustainable development goals to reduce reliance on petrochemical-based plastics and developing green, low-carbon alternative materials have become a key focus in both academia and industry. Cellulose, as a natural polymer, is an ideal candidate to replace traditional plastics due to its excellent biocompatibility and low toxicity. With advancements in nanotechnology, material science, and chemical modification techniques, natural cellulose can be transformed into various forms, including nanocellulose, regenerated cellulose fibers, regenerated cellulose films, and cellulose-based aerogels. These multidimensional structures exhibit unique functional properties and can be widely applied in pharmaceutical excipients, smart textiles, degradable packaging materials, and energy-efficient water purification materials. Therefore, studying the preparation methods, properties, and applications of cellulose-based materials is of great academic and practical significance, providing a theoretical foundation and technical support for the development and industrialization of green alternative materials.

Progress In recent years, research into cellulose-based materials has advanced considerably, driven by the growing demand for sustainable alternatives to petrochemical-based products. Through chemical modification and nanoscale processing techniques, natural cellulose can now be transformed into a range of innovative materials with diverse structural forms, including low-dimensional nanocellulose, one-dimensional regenerated cellulose fibers, two-dimensional regenerated cellulose films, and three-dimensional cellulose-based aerogels. These various structural forms offer distinct advantages in terms of mechanical properties, processing technologies, and functional applications. For example, nanocellulose, with its high surface area, nanoscale dimensions, and exceptional mechanical strength, has gained significant attention in fields such as composites, sensors, and biomedical applications. The remarkable properties of nanocellulose allow it to be used as a reinforcing agent in composites, enhancing the material's strength while remaining lightweight. Regenerated cellulose films have seen notable progress in applications such as smart packaging, where their ability to respond to environmental stimuli has made them particularly suitable for developing responsive, eco-friendly packaging solutions. Additionally, cellulose-based aerogels are lightweight, highly porous materials with superior adsorption properties. They are increasingly being explored for their potential in energy storage, thermal insulation, and environmental protection, particularly for applications such as oil spill cleanup and water purification. Moreover, the biodegradability of cellulose materials and their minimal environmental impact make them promising substitutes for traditional petrochemical-based materials. As environmental concerns escalate, cellulose-based materials are viewed as viable and sustainable options, offering a greener alternative for many industrial applications. This transition to renewable, biodegradable resources represents a significant step toward achieving global sustainability goals and reducing dependence on non-renewable resources.

Conclusion and Prospect The research and application of cellulose-based multidimensional materials have demonstrated great promise, offering extensive potential across various industries, ranging from packaging to environmental protection. However, significant challenges persist, especially in the realms of processing techniques, optimization of material properties, and feasibility of large-scale production. One of the primary obstacles is the necessity to refine the methods employed for fabricating and modifying cellulose materials, ensuring their efficient and consistent production at a commercial scale. Additionally, while cellulose materials possess remarkable properties such as biodegradability and versatility, further advancements are necessary to enhance their mechanical strength, durability, and functional capabilities in order to meet the requirements of a wide range of applications. Future research should concentrate on exploring the full potential of cellulose materials in multidimensional structural transformations. Innovations aimed at improving the mechanical properties of cellulose-based materials, such as increasing their tensile strength or impact resistance, will be crucial for broadening their industrial applications. Functionalization, which refers to the ability to customize the properties of cellulose for specific applications, is another significant area of focus. This could involve developing cellulose materials with advanced characteristics like water resistance, antimicrobial properties, or responsive behaviors, which are suitable for use in smart textiles and packaging. Furthermore, ensuring the sustainability of these materials is crucial, as cellulose is inherently renewable. However, the processes used to manufacture and modify it must be environmentally friendly and energy-efficient. With the ongoing advancement of green chemistry, cellulose materials are likely to find commercial applications in various sectors, particularly in biodegradable packaging, smart textiles, and environmental protection. Researchers and industry leaders need to prioritize balancing multifunctionality with environmental impact, ensuring that cellulose-based materials offer practical solutions while also supporting the transition to a green, low-carbon economy. It will necessitate continued innovation, collaboration, and investment in both research and industrial scaling.

Key words: multidimensional structure, nanocellulose, regenerated fiber, cellulose film, functional material

CLC Number: 

  • TQ352.7

Fig.1

Multidimensional structural evolution of natural cellulose and progress in functional materials. (a) Multidimensional structural evolution of natural cellulose and its functional materials; (b) Hierarchical structure of natural cellulose"

Fig.2

Application of low-dimensional nanocellulose as pharmaceutical excipients. (a) Extraction of nanocellulose; (b) pH-responsive pharmaceutical excipients; (c) Sustained release pharmaceutical excipients"

Fig.3

Research strategies and application of 1D, 2D, and 3D cellulose-based functional materials. (a) Preparation path of regenerated cellulose fibers; (b) Applications of 1D, 2D and 3D cellulose-based functional materials; (c) Modification of cellulose films; (d) Molding of cellulose aerogels"

[1] HUANG C, YU H Y, ABDALKARIM S Y H, et al. A comprehensive investigation on cellulose nanocrystals with different crystal structures from cotton via an efficient route[J]. Carbohydrate Polymers, 2022. DOI: 10.1016/j.carbpol.2021.118766.
[2] SHI X, WANG Z, LIU S, et al. Scalable production of carboxylated cellulose nanofibres using a green and recyclable solvent[J]. Nature Sustainability, 2024, 7(3): 315-325.
[3] DROGUET B E, LIANG H L, FRKA-PETESIC B, et al. Large-scale fabrication of structurally coloured cellulose nanocrystal films and effect pigments[J]. Nature Materials, 2022, 21(3): 352-358.
[4] DHALI K, GHASEMLOU M, DAVER F, et al. A review of nanocellulose as a new material towards environmental sustainability[J]. Science of the Total Environment, 2021. DOI: 10.1016/j.scitotenv.2021.145871.
[5] DONG Y, JIA B, FU F, et al. Fabrication of hollow materials by fast pyrolysis of cellulose composite fibers with heterogeneous structures[J]. Angewandte Chemie International Edition, 2016, 55(43): 13504-13508.
[6] CAPRIE Steering. A randomised, blinded, trial of clopidogrel versus aspirin in patients at risk of ischaemic events[J]. The Lancet, 1996, 348: 1329-1339.
[7] SAYYED A J, DESHMUKH N A, PINJARI D V. A critical review of manufacturing processes used in regenerated cellulosic fibres: viscose, cellulose acetate, cuprammonium, LiCl/DMAc, ionic liquids, and NMMO based lyocell[J]. Cellulose, 2019, 26(5): 2913-2940.
[8] WANG C, LI Y, YU H Y, et al. Continuous meter-scale wet-spinning of cornlike composite fibers for eco-friendly multifunctional electronics[J]. ACS Applied Materials & Interfaces, 2021, 13(34): 40953-40963.
[9] HEINZE T, LIEBERT T. Unconventional methods in cellulose functionalization[J]. Progress in Polymer Science, 2001, 26(9): 1689-1762.
[10] SWATLOSKI R P, SPEAR S K, HOLBREY J D, et al. Dissolution of celluose with ionic liquids[J]. Journal of the American Chemical Society, 2002, 124(18): 4974-4975.
[11] SHEN H, SUN T, ZHOU J. Recent progress in regenerated cellulose fibers by wet spinning[J]. Macromolecular Materials and Engineering, 2023. DOI: 10.1002/mame.202300089.
[12] WANG C, LIAO Y, YU H Y, et al. Homogeneous wet-spinning construction of skin-core structured PANI/cellulose conductive fibers for gas sensing and e-textile applications[J]. Carbohydrate Polymers, 2023. DOI:10.1016/j.carbpol.2023.121175.
[13] CHEN Y, YU H Y, LI Y. Highly efficient and superfast cellulose dissolution by green chloride salts and its dissolution mechanism[J]. ACS Sustainable Chemistry and Engineering, 2020, 8(50): 18446-18454.
[14] YANG M, CHEN Y, ABDALKARIM S Y H, et al. Efficient cellulose dissolution and derivatization enabled by oxalic/sulfuric acid for high-performance cellulose films as food packaging[J]. International Journal of Biological Macromolecules, 2024. DOI: 10.1016/j.ijbiomac.2024.133799.
[15] WOLFS J, NICKISCH R, WANNER L, et al. Sustainable one-pot cellulose dissolution and derivatization via a tandem reaction in the DMSO/DBU/CO2 switchable solvent system[J]. Journal of the American Chemical Society, 2021, 143(44): 18693-18702.
[16] FRANCISCO M, VAN Den Bruinhorst A, KROON M C. New natural and renewable low transition temperature mixtures (LTTMs): screening as solvents for lignocellulosic biomass processing[J]. Green Chemistry, 2012. DOI: 10.1039/C2GC35660K.
[17] HUANG C, YU H Y, CHEN L, et al. A binder-free method to produce heat-sealable and transparent cellulose films driven by confined green solvent[J]. Green Chemistry, 2023. DOI: 10.1039/D2GC04655E.
[18] HUANG C, GAO Y, CHEN Y, et al. Molecular dissociation of DTMS tailoring cellulose regeneration and hydrophobic modification for building highly transparent cellulose films[J]. Journal of Cleaner Production, 2024. DOI: 10.1016/j.jclepro.2024.142107.
[19] 杨浩, 陈琪, 马新华, 等. 不同凝固浴对纤维素膜特征影响的研究[J]. 现代化工, 2020, 40(8): 162-172.
doi: 10.16606/j.cnki.issn0253-4320.2020.08.034
YANG Hao, CHEN Qi, MA Xinhua, et al. Effect of different coagualtion baths on characteristics of cellulose membrane[J]. Modern Chemical Industry, 2020, 40(8): 162-172.
doi: 10.16606/j.cnki.issn0253-4320.2020.08.034
[20] CHEN Y, HUANG C, MIAO Z, et al. Tailoring hydronium ion driven dissociation-chemical cross-linking for superfast one-pot cellulose dissolution and derivatization to build robust cellulose films[J]. ACS Nano, 2024, 18(12): 8754-8767.
doi: 10.1021/acsnano.3c11335 pmid: 38456442
[21] ZHANG R, WU N, PAN F, et al. Scalable manufacturing of light, multifunctional cellulose nanofiber aerogel sphere with tunable microstructure for microwave absorption[J]. Carbon, 2023, 203: 181-190.
[22] HUANG Z, ZHANG H, GUO M, et al. Large-scale preparation of electrically conducting cellulose nanofiber/carbon nanotube aerogels: ambient-dried, recyclable, and 3D-printable[J]. Carbon, 2022, 194: 23-33.
[23] CHEN Q, ZONG Z, GAO X, et al. Preparation and characterization of nanostarch-based green hard capsules reinforced by cellulose nanocrystals[J]. International Journal of Biological Macromolecules, 2021, 167: 1241-1247.
doi: 10.1016/j.ijbiomac.2020.11.078 pmid: 33189752
[24] 杨艳. 纳米纤维素及其衍生物作为药物缓释材料的研究[D]. 兰州: 兰州大学, 2014: 28-54.
YANG Yan. The study of nanocellulose nanocrystal and its derivatives as drug slow release material[D]. Lanzhou: Lanzhou University, 2014: 28-54.
[25] 张燕洁, 黄进, 马小舟. 多羧基纤维素纳米晶的制备与性能研究[J]. 中国造纸学报, 2019, 34(3): 6-12.
ZHANG Yanjie, HUANG Jin, MA Xiaozhou. Study on preparation and properties of multi-carboxyl cellulose nanocrystal[J]. Transactions of China Pulp and Paper, 2019, 34(3): 6-12.
[26] SVAGAN A J, BENJAMINS J W, AL-ANSARI Z, et al. Solid cellulose nanofiber based foams: towards facile design of sustained drug delivery systems[J]. Journal of Controlled Release, 2016, 244: 74-82.
[27] YUNESSNIA Lehi A, SHAGHOLANI H, GHORBANI M, et al. Chitosan nanocapsule-mounted cellulose nanofibrils as nanoships for smart drug delivery systems and treatment of avian trichomoniasis[J]. Journal of the Taiwan Institute of Chemical Engineers, 2019, 95: 290-299.
[28] LI J, WANG Y, ZHANG L, et al. Nanocellulose/gelatin composite cryogels for controlled drug release[J]. ACS Sustainable Chemistry & Engineering, 2019, 7(6): 6381-6389.
[29] GAO Z, WANG C, DONG Y, et al. Freeze polymerization to modulate transverse-longitudinal polypyrrole growth on robust cellulose composite fibers for multi-scenario signal monitoring[J]. Chemical Engineering Journal, 2024. DOI: 10.1016/j.cej.2024.149785.
[30] ZENG C, WANG H, BU F, et al. A regenerated cellulose fiber with high mechanical properties for temperature-adaptive thermal management[J]. International Journal of Biological Macromolecules, 2024. DOI: 10.1016/j.ijbiomac.2024.133550.
[31] UDANGAWA W M R N, WILLARD C F, MANCINELLI C, et al. Coconut oil-cellulose beaded microfibers by coaxial electrospinning: an eco-model system to study thermoregulation of confined phase change materials[J]. Cellulose, 2019, 26(3): 1855-1868.
[32] OTT E. Cellulose derivatives as basic materials for plastics[J]. Industrial & Engineering Chemistry, 1940, 32(12): 1641-1647.
[33] XIE Z, LIU D, TANG X, et al. Largely improved dielectric energy performances and safety of BOPP film via surface engineering[J]. Composites Science and Technology, 2023. DOI: 10.1016/j.compscitech.2022.109856.
[34] OPREA M, VOICU S I. Recent advances in composites based on cellulose derivatives for biomedical applica-tions[J]. Carbohydrate Polymers, 2020. DOI: 10.1016/j.carbpol.2020.116683.
[35] ZHU M, WANG Y, ZHU S, et al. Anisotropic, transparent films with aligned cellulose nanofibers[J]. Advanced Materials, 2017. DOI: 10.1002/adma.201606284.
[36] CHEN Q, YING D, CHEN Y, et al. Highly transparent, hydrophobic, and durable anisotropic cellulose films as electronic screen protectors[J]. Carbohydrate Polymers, 2023. DOI: 10.1016/j.carbpol.2023.120735.
[37] ZHANG L, ZHOU A G, SUN B R, et al. Functional and versatile superhydrophobic coatings via stoichiometric silanization[J]. Nature Communications, 2021, 12(1): 1-7.
[38] BARTHLOTT W, NEINHUIS C. Purity of the sacred lotus, or escape from contamination in biological surfaces[J]. Planta, 1997, 202(1): 1-8.
[39] FÜRSTNER R, BARTHLOTT W, NEINHUIS C, et al. Wetting and self-cleaning properties of artificial superhydrophobic surfaces[J]. Langmuir, 2005, 21(3): 956-961.
pmid: 15667174
[40] LIAO Y, WANG C, DONG Y, et al. Robust and versatile superhydrophobic cellulose-based composite film with superior UV shielding and heat-barrier performances for sustainable packaging[J]. International Journal of Biological Macromolecules, 2023. DOI:10.1016/j.ijbiomac.2023.127178.
[41] TAN H, MA R, LIN C, et al. Quaternized chitosan as an antimicrobial agent: antimicrobial activity, mechanism of action and biomedical applications in orthopedics[J]. International Journal of Molecular Sciences, 2013, 14(1): 1854-1869.
[42] CUI B, LIU L, LI S, et al. Bio-inspired, UV-blocking, water-stable and antioxidant lignin/cellulose films combining high strength, toughness and flexibility[J]. Materials Chemistry Frontiers, 2023, 7(5): 897-905.
[43] ZHOU G, ZHANG H, SU Z, et al. A biodegradable, waterproof, and thermally processable cellulosic bioplastic enabled by dynamic covalent modification[J]. Advanced Materials, 2023. DOI: 10.1002/adma.202301398.
[44] WANG J, EMMERICH L, WU J, et al. Hydroplastic polymers as eco-friendly hydrosetting plastics[J]. Nature Sustainability, 2021, 4(10): 877-883.
[45] GONG K, HOU L, WU P. Hydrogen-bonding affords sustainable plastics with ultrahigh robustness and water-assisted arbitrarily shape engineering[J]. Advanced Materials, 2022. DOI: 10.1002/adma.202201065.
[46] KOH J J, KOH X Q, CHEE J Y, et al. Reprogrammable, sustainable, and 3D-printable cellulose hydroplastic[J]. Advanced Science, 2024. DOI: 10.1002/advs.202402390.
[47] HUANG C, LIAO Y, ZOU Z, et al. Novel strategy to interpret the degradation behaviors and mechanisms of bio- and non-degradable plastics[J]. Journal of Cleaner Production, 2022. DOI: 10.1016/j.jclepro.2022.131757.
[48] LI R, ZHU X, PENG F, et al. Biodegradable, colorless, and odorless PLA/PBAT bioplastics incorporated with corn stover[J]. ACS Sustainable Chemistry & Engineering, 2023, 11(24): 8870-8883.
[49] BASAK S, SINGHAL R S. The potential of supercritical drying as a ″green″ method for the production of food-grade bioaerogels: a comprehensive critical review[J]. Food Hydrocolloids, 2023. DOI: 10.1016/j.foodhyd.2023.108738.
[50] XIONG Y, WANG C, WANG H, et al. A 3D titanate aerogel with cellulose as the adsorption-aggregator for highly efficient water purification[J]. Journal of Materials Chemistry A, 2017, 5(12): 5813-5819.
[51] ZHANG X, ELSAYED I, NAVARATHNA C, et al. Biohybrid hydrogel and aerogel from self-assembled nanocellulose and nanochitin as a high-efficiency adsorbent for water purification[J]. ACS Applied Materials & Interfaces, 2019, 11(50): 46714-46725.
[52] JI Z, ABDALKARIM S Y H, LI H, et al. Waste pomelo peels-derived ultralow density 3D-porous carbon aerogels: mechanisms of ″soft-rigid″ structural formation and solar-thermal energy storage conversion[J]. Solar Energy Materials and Solar Cells, 2023. DOI: 10.1016/j.solmat.2023.112453.
[53] LI Z, WANG M, CHEN L, et al. Highly efficient carbonization of nanocellulose to biocarbon aerogels with ultrahigh light absorption efficiency and evaporation rate as bifunctional solar/electric driven steam generator for water purification[J]. Sustainable Materials and Technologies, 2023. DOI: 10.1016/j.susmat.2023.e00649.
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